ASSESSMENT OF FOREIGN COAL CONVERSION TECHNOLOGIES, VOL III

r Re ed iil fl Cl RDP83M00914R00100006Q0-1-& ASSESSMENT OF FOREIGN COAL CONVERSION TECHNOLOGIES Volume III Appendix B I OFFICIAL USE ONLY t 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 OFFICIAL USE ONLY INSTITUTE OF GAS TECHNOLOGY IIT CENTER CHICAGO, ILLINOIS 60616 ASSESSSMENT OF FOREIGN COAL CONVERSION TECHNOLOGIES Volume III Appendix B by Martin Novil Christopher.F. Blazek Edward J. Daniels July 1982 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 Coal-synfuels commercialization forecasts have traditionally been based on the assumption that the technology for implementation does or will exist. The processes under development worldwide represent an extention of existing coal synfuels technologies in their potential for greater process efficiency, tolerance of a variety of coals, or production of a specific product range of greater interest to the anticipated commercial market. Because of technical, economic or marketing problems most of the approximately 40 processes under development outside the United States will not succeed beyond the demonstra- tion phase. The economic and market related issues have been presented as constraints in Volume II of this report. In this appendix, the technical and development status of emerging coal synfuels technologies is presented. Tables OB1 and OB2 summarize the status of processes analyzed. Technical details are provided in the text of this volume. 46(3)/overvol3/ER  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table OB1. COAL GASIFICATION AND COMBINED CYCLE PROCESSES Largest Pilot Plant Size (metric tons of Largest Proposed coal/day Pilot Plant Commercial Commercial Country/Process except as noted) Location Plane Sites Ruhr-100 High Pressure 135 Lurgi VEW Partial Gasification 360 (Combined Cycle) Eergbau-Forschung 10.8 Nuclear Assisted Rheinbraun Nuclear 25 Lignite Hydrogasification Steag/Lurgi (Combined- Cycle) * Already under construction or completed. Volklinger-Fur- stenhausen, FRG Oberhausen/ Holten Muscle Shoals, US* Cool Water Project,UJe Tennessee Eastman,US Stockum, FRG 1 Gersteinwerke, FRG Essen, PEG Weaseling, FRG Ruhr region, FRG / Proposed Commercial Plant Size (metric tons/of coal/day except as noted) Continued in-house research feasibility studies continue, no commerical plant announcements. Intended plans have been cancelled for the FRG. No government support, commercial plant under construction by Rheinbraun. Government support ending soon, no commercial plane announced. Government interested in supporting commercial demon- stration plant in the FRG. Government support ending soon, no commercial plans announced. State government of Nordrhein, Westfalia, is expected to fund project through demonstration phase. Commercialization prospects are low with anticipated government support ending. Research continues, no commercial plans announced. Research continues, no commercial plans announced. Government interested in supporting commercial demonstration plant in the FRG. Commercial size facility shut down for economic reasons. Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  M A"vec" ReWV 20j2/2 A-F 3M"4R00(1 8-9MS Table OB1. COAL GASIFICATION AND COMBINED CYCLE PROCESSES, (Cont.) Country/Process Great Britain British Gas Slagging Lurgi National Coal Board PFB 5MW (Pressurized Fluidized Bed Combustion of Coal)** Bharat Heavy Electrical 144.0 Japan Sumitomi Molten Iron 60 Coal Mining Research 40 (Combined Cycle) Largest Proposed Pilot Plant Commercial Commercial Location Plans Sites Westfield, Scotland Abington, England Leatherhead, / Grimethorpe, England England Trichy, India / Tiruchirapalli, India* Kashima, Japan / Kitakyusha, Japan Yubari, Hokkaido, / Japan * Already under construction or completed. ** Noted here because of potential competitaion with combined cycle coal gasification for electric power generation. Largest Pilot Plant Size (metric tons of coal/day except as noted) Proposed Commercial Plant Size (metric tons/of coal/day except as noted) British Gas is trying to find a sponsor for commercialization. Proposed plant does not apper to be ready for commercialization. 20NW* Testing of the demonstration size unit will last throuh 1982. Experimental research facility in operation since 1962. Future plans call for the construction of a demonstration plant in Japan, and Australia. Still in early phases of pilot plant testing. Future plans call for construction of a 40 MTPD pilot plant. Approved For Release 2007/02/20: CIA-RDP83MOO914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0 Table OB1. COAL GASIFICATION AND COMBINED CYCLE PROCESSES, (Cont.) Largest Pilot Plant Size (metric tons of coal/day Country/Process except as noted) Power Engineering 100-200 High Speed Pyrolysis (Fixed Bed) Largest Proposed Pilot Plant Commercial Commercial Location Plans Sites Proposed Commercial Plant Size (metric tons of coal/day except as noted) Official Status 175 mt/hr Demonstration plant at Karsnoyarsk (demon- still in the construction phase. stration Proposed comercial plant at Kansk plant) Achinsk has capacity of 25 X 106 metric tons/yr. M _ r _ - - = i - - = = = - -~ - _. Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  i r M PPveco Re 20 2/2i"A-1 3M J04RWWO0C 18-Ci= M M ~ M Table OB2. COAL LIQUEFACTION PROCESSES Largest Pilot Plant Size (metric tons of Largest Proposed coal/day) Pilot Plant Commercial Commercial Country/Process except as noted) Location Plans Sites Ruhrkohle/Veba Oil Catalytic Hydrogenation Saarbergwerke Catalytic Hydrogenation 200 6 Volklinge r / Furatenhausen, W.G. 11,250 6000 National Coal Board 2.7 Stoke Orchard, Supercritical Gas Solvent Extraction England National Coal Board 0.7 Stoke Orchard, Liquid Solvent Extraction England CSIRO High Speed 0.5 North Ryde, Flash Pyrolysis England Central Mining Institute 0.12 Tychy-Wyry, Catalytic Hydrogenation Poland Proposed Commercial Plant Size (metric tons of coal/day except as noted) Official Status South Africa Commercial development in doubt pending decision on FRG support. Commercial development in doubt pending decision on FRG support at end of pilot plant tests in 1983. Commercial development in doubt pending decision on FRG support. Commercial development unlikely in the near term due to National Coal Board R&D cutbacks. Commercial development unlikely in the near term due to National Caol Board R&D cutbacks. Research is still underway but no commercial plans have been announced. Sasol (Lurgi/Fischer Sasolburg, (Sasol II)* 11000 Commercial operation since 1955. Tropach) Secunda (Sasol II + III)* 60000 Full commercial operation of both facilities by end of 1982. * Under construction or already completed. Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0 Table OB2. COAL LIQUEFACTION PROCESSES, (Cont.) Largest Pilot Plant Size (metric tons of Largest Proposed coal/day) Pilot Plant Commercial Commercial Country/Process except as noted) Location Plans Sites South African Explosives & Chemicals Koppers Totzek South African Explosives & Chemicals/Mobil Sasol Direct Bench scale Liquefaction > CY ).4. Mitsui Solvent Refined 4.5 Coal W Nippon Brown Coal 0.55 "Kominic" Direct Hydrogenation Mitsui Eng. & Ship 2.4 Building Direct Sumitomo Solvent Extraction Mitsubishi Heavy Ind. 1 Solvolysis Inst. of Mineral Fuels 0.1 Catalytic Hydrogenation Sasolburg Ohmuta City, Japan Ibaraki Prefac- ture, Japan * Under construction or already completed. Proposed Commercial Plant Size (metric tons/of coal/day except as noted) Commercial operation since 1972 for ammonia production. Status of this development in doubt. Methanol production intended. Still in the early experimental phase of development. Recent announcements have indicated that construction of the demonstration facility has been postponed indefinitely. Construction of a 50 MTPD demonstration plant in Australia should be completed in 1983. Pilot plant still in early research stage. Pilot plant still in early research stage. Pilot plant in construction at Belkovskaya mine (10 MTPD). Future plans call for pilot plant construction at Kansk-Achinsk (75 MTPD). M r w - Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Pag e I Shell-Koppers Coal Gasification Process B-3 I 2. High-Temperature Winkler Coal Gasification Process B-10 3. Saarberg-Otto Coal Gasification Process B-10 4. RCH/RAG Texaco Coal Gasification Process B-23 I 5. Ruhr 100 High-Pressure Lurgi Gasification B-31 6. KGN Fixed-Bed Coal Gasification Process B-38 1 7. VEW Coal Conversion Process B-44 8. Bergbau-Forschung Nuclear-Assisted Coal Gasification Process B-50 I 9. Rheinbraun Nuclear-Assisted Lignite Hydrogasification Process B-57 10. KHD Kloeckner-Humbolt-Wedag Molten-Iron Coal Gasification Process B-64 1 11. Ruhrkohle/Veba Oil Hydrogeneration Coal Liquefaction Process B-71 12. Saarberg Catalytic Hydrogenation Coal Liquefaction Process B-82 13. Rheinbraun Brown Coal Liquefaction Process B-94 14. Steag/Lurgi Combined Cycle Project B-103 ' 15.1 British Gas Slagging Coal Gasification Process B-114 16. British Gas Composite Coal Gasification Process B-126 I 17. National Coal Board Supercritical Gas Solvent Extraction Coal Liquefaction Process B-128 18. National Coal Board Liquid Solvent Extraction Coal Lique- faction Process B-138 19. National Coal Board Pressurized Fluidized-Bed Coal Combustion Process B-149 ' 20. Esso Chemically Active Fluidized Bed Coal Gasification Process B-162 21. CSIRO Flash Pyrolysis Coal Liquefaction Process B-168 ' 22. Polish Central Mining Institute Catalytic Hydrogenation Coal Liquefaction Process B-174 I 23. SASOL (Lurgi/Fischer-Tropsch) Coal Liquefaction Process B-182 24. Modderfontein Coal-to-Methanol Process B-201 I 25. Sasol Direct Coal Liquefaction Process B-211 26. Central Fuels Research Institute (Lurgi) Coal Gasification Process B-217 I 27. Central Fuels Research Institute (Bergius) Coal Liquefaction Process B-220 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 TABLE OF CONTENTS, Cont. Page 28. Bharat Heavy Electricals Ltd. Combined Cycle Coal Gasification Process B-222 29. Mitsui Solvent Refined Coal Process B-228 30. Nippon Brown Coal "Kominic" Hydrogenation Direct Coal Liquefaction Process B-236 31. Mitsui Engineering and Shipbuilding Direct Coal Liquefaction Process B-262 32. Sumitomo Solvent Extraction Coal Liquefaction Process B-266 33. Sumitomo Molten Iron Coal Gasification Process B-275 34. Mitsubishi Heavy Industries Solvolysis Coal Liquefaction Process B-302 35. Mitsui M-Gas Coal Gasification Process B-308 36. Coal Mining Research Center Combined Cycle Coal Gasification Process B-309 37. Hitachi Coal/Oil Mixture Gasification Process B-310 38. Power Engineering High-Speed Pyrolysis Process B-312 39. Institute of Fossil Fuels Hydrogenation Coal Liquefaction Process B-314 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I The following sections survey 39 foreign coal conversion processes. These processes are numbered consecutively and organized by country of origin: ? Sections 1 through 14 are West German processes. ? Sections 15 through 20 are British processes. ? Section 21 is an Australian process. ? Section 22 is a Polish process. ? Sections 23 through 25 are South African processes. ? Sections 26 through 28 are Indian processes. ? Sections 29 through 37 are Japanese processes. ? Sections 38 and 39 are Soviet processes. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1. Shell-Koppers Coal Gasification Process Process Description The coal gasification reactor in the Shell-Koppers process is essentially an empty pressure vessel equipped with diametrically opposed diffuser guns. Crushed, ground, and dried coal sized to 90%98% up to 2,700?C 600 psig tars, oils AnnrrwPrl Fnr RPIPa 9007/02/20 : CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0 Table 1, Part 2. TECHNOLOGY FACT SHEET: RCH/RAG Texaco Coal Gasification Process Z STATUS OF DEVELOPMENT: OPERATING FACILITIES - Texaco pilot plant (15 tons/day) in Montebello, Cal. since early 50's. Demon- stration plant built at Oberhausen-Holten, West Germany in 1978. Tests at this 6 ton/hr facility are still underway. TVA has recently started up a Texaco gasifier at their Muscle Shoals facility. MAJOR FUNDING AGENCY Two-thirds funded by Federal German Ministry for Research and Technology. ANNUAL LEVEL OF FUNDING - Initial plant cost 29 MM DM, Annual operating cost offset by syngas sale to Ruhrchemie. Government support for commercial develoment seems likely. TECHNICAL PROBLEMS: From the tests to date, two areas of critical concern are the ash removal systems and the refractory lining of the gasifier vessel. Molten ash removal has caused a shut-down at the Muscle Shoals Texaco facility and equipment re-design is required. System re-design was also rqquired at the RCH/RAG pilot plant in 1978. The most suitable ceramic lining materials tested to date have expected operating lifetimes of just over 10,000 hours. This relatively short lifetime may call for gasification vessel re-design. OTHER FACTORS AFFECTING OVERALL FEASIBILITY: ? Testing of alternative components required ? Substitution of water as the suspension agent ? Optimization of heat transfer equipment ? Carbon recycle system needs further demonstration ? Testing of different types of coals required. Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  1 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Research on the RCH/RAG version of the Texaco coal gasification process also includes the following aspects: ? Test of alternative components and systems ? Investigation of fundamental relationships and further system optimization ? Substitution of water as the suspension agent ? Optimization of heat transfer equipment e Optimization of recycle carbon and noncombustible materials ? Testing of different geographic coals Relationship to Prior Technologies The Texaco coal gasification process (TCGP) is an extension of their synthesis gas generating process (TSGGP) for converting high-sulfur residual petroleum fuels and tars into synthesis gas. Research on the TSGGP was started in 1949 and resulted in licensing agreements by 1953. More than 75 plants, in 22 countries, have been constructed since 1955 for the ammonia, methanol, and oxo-chemical industries. The feedstock flexibility of the TSGGP suggested to Texaco that this concept could also be used for converting coal into synthesis gas. The abundance of coal in the U.S. and its potential role as a leading energy supply prompted Texaco to initiate process development research on the Texaco coal gasification process in 1984. In the early 50's Texaco's Montebello research laboratory, east of Los Angeles, started development work on a 15 ton/day coal gasification pilot plant. This resluted in the construction and two-year operation of a 100 ton/day demonstration plant in Morgantown, West Virginia, in 1956. This project was sponsored by the U.S. Government through the Bureau of Mines. Eastern coal was used in the gasifier to produce synthesis gas to make ammonia. This air-blown quench-type gasifier operated at 400 psig and incorporated a refractory lining and water jacket. Due to the increasing availability of low-cost oil and natural gas, this demonstration plant research was discontinued. The Arab oil embargo in 1973 rekindled Texaco's interest in coal-gas- ification. During this same time period Ruhrchemie AG, a syngas consumer, and Ruhrkohle AG, a coal producer and processor (RCH/RAG) of West Germany began their own investigation of coal gasification technologies. At that time, I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 their conclusions resulted in the selection of the Texaco process for commer- cial applications. In 1975, RCH/RAG entered into a licensing agreement with Texaco Development Corp. to adapt the TCGP to a commercial scale. Ruhrchemie's and Ruhrhohle's experience in the commercial scale equipment aspects related to coal gasification, and the experimetnal results from Texaco's Montebello gasifier were combined to build a 150 ton/day demonstration plant at Oberhausen-Holten, West Germany. Operating Facilities Ruhrkohle and Ruhrchemie have operated a 160 ton/day Texaco coal gasifi- cation pilot plant since 1977 in Oberhausen, West Germany, More than 50,000 tons/day of coal have been gasified in 10,000 hours of operation. Texaco, U.S. also operates two 15 ton/day gasifiers at its Montebello California research facility. Another Texaco gasification facility is under- going testing at the Tennessee Valley Authority's Muscle Shoals ammonia facility. The Texaco coal gasification process has thus far been licensed to a number of plants around the world. These plants and other organizations considering Texaco coal gasification technology include following: ? Tennessee Eastman project ? Cool Water Combined Cycle Coal Gasification project ? Tennessee Valley Authority project ? Dow Chemical (Texas) project ? Ruhrkohle and Ruhrchemie project ? Alsands project ? WyCoal Gas project ? SRC-II project ? Mitsubishi Heavy Industries and Central Research Institutes of the Electric Power Industry (Japan) Combined Cycle project ? Rotterdam Municipal Utility project ? Ube Industries (Japan) Ammonia project ? Nyanes Petroleum (Sweden) project ? Moers-Meerbeck (West Germany) Combined Cycle project B-28 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  1 1 r Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Major Funding Agencies The total demonstration plant costs were 29 million Deutsche Marks (DM), with approximately two thirds of the funding from the Federal German Ministry for Research and Technology. This relatively minor project cost is the result of effective utilization of the Ruhrchemie plant infrastructure and the sale of the syngas to Ruhrchemie's syngas network, which helps to offset the annual operating cost expenditures. The companies of Carl Still, Rechlinsghausen, and Friedrick Uhde, Dortmund FDR, are monitoring the project. Ruhrkohle's project responsibilities are being carried out by its subsidiary "Gesellschaft fur Vergasung and Verflussigung von Steinkohle mbH." In June of 1982 the West German Ministry of Economics requested addi- tional environmental and economic information from RCH/RAG in order to make a final decision to assist in the construction of a demonstration facility. The Ministry can grant up to half of the 220 million Deutsch Mark ($93 million DM) cost of the project. The Ministry is expected to make a final decision of the RAG/RCH Texaco demonstration project in September or October of 1982. Technical Problems From the test results to date, two areas of critical concern are the ash removal systems and the refractory lining of the gasification vessel. The prerent shut-down of the TVA Muscle Shoals Texaco plant due to ash removal problems is an illustration of those problems. Ash removal problems were also encountered at the RCH/RAG Texaco pilot plant These problems resulted from the unexpectedly low density of the slag, which inhibited settling velocities in the slag bath. The low bulk density ash also created very high transport volumes. These problems were overcome at the RCH/RAG pilot plant through system redesign. Another ash removal problem centers on the necessity to use special valves which must be resistant to the strongly eroding lag solids. These valves are subject to failure if lockhopper operation is not closely monitored. Another area of major concern at the onset of the RCH/RAG pilot plant operation was reactor lining life. A test program to determine the best refractory lining material was undertaken at the Holten pilot plant. In special test zones in the reactor jacket lining, some 50 different ceramic materials from various manufacturers were tested. Inferior refractory lining I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 life times were encountered in the early tests due to early failure of the weakest materials. The most suitable ceramic lining materials tested to date have expected lifetimes of more than 16,000 hours. Unfortunately, this is less than one year of commercial plant operation. Strict temperature control will be required for commercial operation. Another problem that was mentioned in the questionnaire responses is that because the RCH/RAG Texaco is an entrained gasifier, the inventory of coal in the gasifier is small. Consequently, the stability of the process becomes very dependent upon the capability to adequately monitor the conditions of the process. Measurement of the reactor temperature has been a particular problem of the RCH/RAG pilot plant as the temperature monitoring devices apparently degrade in their environment of slag and hydrogen. r I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL GASIFICATION PROCESS 5. Ruhr 100 High Pressure Lurgi Coal Gasification Process Process Description The Ruhr 100 gasifier is designed to operate between 25 and 100 bars (360 to 1450 psi) at a coal feed rate of 3 to 7 metric tons per hour. The 135 metric ton/per day pilot plant gasifier has a 1.5 meter inside diameter and a height of 11.5 meters, excluding the coal lockhoppers. The total reactor height including the ash and coal lockhoppers is more than 20 meters. Coal feed at the Ruhr 100 pilot plant is stored in bunkers at the neighboring Furst Leopold mine for transportation to the gasifier by a 350 meter conveyor belt system. The coal arriving at the gasifier plant is then dedusted and screened to 6.3 mm before being stored in an 85 metric ton coal bin. Coal from the bin is fed to a weighing system before injection into the coal lockhoppers. Two alternating mode lockhoppers are used to feed coal into the gasifier to reduce lockhopper gas losses by 40%. The pressurized Ruhr 100 reactor vessel consists of three sections with a cooling water jacket surrounding the middle and bottom sections. The outer walls of the gasifier vessel are made of a special steel alloy, formerly used only on a nuclear reactor, to help minimize the wall thickness. The inner shell of the reactor is comprised of a number of different alloys in order to collect data for future designs of larger units. Special temperature measure- ment equipment is also installed in the pilot plant gasifier in order to monitor the gasification reactions at various points within the gasifer. As the coal enters the gasifier via the lockhoppers, it descends through a drying zone, carbonization zone, gasification zone and combustion zone. The slowly descending coal is evenly distributed within the gasifier by an externally driven rotating grate. A special feature of the Ruhr 100 gasifier is the addition of an extra raw gas outlet located below the carbonization zone. This second outlet makes it possible to influence the temperature and flow rate of the hot raw gases into the devolitilization zone. The effect of this control mechanism will be to reduce the amount of fines carryover by a reduction of gas velocity through the topmost gas outlet. The product gas exits the "clear gas" outlet below the carbonization zone at a temperature of approximately 800?C and the carbonization zone outlet is rich in methane and I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 hydrocarbon liquids which were formed in the carbonization zone. A technology fact sheet for this process is presented in Table 1. Process Goals The basic objective of the Ruhr 100 project is to increase the operating pressure of the Lurgi gasifier from its normal operating pressure range of 20 to 28 bars (290 to 400 psi) to a maximum operating pressure of 100 bars (1450 psi). One positive outcome in this incresed pressure operation will be an increase in gasifier throughput without increasing the gasifier diameter. In addition bench scale and theoretical research by G. Baron has indicated that due to the higher partial pressure of hydrogen of the carbonization pro- ducts results in a 60% to 80% (by volume) increase in methane formation over 25 bar operation. The increase in methane production within the gasifier reduces coal and oxygen consumption due to the exothermic reaction of methane formation and the resulting reduction of the partial combustion of coal within the gasifier to produce heat. The results of tests made by Sustmann and Ziescehe also indicate a 75% reduction of tars in the raw gas stream at the 100 (1450 psi) bar operating pressure. This is due in part to the hydrogasi- fication of some of the tars in the gasifier. In addition to less tar produc- tion, fewer higher hydrocarbons and phenols are formed as a result of the 100 bar 91450 psi) gasification pressure. The increase in methane production within the gasifier is of particular importance to SNG plant design and economics and of obvious concern to the Ruhrgas AG. The increase in the methane content of the raw gas will reduce the size of the downstream balance plant, especially the methanation plant, to further reduce plant costs. An added benefit to increased pressure operation is the production of SNG above the typical pipeline operating pressure of 70 bars (1015 psi) which will eliminate the need for recompression equipment. Another special feature of the Ruhr 100 gasifier is the addition of a second raw gas outlet just above the gasification zone. This second gas out- let will reduce fines carryover by reducing the gas velocity before the devolatilization zone. The gas exiting this second outlet will also contain far fewer condensible products because these condensible products are formed predominantely in the devolatilization zone and withdrawn from the topmost (1st) gas outlet. The reduction of fines carryover will enable the Ruhr 100 gasifier to accept a wide range of coal particle sizes including possible run-of-mine coals. 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  W M M ~ M Aow ved W Re j 2C2/2iiiIA-Fii3M14R JW00("18-rte M go M M Ruhr 100 High-Pressure Lurgi Coal Table 1 Part 1 TECHNOLOGY FACT SHEET: Gasification Process NEW TECHNOLOGY (PROCESS DESCRIPTION AND GOALS): The Ruhr 100 gasifier is a fixed bed, countercurrent flow reactor consisting of three sections with a cooling water jacket around the middle and bottom sections. The goals of the project are to increase throughput and methane production by increasing reaction pressures to 1450 psia. Other goal sinclude operation of the gasifier on run-of-mine coals and "clear" gas removal from novel side port. RELATIONSHIP TO PRIOR TECHNOLOGY (INCLUDING STATE OF DEVELOPMENT OF PRIOR TECHNOLOGY): The "Ruhr .100" project is an extension of the continuous research effort to improve the Lurgi coal gasification process. This research has led to the development of the'Mark IV gasifier, the British Gas Slagging Lurgi gasifier and the Ruhr 100 gasifier. The Lurgi?gasifier has been commercially available for more than 40 years. The Ruhr 100 gasifier is currently in the pilot plant stage of development with a 135 metric ton/day plant operating in the FRG. CHARACTERISTICS OF THE TECHNOLOGY: PRIMARY OUTPUT (DESIGN CASE) ........................ TYPE OF PROCESS ..................................... FEEDSTOCK REQUIRFIENTS.............................. OVERALL THERMAL EFFICIENCY (INCLUDING BY-PRODUCTS).. CARBON CONVERSION EFFICIENCY. ....................... OPERATING TEMPERATURE ............................... OPERATING PRESSURE ..................:............... BY-PRODUCTS ......................................... * Represents efficiency for high Btu gas production ** Cold gas efficiency for syngas NEW TECHNOLOGY 340 Btu/SCF Screened to - 6.3 mm ** 79.7% 98.9% 800?C 1450 psia tar, oils, ash PRIOR TECHNOLOGY 309 Btu/SCF Below coal's ash fusion temperature 370 psia Ash, steam, tars, oils, phenols Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1 Part 2 TECHNOLOGY FACT SHEET: Ruhr 100 High-Pressure Lurgi Coal Gasification Process STATUS OF DEVELOPMENT: OPERl1TING FACILITIES - The Ruhrgas/Ruhrchemie Lurgi coke-oven gas facility at Dorsten, FRG, was selected for the 135 metric ton/day Ruhr 100 pilot plant site: this decision was based on the availability of offsite facilities and experienced operators that were still available trom. the ormer urg opera ons a c ose in MAJOR FUNDING AGENCY 75% funding by German Ministry of Research and Technology until the end of 1982. ANNUAL LEVEL OF FUNDING - Four year funding program at 150 million DM level until the end of 1982. TECHNICAL PROBLEMS: The areas of critical concern include lock hopper operation at high pressures, fouling due to fines carryover, utilization of caking coals, and plugging of downstream processes. Of these problems lock hopper operation at high pressures for coal feeding and ash removal and operation which involves large amounts of gas, high speed operation, erosion of valves, control system reliability and sealing are areas of OTHER FACTORS AFFECTING OVERALL FEASIBILITY: Ruhrkohle is an owner/parent company of Ruhrgas. Incentive for development is to provide SNG for Ruhrgas while providing a market for Ruhrkohle's coal. Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 r Relationship to Prior Technology The "Ruhr 100" project is an extension of a continuous research effort to improve the Lurgi coal gasification process. This research, which started with the theoretical work of Drawe and Danulat, produced the first generation Lurgi gasifier for the gasification of lignite under pressure in the early 19301s. Due to the loss of availability of lignites from Central Germany after World War II, Lurgi and Ruhrgas continued research to adapt the Lurgi process to the gasification of hard coals such as the mildly caking subbituminous variety available in the Ruhr district of West Germany. This renewed research led to the construction of a pilot plant in 1950 which was equipped with a 1 meter diameter gasifier at the Ruhrchemie site in Oberhausen-Holten, West Germany. The pilot plant tests resulted in two different second generation Lurgi designs. The Dorsten site acted as a proving ground for technical improvements to the Lurgi process. These improvements were in the area of corrosion control, grate water cooling systems, raw gas treatment, and coal and ash lockhopper design. Although the second generation designs represented a marked improve- ment to gasifier throughput, further increases in gasifier throughput were still desirable. Based on the operating experience gained in the Dorsten facility, a third generation design with a larger internal diameter was introduced in 1969. In the wake of the Arab oil embargo of 1973, a sense of urgency developed to further improve the Lurgi gasification design. This research effort has centered on increasing gasifier capacity, especially for SNG plants, and increasing the range of gasifiable coal type and coal size distributions, including run of mine coals. This has led to the development of the Mark V gasifier, the British Gas slagging Lurgi gasifier, and the Ruhr 100 gasifier, all based in part on the basic Lurgi design philosophy. Work on the Ruhr 100 project started in 1973 when Ruhrgas AG, Ruhrkohle AG, and Steag AG formed a joint venture to explore a high pressure Lurgi option for hard coal gasifi- cation to increase gasifier throughput and methane conversion rates. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Operating Facilities The Ruhrgas/Ruhrchemie Lurgi coke-oven gas facility at Dorsten, West Germany was selected as the Ruhr 100 pilot plant site. From the first test in September of 1979 to September of 1981 a total of 15 tests were conducted. Over 2360 hours of operation were logged which consumed about 16,000 tons of coal and produced nearly 9.6 million m3 of gas. The tests lasted from 3 to 20 days. During the most recent test conducted at 96 atms, 60 to 100% tar recycle was achieved over a ten day period. Previous tests proved gasifier operation with run-of-mine coal having an ash content of up to 50%. After the pilot plant stage of development which is scheduled to be partially funded by the German Government through 1982. Plans call for the possible construction of a 3-million tonne/year commerical facility to produce 1.5 billion m3/yr of SNG. Major Funding Agencies The total engineering design and cost of the pilot plant in 1977 was about DM 60 x 106. An additional D14 90 x 106 was spent to cover four to five years of operating costs. The West German Ministry of Research and Technology has funded 75% of this cost to date. Funding is expected to last through 1982. It does not appear that the Ministry will fund this project after this period. Technical Problems Although pilot plant testing is still underway, areas of critical concern have surfaced. These areas include lockhopper operation at high pressures, fouling due to fines carryover, utilization of caking coals, and plugging of downstream processes. Of these problems, lockhopper operation at high pres- sures for coal feeding and ash removal and operation with caking coals are the most important. Due to rapid pressurization and depressurization which involves large amounts of gas, high speed operation, erosion of valves, con- trol system reliability and sealing are areas of great concern. The utiliza- tion of caking coals will involve better control and operation of the devola- tilization section in order to avoid coal caking in the lower sections of the gasifier. The Ruhr 100 high pressure Lurgi gasifier is, in general, a more complex gasifier with regard to control systems because of the high pressure 11 0 r 11  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1 w However, the Ruhr 100 operates at temperatures below the coal's ash fusion temperature and some of the problems expected with the British gas slagging Lurgi type gasifier are avoided. The most critical problems avoided are the reactor lining corrosion/erosion problem and the ash removal (slag tap) design problem. During testing in the fall of 1981, the coal feed preparation was changed from 6 mm to 35 mm feedstock, to a feed containing 40 to 45% by weight below 6 mm material. Plugging of the clear gas outlet occurred and all gas was withdrawn from the carbonization gas outlet.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL GASIFICATION PROCESS 6. KGN Fixed Bed Coal Gasification Process Description The Kohlegas Nordrhein GmbH (KGN) fixed bed gasifier consists of a con- ventional revolving grate with a carbonizaton shaft as shown in Figure 1. The gasifier has been designed to operate in both a cyclic and continuous mode. However, synthesis gas (medium Btu-gas) can he only produced in the continuous mode of operation. In the continuous mode the gasifier can be operated between atmospheric and 30 bars of pressure depending on end use application. Due to the nature of the counter flow fixed bed design this process can only operate on non caking or slightly caking coals. In addition, coal feed size requirements are also critical. To overcome coal feed size requirements and the ever increasing production of fines in modern mining techniques, the KGN process utilized anthracite briquettes of approximately 40 grams in weight produced from fines. These briquettes are introduced into the gasifier via a coal-lockhopper. The coal which enters the gasifier passed through a rotating distributor grate at the top into the carbonization zone where carbonization gas is pro- duced. This crude gas containing tars and higher hydrocarbon gases is drawn into the recycle carbonization shaft by steam injection. By drawing the tar and soot laden gases into the gasification zone through the carbonization shaft, all tars and higher hydrocarbons are thermally cracked. In addition, this technique also guarantees that only coke reaches the gasification zone as it is formed in its downward movement in the gasifier. 1 1 r The oxygen and part of the steam required for the gasification reaction are injected into the bottom of the gasifier under the revolving ash grates. These grates separate the ash which is then collected in an ash lockhopper underneath the gasification vessel. The superheated steam (580?C) required for the process is partially pro- duced by heat exchange with the exiting gas and from heat collected by the 11 gasifier cooling jacket. are injected at 35 bars. The oxygen and the steam required for gasification As the tar-free synthesis gas exits the gasifier at 11 800?C and 30 bars, most of the soot in the gas is removed in hot cyclones. The gas is then cooled to 280?C before entering a final soot removed stage using venturi scrubbers. t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t 1 Drying zone Distillation zone Gasification zone I Driving device for rotating grate Ash lock hopper Figure 1. KGN FIXED-BED GASIFIER I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Part I TECHNOLOGY FACT SHEET: KGN Fixed Bed Coal Gasification NEW TECHNOLOGY (PROCESS DESCRIPTION AND GOALS): The KNG gasifier consists of a conventional revolving grate fixed bed gasifier which incorporates a carbonization shaft (Figure 1). Coal, fed through lockhoppers, descends slowly through the integrated pyrolysis/char bed to the gasification zone. Raw synthesis gas con- taining tar is recycled to the combustion zone for thermal cracking. Project goals include the production of a tar-free gas which would simplify gas conditioning. Other goals include the use of fines with a high ash content, the development of a briquetting stage, and the development of a suitable gas cleaning system. RELATIONSHIP TO PRIOR TECHNOLOGY (INCLUDING STATE OF DEVELOPMENT OF PRIOR TECHNOLOGY): Based on a conventional counter flow-fixed-bed principle-.--.- PRIMARY PRIMARY OUTPUT (DESIGN CASE) ........................ TYPE OF PROCESS ..................................... FEEDSTOCK REQUIREMENTS .............................. OVERALL THERMAL EFFICIENCY (INCLUDING BY-PRODUCTS).. CARBON CONVERSION EFFICIENCY ........................ OPERATING T1WERATURE ............................... OPERATING PRESSURE .................. ................ BY-PRODUCTS .:....................... ................ NEW TECHNOLOGY 234 Btu/SCF Pressurized fixed bed Non-caking coals 80% 850?C 30 bars Steam, ash, sulfur PRIOR TECHNOLOGY Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  ~ No 1W M M t vec Re 20Wd2/2f lA-FW3M"4R"000 18-OM M = M aLa ub ur- ur.vtLvrmNT: Pilot Plant u1U-INU FACILITLE5 - Iwo LO11/11L p11UL plant capacie or operating in the cyclic or continuous 1 C mode.Pilot Plant is located near Huchelhoven in the colliery of Sophia- ANNUAL LEVEL OF FUNDING - Total cost approximately 19 million DM. TECHNICAL PROBLEMS: Early operating problems with the grate drives and lockhoppers were reported but too have since been fixed. OTHER FACTORS AFFECTING OVERALL FEASIBILITY: Briquetting requirements may prove uneconomical unless z inexpensive source of coal fines is available. 0 r- 0 roved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 After further cooling the 75?C the gas can be cleaned of CO2 and sulfur compounds in a Stretford unit. The final gas processing step involves gas drying in a Glycol unit. The objective of the Kohlegas Nordrhein project is to develop a commer- cial size fixed bed gasifier which is easy to operate and which can produce tar-free gases. In addition to the production of tar free gas the sensible heat of the crude gas will also be available. Relationship to Prior Technology - The KGN process is based on the commercially proven fixed bed counter flow gasifer principle. Operating Facilities Construction of a 2.0 tonne/hour pilot plant was completed in February 1979. The reactor, which has an internal diameter of 2.1 meters is capable of operating at pressures of up to 7 bars. Over 200 tons of briquette coal have been processed in the facility with a turndown ratios of nearly 20%. The longest run of 1000 hours was achieved without problems. Only two operators per shift are required for this fully automatic pilot plant design. Briquettes for the process are produced on site by the colliery in which the pilot plant is located. This facility, located near Huchelhoven, West Germany, is operated by Gewerkschaft Sophia-Jacoba. In actuality Kohlegas Nordhein GmbH is a joint venture company of Gewerkschaft Sophia-Jacoba and Projektierung Chemische Verfahrenstechnik GmbH. This site was selected due to the availa- bility of nearly 1.8 million tons/year of coal fines from the colliery opera- t ion. Major Funding Agencies The project is sponsored by the Ministry of Economics of the state of Nordrhein Westfalia, West Germany. Project cost is estimated to be approxi- mately 19 million DM. Operation of the pilot plant phase of development is expected to continue through 1982. The State Ministry of Economics is expected to continue funding of this process through the demonstration phase. 1 t t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 . During early pilot plant operation mechanical difficulties were encoun- tered with the rotating grate drive units and the coal-lockhoppers. Operating problems with the carbonization recycle tube also occurred. However, all of these problems were overcome and the pilot plant has since sustained smooth operation.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL GASIFICATION PROCESS 7. VEW Coal Conversion Process Process Description The Verinigte Elektrizitatswerke Westfalen (VEW) coal conversion process has been developed for combined cycle power generation applications. However, it can also be applied to synthesis gas and reducer gas production when oper- ated with oxygen. In this process, shown in Figure 1, coal is partially gasified in the entrained flow gasifier. Prior to-gastfication the coal must be pulverized to a partical size of 90 um or less. In the pilot plant operation, the coal is pneumatically transported to a heat exchanger where it is heated to a tempera- ture of 350 to 400?C. Next the coal undergoes pre-treatment with steam for 2 to 3 seconds in a reaction tube to reduce its caking tendencies. Coal pre- treatment may not be necessary since pilot plant operation seems to indicate that the coal's caking properties do not affect gasifier operation. The pulverized coal is injected through a gasification burner at the top of the reactor with preheated air or oxygen and 600?C steam (see Figure 2). Since the gasifier operates at atmospheric pressure, the use of a lockhopper feed system is not required. The coal entering the burner undergoes rapid devolatilization and partial combustion to form a tar free gas and coke. Due to the rapid reaction rates the coke which is formed has a large surface area. This large surface area promotes desulfurization. The resulting crude gas and coke exit the bottom of the gasifier at 1200 to 1300?C and the coke is separated out for use as a boiler fuel. Waste heat is recovered from the hot crude gas at a level of 100 to 150?C. Heat is also recovered from the hot exiting coke stream. The gas can then undergo further treating depending upon application. At a coal conversion rate of 50% to 60%, approximately 80% of the gasifier steam requirements can be produced from waste heat recovery. Coke formed in this process has been tested as a boiler fuel in separate tests. It's combustion characteristics show very good ignition and burning qualities comparable to hard coal firing. A technology fact sheet for this process is shown in Table 1. t  M M M M . f veccg Re 2 2/2iJIA-F 3MM14R"00(("18-(bo l? m m m Crushing Gasification F- Heat Heat Recovery Steam Turbine Flue Gas Heat Electric Process GasTurbine Pbwer m 0 x z Ash Electric Power 0 r 0 0 Figure 1. VEW-COAL CONVERSION PROCESS Dust Sulphur Purification 7 Gas Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Coal, Air Steam. Air (600?C) (02) Air, Gas Burner for Starting t Steam forCooling Steam for Cooling t To Combustion Chamber To CharBunker Figure 2. VEW-COAL CONVERSION PROCESS REACTOR 11 I I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  M M M PMvecftReWW20 2/2%&A-1 3M J04R"000"18-( M = = Table 1 Part 2 TECHNOLOGY FACT SHEET: VEW Coal Conversion Process NEW TECHNOLOGY (PROCESS DESCRIPTION AND GOALS): The VEW process has been developed primarily for combined cycle applications. This partial gasification, entrained flow gasifier is claimed to significantly reduce the sulfur content of the by-product coke thereby making it more attractive for direct combustion applications. RELATIONSHIP TO PRIOR TECHNOLOGY (INCLUDING STATE OF DEVELOPMENT OF PRIOR TECHNOLOGY): CHARACTERISTICS OF THE TECHNOLOGY: CHARACTERISTICS NEW TECHNOLOGY PRIOR TECHNOLOGY PRIMARY OUTPUT (DESIGN CASE)....... sXngas........... @30 to 60 coal conversion-44.4 to 48.5 CO, 1.1 to 8.3 Vol. % CH4 TYPE OF PROCESS ..................................... partial gasification - entrained bed FEEDSTOCK REQUIREMENTS .............................. all types of coal OVERALL THERMAL EFFICIENCY (INCLUDING BY-PRODUCTS).. 41% coal to electricity CARBON CONVERSION EFFICIENCY........................ designed operation 30 to 60%* OPERATING TEMPERATURE. .............................. 1300>?C OPERATING PRESSURE .................................. 1 atm BY-PRODUCTS .............................. .........., coke, sulfur * low carbon conversion efficiency due to partial gasification 02/20: CIA-RDP83MOO914ROO1000060018-0 Vol.% H29 approx. 44.6 Vol.%  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1 TECHNOLOGY FACT SHEET: OPEMTING FACILITIES - A one tonne/hr pilot plant has been in operation at Stockum, West Germany since 1977. A 15 tonne/hr demonstration plant began operation in 1981. Plans call for the construction of a 1.8 million tonne/yr commercial MAJOR FUNDING AGENCY The-Federal Ministry for Research and Technology, West Germany. The 1 tonne/hr pilot plant cost 9 million DM to construct and the ANNUAL LEVEL OF FUNDING - 15 tonne/hr demonstration plant cost 37 million DM to construct. Coal caking tendencies and heat recovery from dust laden eases were originally spen.ac lrnhlPm ara~c td However, these areas posed no technical problems during pilot plant operation. is 00 -i M OTHER FACTORS AFFECTING OVERALL FEASIBILITY: Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Process Goals The main objective of the VEW development work is to apply this process to combined cycle power generation. In addition, the partial gasification principle is being tested for the production of low sulfur coke. The favor- able sulfur scavenging effect in the reactor during gasification produces a 70 to 80% sulfur removal rate based on a 50 to 60% coal conversion efficiency. Relationship to Prior Technology The VEW gasification process is based on the entrained flow principle of coal gasification. However, the VEW process is not an extension of a commerc- ially available gasification process (i.e., Koppers-Totzek). Operating Facilties The VEW gasification process is being tested in a 9 million DM 1 tonne/hr pilot plant in Stockum, West Germany. The pilot plant gasifier which has been in operation since 1977 consists of a refractory lined vertical shaft of about 12 meters in- length with a diameter of 0.5 meters. The plant does not have gas purification facilities. Operation of this facility with air and different coals thus far has proved satifactory. VEW is all being developed by the company of Stein Miller, Gummersbach, which is responsible for the gasification plant. The company of Still, Recklingshausen, is responsible for the gas cleaning system. In 1981 construction was completed on a 15 tonne/hour demonstration plant which cost 37 million DM. The plant also began operation in 1981. Future plans call for the construction of a 1.8 million tonne/yearly VEW combined cycle plant in 1983. This plant will be located at Gersteinwerke, Lippe and Emstand. Operation is scheduled for 1985. Major Funding Agencies The Federal Ministry of Research and Technology in West Germany is the major funding source of the VEW process. It does not appear that government support of this process will continue. Technical Problems None reported to date. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 8. Bergbau-Forschung Nuclear Assisted Coal Gasification Process Process Description Bergbau Forschung GmbH (BF) is developing a nuclear heat assisted coal gasification [Prototypanlage Nukleare Prozesswarme (PNP)] process for the production of synthesis gas or SNG. Based on the study of coal kinetics it was determined that the heat produced from a high-temperature gas-cooled nuclear reactor (HTGR) is sufficiently high (950?C) to gasify coal. With the gasifier heat requirements being met by nuclear energy, a substantial reduction in oxygen requirements and coal could be accomplished. The heat produced in the HTGR is transferred by a helium circuit at a temperature of 950?C. For safety reasons, the heat is transferred to a secondary helium loop which flows through the gas generator and the power plant. The gas generator which is shown in Figure 1, is a fluidized bed reactor with a submerged helium heat exchanger. The hot helium flows through this immersed heat exchanger to supply the heat of reaction. All gas loops and the gasifier reactor are operated at a pressure of 40 bars. The gasifier itself is a horizontally mounted cylindrical pressure vessel. Feed coal below 0.5 mm is fed into the top of the reactor through lockhoppers. The bed is designed with a perforated trough where steam enters to provide fluidization. The hot (900?C) helium heat exchanger tubes drop from above into the fluidized bed. The coal as it is introduced into the gasifier moves longitudinally through the bed as it is gasified. The ash which accumulates at the other end as well as entrained solids which are removed overhead in a cyclone are removed through another set of lockhoppers. In the pilot plant noncaking coals are fed to the free board while caking coals are fed directly into the fluidized bed. The difficulty of feeding into the bed is probably a reason for using this technique only when absolutely necessary. In large scale commercial operation a pretreatment step may be required for caking coals. A schematic of the pilot plant process is shown in Figure 2. A summary of this process is presented in the technology fact sheet of Table 1. Conventional coal gasification processes consume 30 to 40% of the input coal for process energy needs. The remaining 60 to 70% is then available for B-50 I N S T I T U T E O F G A S T E C H N O L O G Y 1 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  M ~ M M M vec Re6W21 2/2"1A-FW3M"14R"00{"18-(Jo M M M M A C1 1 cooling water Dampf steam Figure 1. GAS GENERATOR Helium DDS Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 - -- 33600 5 x 5470 Rohgas/raw gas Kuhlwasser Koks char  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 SCHWELKOKS CHAR GENERATION u HELIUM ERHITZUN HEATING STEAM KONDENSAT CONDENSATE DAMPFERZEUGUNG ROHGAS 0 RAW GAS ZYKLON GASKUHLUNG GASWASCHE CYCLONE GAS COOLING GAS CLEANING ASCHE/ASH H2O Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  1WWvejW 1ejjW 2 j"212 IA-F S3M"14R }00( 18-*W Bergbau-Forschung Nuclear Assisted Table 1 Part 2 TECHNOLOGY FACT SHEET: Coal Gasification Process NEW TECHNOLOGY (PROCESS DESCRIPTION AND GOALS): The Bergbau-Forschung process is being developed to use the energy from a high temperature gas cooled nuclear reactor to supply process heat to a steam coal gasification process. The process utilizes a fluidized bed gasifier which has an internal heat exchange that circulates.900?C helium from the HTGR. The use of an outside heat source will lower oxygen demand and coal use as well as reduce gaseous pollutant RELATIONSHIP TO PRIOR TECHNOLOGY (INCLUDING STATE OF DEVELOPMENT OF PRIOR TECHNOLOGY): No relation to priortclinology. PRIMARY OUTPUT (DESIGN CASE) ...... syngas.(Yol;%) ..... TYPE OF PROCESS ..................................... FEEDSTOCK REQUIREMENTS .............................. OVERALL THERMAL EFFICIENCY (INCLUDING BY-PRODUCTS).. CARBON CONVERSION EFFICIENCY ........................ OPERATING TEMPERATURE ............................... OPERATING PRESSURE .................................. BY-PRODUCTS... * ....... 9 ............................. NEW TECHNOLOGY H2=53%, CO=11%, C02=26%, CH4=10% Nuclear assisted fluidized bed Coal less than 0.5 mm 95% 900?C 40 bars PRIOR TECHNOLOGY Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1 Part 1 TECHNOLOGY FACT SHEET: Bergbau-Forschung Nuclear Assisted Coal Gasification Process OPERPtTING FACILITIES - 450 kg/hr pilot plant at Bergbau Forschung Facility in Essen, West Germany. MAJOR FUNDING AGENCY West German Federal Ministryof Research and Technology/The state of Nordhrein- Westfalia. ANNUAL LEVEL OF FUNDING - 3.0 x 106 DM/yr Ability to utilize caking coals without pretreatment in question. Long residence time in reactor will require large reactor size. m OTHER FACTORS AFFECTING OVERALL FEASIBILITY: Coupling of HTGR heat source with fluidized bed coal gasification process still unproven. Also, productio n of low cost process heat with an HTGR relative to coal Z still need analysis. 0 r 0 M 'm MM - - M 'M = - r M r Approved For Release 2007/02/20: CIA-RDP83MOO914ROO1000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 conversion into gas. To overcome the use of feed coal to supply process energy, the goal of this development work is to use process heat from an HTGR as a source of process energy. This offers the following process advantage: ? Better use of coal supplies ? Higher process efficiency as well as nuclear cycle efficiency ? Decrease of gaseous pollutants per unit of gaseous energy produced ? Lower production cost if coal prices are regionally high and nuclear enrgy is inexpensive. Relationship to Prior Technology This technology represents a novel approach to coal gasification and does not have any relationship to prior technology. Operating Facilities Bergbau-Forshung has been developing this nuclear assisted coal gasifi- cation process since 1969. This research is being conducted at BF's Essen facilities. Besides coal gasification research, BF is also involved in coal liquefaction, production of active carbon, flue gas treatment, water purification, sewage treatment, gas separation by molecular sieves, and coke and electrode carbon production. The support research laboratories for coal gasification were predominatly built in the last six years. These facilities include a high pressure thermogravimetric analyzer, a high pressure wire screen reactor, a curve-point pyrolysis reactor, a high-pressure hot-stage microscope, and an externally heat steam-char gasification PDU. The development of the nuclear assisted coal gasification unit has proceeded in a step wise manner since 1969. The reaction kinetics of steam and hydrogasification of different coals and chars using particle sizes smaller than 2 mm has been investigated since 1969 in a fixed-bed differential sweep gas reactor at temperatures up to 1000?C, total pressures up to 70 bar (70 x 105 N/m2), and various steam-hydrogen mixtures. A small-scale pilot plant has been operated since 1973 at 40 bar (40 X 105 N/m2) using an inter- nally heated fluidized bed. This unit processes up to 5 kg/h and gives result concerning reaction kinetics, gas composition, reaction heat, fluidized bed density, and heat transfer under quasi-realistic conditions. In the mid-70's BF started construction of a 450 kg/hr pilot plant which started operation in 1979. The pilot plant gasifer is 0.9 m in inside I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 diameter and approximately 4 meters in height. The overall pilot plant structure is about 60 ft tall by 40 ft square. Since the beginning of pilot plant tests in 1979, they have logged over 7525 hours of coal gasification. The longest run lasted for 40 days in 1979. A typical raw gas is reported to contain CH4=14%, C0=14%, H2=51%, and C02=21%. BF claims 95% carbon conversion but with very long residence times (in excess of two hours). The steam distributor is made up of an incolloy 800 pipe with holes pointing downwards. Major Funding Agencies The nuclear assisted steam coal gasification process is being jointly developed by the following companies: ? Bergbau-Forschung GmbH, Essen, in cooperation with: ? Gesellschaft fur Hochtemperaturreaktor-Technik GmbH ? Hochtemperature-Reaktorbau Gmbh ? Kernforschungsanlage Julich GmbH ? Rheinische Braunkohlenwerke AG The major funding agency for this project is the West German Federal Ministry of Research and Technology as well as the State of Nordrhein- Westfalia. The pilot plant was designed and built at a cost of DM 13.5 X 106 and the current annual operating cost is DM 9 X 106. The project manger is Dr. van Heek who also directs what is called the pyrolysis laboratories (including devolatilization and char gasification work) and the materials testing laboratory. The annual costs for these two support research activities are about DM 2.0 x 106 and DM 4.0 X 106, respectively. This research group has a total of 30 to 35 people out of the DM 15 X 106 annual budget. The group spends nearly DM 4.68 X 106 per year towards salaries and the rest towards equipment, materials, and supplies and utilities. Technical Problems The fluidized bed gasifier used in this process is very sensitive to the caking properties of the coal feedstock. In addition, the required long resi- dence time in this reactor will require a large reactor size to attain the desired coal throughput. Finally, it has yet to be proven whether or not two different processes such as the HTGR and the fluidized bed coal gasification process can operate in harmony given their inherently different operating conditions. 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t Rohren- paltolen Dampf- erzeuger H2 C: H2O C02 Co P; H2 C02 Ko;; CO herung koHe Trockner Koks Hydner- vergaser H2- Vorwarmer Gas- zerlegung Gas- wasche I I CH,,-Abgabe H2S C02 WEST GERMAN COAL GASIFICATION 9. Rheinbraun Nuclear Assisted Lignite Hydrogasification Process Process Description The Rheinbraun process is being developed as part of the West German Prototype Plant Nuclear Process Heat Project (PNP). In this process, a fluidized bed coal gasifier is used to hydrogasify coal. Unlike conventional hydrogasification techniques that react a part of the coal input to produce the required hydrogen, the Rheinbraun process reforms part of the end-product methane to produce hydrogen. The heat for the endothermic reforming reaction is produced by a high temperature gas-cooled nuclear reactor (HTGR). A flow diagram of this process is shown in Figure 1. Figure 1. RHEINBRAUN HYDROGASIFICATION PROCESS I In the pilot plant arrangement shown in Figure 2, low sulfur coal is crushed and fed into the fluidized bed gasifier via a lockhopper. Prior to entering the gasifier the coal powder is also dried and pretreated to reduce caking properties. The hydrogasifier reactor operates at a pressure of 65 to 100 bars and a temperature of 1000?C with a coal throughput capacity of up to 400 kg/hr of raw brown coal. The gasifier consists of a steel pressure vessel with an alumina lining. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0 For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Because of the long residence time required for complete gasification, only a fraction of the coal is gasified. This fraction of gasified coal is in the range of 50 to 70% of the coal input. The resulting char is removed from the gasifier via lockhoppers and can be used as a boiler fuel to raise steam. Hydrogen for the hydrogasification reaction along with steam and oxygen are injected into the bottom of the gasifier. These reaction products also pro- vide the fluidization in the bed. A synthesis gas with a methane content of 30 to 50% can be produced in this gasifier. In a commercial operation, the hot raw gas exiting the gasifier is cooled and separated into its prime constituents. The carbon dioxide and hydrogen sulfide are scrubbed out and processed while the hydrogen is recycled back into the gasifier. Part of the captured methane exits the plant as product while the remainder is sent to a catalytic steam reformer. The heat required for the endothermic steam reforming reaction is supplied by an HTGR via heat exchange with a 900?C loop of circulating helium. This step produces the additional hydrogen required by the hydrogasification reaction. The resulting synthesis gas is then mixed with the carbon monoxide from the gasifier and reacted in a water gas shift reactor to produce additional hydrogen. This hydrogen is then sent to the gasifier and the carbon dioxide is scrubbed and released to the atmosphere. The above described process can be modified by the addition of a High- Temperature Winkler gasifier. This gasifier would eliminate the use of nuclear heat by consuming the unreacted char from the hydrogasifier to produce the additional hydrogen required by the process. A technology fact sheet describing the HTGR coupled process is shown in Table 1. The goal of this project is to produce SNG with an integrated HTGR and hydrogasification process. This offers the advantage of reducing gaseous pollutants and conserving coal reserves. This project will demonstrate the use of a novel gasifier, methane steam reformers, and integrated HTGR. Relationship to Prior Technology Although the concepts of each major component are not new, the designs and application of these concepts have not been demonstrated by any previous process.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 U a) a) - w a) 0 bO 0 a) +J 0 $4 a) U a) a co a) 0 v Id 0 bo D 0 u CA a) a ca a) a 0 U 0 W O 1J 00 a) 1.1 Q. cn 0 U s .H 0 0 W a) a a) a) U z cd a 0 u r4 G 0 44 0 U) 41 a) 1J a) Cd bD cn o P a) x ca u r+ W U) a) (Cl 41 a) 0 O w to 0 N a W Cd 10 cd ca H p 0 a) - ca 0 +.I a) a) a P4 4.1 4.1 w a) 0 0 U W 0 ~a 0 H H P a 0. 0 0 0 ri 0 ao H 0 U W 0 a~ .r{ '-1 N .rI ?C a 0 .r{ 71 (3) 4 cc ,.a H W W (1) b0 U) a a) cd H 4-1 W ..a ?rl a 0 "C N P W U 0 U) 0 cn ?H U Ia cn N m T1 0 0 cad P ? H O H > 1' T O 7a U)) . G a. ? %D H u 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 V. 0 ro 44 U) ca co w b Io r4 a a) +W w ?rl U) $4 xa i O C? z 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Operating Facilities Successful operation of this concept has been demonstrated at the 0.4 metric ton/hr process development unit operated by Rheinbraun since 1975 at their Wesseling facilities. The nuclear heat steam reformer concept has been tested since 1972 in a single tube design by Kernforschungsanlage (KFA) in Julich. Construction is underway of a one-tenth scale, 25 ton/day, pilot scale gasification plant and a 30 tube nuclear assisted methane steam reformer reactor. Major Funding The nuclear assisted lignite hydrogasification process is being developed by Union Rheinische Braunhoklenwerke AG (Rheinbraun) in association with the Gesellschaft fur Hochtemperatureaktor - Technik mbH, Hocktemperature - Reactorbau GmbH, Kernforschungsanlage Julich GmbH, and Bergbau-Forschung GmbH. Funding for this project is being sponsored by the Federal Ministry of Research and Technology (FMRT) as well as the State of Nordrhein-Westfalia. Total cost of the project is 150 million DM through the semi-commercial stage of development. Seventy-five percent of this cost is sponsored by the FMRT. Technical Problems Blockages occurred in the upper gasifier section when agglomerates formed during operation on caking coals. This problem can be overcome by the selective use of coals or the pretreatment of caking coals. Capital Costs The capital cost for a nuclear assisted lignite hydrogasification fac- ility consuming 17.4 X 106 metric tons/yr of brown coal is shown in Table 2. This facility would cost 3,615 million DM in 1976 DM. This cost includes a 3000 MW HTGR to supply process heat. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 .Table 2. CAPITAL COST OF THE RHEINBRAUN INTEGRATED HTGR-HYDROGASIFICATION PROCESS (1976 Basis) HTGR Thermal Output 3000 MW Utilization Factor 7500 hr/yr Coal Input 17.4 X 106 tonne/yr Gas Output 2.96 X 109 m3/yr Char Output 2.13 X 106 tonne/yr Electricity Production 877 X 106 kWhr/yr Project Cost 3,615 million DM Coal Price 7 DM/G cal I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL GASIFICATION PROCESS 10. KHD Kloeckner-Humbolt-Wedag Molten Iron Coal Gasification Process Process Description The Kloeckner process is based on the use of a molten iron bath for gasification. The gasifier is a refractory lined vessel equipped with gas cooled tuyeres. Crushed coal sized up to 3 mm is injected into the bath through the bottom tuyeres which are similar to the Q-BOP technology proven by the steel-making industry. The coal which has been dried to a moisture con- tent of 1.5% is also mixed with lime of the same partical size before being pneumatically injected with nitrogen into the molten bath. Additional gasi- fying agents such as oxygen, air steam, or CO2 can also be injected simul- taneously into the bath through the special tuyeres. A diagram of the tuyeres design is shown in Figure 1. Hr-` 1 I r~ ! Figure 1. TRIPLE-FLOW TUYERES DESIGN To protect these tuyeres which are made of a high grade steel, from the excess heat, a cooling gas is blown through the outermost annular gap. This gas can be propane, methane, carbon dioxide, steam or purified recycled syn- thesis gas. A simplified flow diagram of the Kloechner process is presented in Figure 2. As the coal enters the 1350 to 1400?C iron bath it undergoes rapid devolitization and cracking of the hydrocarbons. The carbon in the coal is dissolved in the bath and the coal ash rises to the bath surface. Any sulfur I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 in the coal reacts with the iron to form FeS. This FeS reacts further with the injected lime to form CaS. The calcium sulfide and ash are removed from the gasifier as liquid slag. The dissolved carbon in the iron bath reacts with the injected gasification agents such as oxygen and steam to produce a synthesis gas consisting of CO and H2. The high process temperature produces a gas which is relatively free of carbon dioxide, volatiles, and sulfur com- pounds. When the gasifier is operated under continuous conditions the carbon content of the iron bath is approximately 3.5%. The carbon conversion effici- ency of the process is 98% with a raw gas production of 2100 m3 per ton of coal. Table 1 shows the operating characteristics of the Kloechner pilot plant tests. The technology fact sheet for this process is shown in Table 2. Figure 2. FLOW DIAGRAM OF THE KLOEKHNER MOLTEN IRON GASIFICATION PROCESS I I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. OPERATING CHARACTERISTCS OF THE KLOECKNER PROCESS Coal 250 - 400 kg/hr ? tonne Fe Oxygen 0.58 m3/kg of coal Propane 0.1 m3/m3 02 Transporting Gas (N2) 0.1 m3/kg of solids (coal & lime) Coal Composition: Fixed carbon 67.50%; sulfur 1.0%; vola- tile matter 22.0%; ash 8.0%; moisture 1.5%, net heating value 7,5000 kcal/kg Raw Gas Composition CO 65 +; H2 25-30%; C02 > 0.3% S < 20 ppm; CH4 > 1%. The objective of the Kloeckner-process is to produce a synthesis which is relatively gas free of unwanted components for use in the chemical industry or as a combined cycle fuel. This is accomplished by the use of a molten iron gasifier equipped with specially designed tuyeres similar to those used in the Q-BOP technology of the steel making industry. This process also offers the stated advantage of being economical due to the high gasifier throughput and the dramatic reduction of gas cleanup facilities. Relationship to Prior Technology The concept of molten iron gasification was first patented and tested by the Applied Technology Corporation (USA) in the early seventies. However, the Applied Technology Corp. concept introduced the coal and oxygen feedstock through lances from the top into the molten iron bed. Cooling, material problems, and mechanical stability of these lances made this approach techni- cally unfeasible. In 1978 Kloeckner acquired the patent rights and modified the process to use the bottom tuyeres feed arrangement. Operating Facilities A 2.4 tonne/hr process development unit with an iron bath capacity of 6 tonnes has been tested at the Maxhutte Research facilities in Bavaria (West Germany). A larger 10 tonne/hr facility is scheduled to begin operation at the end of 1982 in the Ruhr region. Testing in this 20,000 m3/hr capacity 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 Cl) r4 H 10 a) U C b C 'd a) a I a w a) a) 0 a) U I H a) U) m a y U) J U v a) al 48 U co ) C a) C a U ) .a p ro .0 'H O 'd 0 u "ZI 4.J a) a). ro ~' U) 0 ' v A 1J U) C H v I UI 4J iJ ' p. cd .n w w 0 u cd O a.: o wl v 0 a) u w a. C 4-) a. it. -4 bo co m C 4.4 u C ro m cn U a) m a a) . v I~ a) .a 0 .r, U m C co cC) 0 co w ?14 a) 0 U CO 0. 4J U) U) E-+ W N cd 'H cd 0 v r-) ?r-) U 41 W a) .C C O .-4 a) U) O U ?rl U) a) a) 1.i U a) C a) .C C) I C E 0 ?n C 1J C.) 0 4.i ..1 a) a) 4..1 U) u U C a b C 0 C v a) H 0 4-4 C E m o ro a) ca w 0 r- G ro U a) S.+ u T ,~ b0 ?~j GL 14 r-{ V~ a1 Z U cd (3) a) 1.) a ?ri rrQ?l C O U) 41 F~ U 0 Cd a) a) C a) H ?H U 1y w U) Q) a u x .c n `0 0 O u n G O T o Ti 0 -H N 'H C U) T ~+ a) C II 41 O .n a) r-I - u-) u r=: m all 1-4 -q r, I N S T I T U T E O F G A S T E C H N O L 0 G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 0 00 0 .-. $4 Cdd b0O 0 00 o C: rr?I 0 li 0 -W co .r{ -.t cd I?a N ~i ?rl O B-68 I N S T I T U T E 0 F G A S T E C H N 0 L 0 G Y  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 gasifier will end in 1984. This facility is capable of operating at 10 bars and at a temperature of 1350 to 1400?C. Major Funding Agencies The initial process development unit testing was funded by the Maxhutte Research Institute. The 15 million U.S. $ funding for the 10 tonne/hr pilot plant is being sponsored by the State of Nordrhein Westfalia. Future plans call for the construction of a molten iron coal gasification commercial size plant in 1985 in Bremen, West Germany. This plant will have a 200 tonne molten iron reactor with a rated capacity of 200,000 m3/hr of synthesis gas. The Federal Ministry of Research and Technology will fund 40% of the 750 million D.M. construction cost. Technical Problems Much of this or similar technology has been commercially proven in the steel industry and as such no major technical problems have been reported. Capital Costs The capital costs for a direct reduction, iron ore facility incorporating a Kloechner molten iron gasification process has been published by KHD Humbolt Wedag AG. Figure 3 presents the layout of the iron ore reduction/gasification system. The operating and cost specifications for this plant are shown in Table 3. The gasification plant investment cost of 60 million D.M. was assumed to be on a 1980 basis. However, no basis was presented in the literature. Based on varying coal costs and the information presented in Table 2, Kloeckner has calculated the cost of producing reduction gas. These costs are presented in Figure 4, and vary from a gas cost of approximately 4/m3 at a coal cost of $25/tonne to a gas cost of approximately 8.74~/m3 for a coal cost of $125/tonne. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 3. OPERATING AND COST DATA FOR A KLOECKNER MOLTEN IRON GASIFICATION PLANT CONNECTED TO A IRON ORE REDUCTION FACILITY Plant Capacity 450000 t/a Fe Reducing Gas Demand 1500 m3 N/t by coal gasification -750 m3 N/t by gas recycling 1 Operating Time 8000 h/a Gasification Plant Investment 60 mil. DM Capital Change 14 %/yr gas price cts/rrr3 reduction gas from natural gas x' , 5,00 /MM Btu I x 4,40 S /MM Btu 3,80 S /MM Btu reduction gas from coal 25 50 75 100 125 coal price Figure 3. REDUCTION GAS COSTS USING THE KLOECKNER PROCESS I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 WEST GERMAN COAL LIQUEFACTION PROCESS 11. Ruhrkohle/Veba Oil Catalytic Hydrogenation Coal Liquefaction Process Process Description This catalytic hydrogenation process is a modification of the Bergius- Pier (IG Farben process) hydrogenation technology which was a commercial reality in Germany prior to 1945. Based on this working experience which was documented by BASF, Ruhrkohle (RAG) and Veba Oil in cooperation with KRONIG made the following modifications to the IG process: ? A mixture of heavy oil and middle distillate oil from the process is used as a solvent ? Separation of solids and asphaltenes is accomplished by distillation ? The residual material containing solids and asphaltenes is used to produce hydrogen. These changes are expected to improve the IG process as follows: ? Reduce the process pressure from 700 bars to 300 bars ? Raise the specific coal throughput by 50% ? Improve heat recovery ? Raise thermal efficiency by 25% ? Reduce process capital costs. Based on a renewed interest in the IG process by RAG and Veba Oil in 1974, a process development unit was designed in 1975 and completed in 1976 by Bergbau-Forschung in its Essen Laboratory. Test runs are reported to last a minimum of 4 days with an estimated total of over 21,000 hours operating experience gained since startup. The process development unit has two 11 liter reactors, designed for 400 atm and 500?C with a rate coal throughput of 250 kg/day. About 600 m3/day of hydrogen is supplied from a huge bank of (about 200) 140 psig cylinders. The recycle gas flow rate is about 1000 m3/day. A wide variety of coals are tested in the pilot plant with carbon conversions ranging up to 95% and hydro- gen consumption estimated at about 6% of wt. by d.a.f. coal. The PDU involves mixing ground coal (less than 0.2 mm) with recycled oil, and a disposable catalyst (red mud) of 2% to 3% by weight of coal, resulting I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 in a 45% solids content slurry. The slurry is pressurized in stages (using Moyno pumps to 6-8 atm and high pressure piston pumps to 300 atm), with high pressure hydrogen, preheated to 400 to 450?C, and transferred to the hydro- genation reactor. The isothermal reactor contains an agitator oscillating axially. The resulting products are a mixture of oils of a wide boiling range, gases, water and residual char. These are separated in a series of vacuum flash distillation columns to produce ash and sulfur-free distillate (50% by weight of d.a.f. coal), byproduct gases (20%), sour water (10%), and residual char. Part of the distillate oil and hydrogen, separated by scrubbing the product gases, are recycled to the front end. BF observed that some H2 in the recyled hydrogen aids liquefaction, possibly by activating the catalyst by sulfurization. However, use of pyrite in catalyst resulted in scale deposition in the slurry preheater. A typical catalyst composition is given at 30% Fe203, 40% A1203. 2-6% Ti02, and the rest silica and other inerts. In November 1977, RAG and Veba Oil decided to jointly sponsor the con- struction of a 200 tonne/day pilot plant in Bottrop close to RAG's "Prosper" coking plant which supplies some of the support facilities. The flow diagram of this 200 tonne/day pilot plant, which is similar to the PDU operated by BF, is shown in Figure 1. Construction of the pilot plant started in 1979. The plant output will be processed in a oil refining pilot plant at Veba Oil's Scholven facility nearby. The fresh hydrogen required by the process will be obtained from a nearby hydrogen pipeline operated by Chemische Werke Huls AG. In the pilot plant operation coal is delivered by train or truck and stored in the raw coal bins. From here the coal is sent to the grinding/drying mill where the coal is reduced to a grain size of less than 1 mm and a residue moisture of 0.5% by weight. Any airborne coal dust is recovered by a cyclone and electrostatic filter. All dried and sized coal is sent to the dry coal storage bin at a temperature of 120?F. The catalyst (red mud) is also stored in bins before it undergoes drying and sizing. From the dry coal bins the coal is sent to the mixing section where it is admixed with the solvent, which is a 40 to 60 weight percent ratio of medium oil (boiling temperature range 200 - 325?C) and heavy oil (boiling temperature greater than 325?C) which is recyled from the process. At this point the coal is wet ground with the catalyst to less than 0.2 mm size. This slurry, which 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 O L a 0 C U I- d a U) 0 E 0 C C-4 O N 4- N J '0 0 u 0 O u 1n C N u, .2 01 C m 0 N 4 U) 0 O J O J O W I N 5 T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 contains 40 weight percent solids, is pumped to a pressure of 300 bars and mixed with recycle gas, make up hydrogen, and recycled reacted slurry. This mixture is then heated to 380?C by heat exchange and then to the 425?C reactor inlet temperature by a gas fired heater. The hydrogenation reactions are performed in a series of three reactors. The slurry is introduced in the topmost reactor and flows downward through the remaining two reactors. Due to the exothermic nature of these reactions the reactors are maintained at 475?C through the injection of cooled recycle gas at various levels of the reactors. Upon leaving the last reactor at 450?C, the slurry gas mixture enters a separator where hot gases and vapors are drawn off the top and liquids and solids are removed from the bottom. The gaseous and vapor section is cooled by exchange with the incoming feed and then fed to the distillation section where naphtha, middle oil, and heavy oil are extracted. The resulting gas phase is oil washed to remove gaseous hydrocarbons, H2S, C02, CO, and N2. The remaining process gas is partially recycled to the feed/product heat exchanger and the rest is sent to the flash evaporation unit or sold as product to the cokery. The liquid and solids separator bottoms are flashed to separate the gas and vapor before it is sent to the vacuum distillation unit. The slurry contains about 50 weight percent solids after distillation. If this weight percent ratio cannot be maintained the slurry is heated and compressed to 50 to 100 bars with hydrogen and further processed in a high pressure flash unit. The residue is sent to a granulation units where it is shaped into tablets for further processing outside the plant. The excess oil which is not recycled is then sent to a refinery for further processing. The feed and projected pro- duct slate for this pilot plant are shown in Table 1. The technology fact sheet for this process is presented in Table 2. The refined product specif i- cations after coal-oil processing are shown in Table 3. Process Goals The objective of this process is to improve the efficiency, operating characteristics, and product slate of the old IG Farben Process. New equip- ment which will be tested in the pilot plant includes the slurry feed piston pumps, feed/product preheaters, reactors, bottoms separation flash units, and process oil upgrading. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. FEED AND PROJECTED PRODUCTS OF BOTTROP PILOT PLANT Coal., m.a.f . Feed t/d 200 Hydrogen H2, makeup m3/d (ft3/d) 220,000 (7.8x106) Process water t/d 41.2 Catalyst (Fe203) t/d 4.0 Power kWh/d 108,000 Pro j ected Products /d t 61.3 Naphtha (stab.) I.B.P. 200?C (390?F) t/d 24.4 Middle oil 200-325?C (390-620?F) t/d Heavy oil >325?C (620?F) t/d Residue t/d I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 H 0 U C 0 Cd G a) 00 0 Ea b U r1 co JJ Cd u ca Cl) a) U 0 P4 ri 0 4J u a) 4-4 a) ~4 G 0 4.J ca a) a) O >'a b U J-J H Cd -J Cd u cd U) 0 0 a) u 0 a U) 0 4) cd a) ?~ N ?rl () a) 0 a ?~ .r., m 4-) i1 a) aJ cd a C a a) W OJ 00 N 0 EJ CA Wi ?rl a) v b a) ..C b0 G U 1.I a) G a) 0 a a) u ),a 0 O )a 4-I a) a .0 0 I 0 ri ?r1 ca a) )a U) a) a) 3-I JJ u) H H a) a 4-I a) G ?r-I r-1 0 ad 0n ?rl ca JJ u o H . co fi O 1 1-1 ?? a) 0 H co ~l >+ a1 ril p~ H ?ra 0 o U 1 .r41.a) ? ? a) U7 co a) Ia a) o 4-J pr? a) - c -H Cd 0) -) rui H U) J.J C)) cad I 3 CO U v b Q) . v U) P U) 0 II a) . ' P4 (3) aJ U (a a 0 a -l 0 A b a) 4 0 1 a 4J O -4 a) a) a) co o ri) -! H I-I a H W U' .H H ! U G 0 H a) ? 0 ? G 41 41 ? n 44 b b 4-' H 0 F4 ? 0 cd r1 Cd 0 U) 4J U) H )a b 1d , U3 Cd H ,0 co O O N O H ca 0 N 4.J a) 4I 4-1 U) ?r1 r1 N ?r4 U 10 U) U U r?; 4-I H E y 0 O 0 .rq JJ U 0 r. 0 41 a !+ H v U) r~-J U ?z. O ) 0 H co w a) a) H ~ I G H a R. E-4 I ?H rH-I U U cfl )a 4-J x H cd u 4-3 ?r+ 4-J U co r-i a) 0 L U U Lf1 ? ar W ? W ? ? pry ? Z p"'G e H ? fA pVc~~ ? V M z A E4 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I v r-I ,4 r- 4 r--I r-I r-I r1 Q) U1 3 3 ul 4 4J m ~ G 00 ?r1 rn co >-i 0 r-I 0 0. cd 4-1 0 G o 4-i co O 0 a) s?-i 4, 0 ad '.0 ?r1 1 i a~ -1 0 cd ca Pq bD a) 3-i 0 4-+ q a) a) G Pq 4-1 a) rl J..1 .r1 Co .C 4J 4-4 ca a cd 1 T1 P a u cd a) 0 ?r-r4 CO 4-4 0 P. ?r1 a . o a P4 i.1 cd HEf) U) a) 0 1-I a 4-I ca co ca 44 G 0 z a a) cd r-1 I?+ q r~ b 4-4 cd r o 4) a) ~4 o 0) G a) > 4 a r Co 0 ca ca 4-1 0 'b 4J 4 M G U) a r-q .r.1 Cl) a cd a) J-1 ~' ?v a. ca 0 b 4-' 4 10 Co a fd ,a 4-4 z 4? 0 N (2) a a) a o A A 0- 4-4 ?rl 0 0 a) a~ O "C .r4 E~ r-I ,-I 0 aai o U a O 0 a) -4 4i N a G E? r-1 .o Co r-I b0 0 w M 9 ?rl o Cl) 0 .C `4 '-4 v co )-1 r1 ~ rI a) Co Q) a) rl bo r-1 ) i U ,. 0 ?ri 44 +J a ?r1 r?1 a U 0 ca >?+ a a Co cd rl U 0 a r1 41 a a) W a 4-i .C 0 3-I 00 4 134 E-4 1 a) 0 r1 a co U) G a c d 0 ca Cl) U w E~ rl 60 C9 ) ~ "C G U Co a ca M, 0 W ~ ?r1 z e r -I cd 1?+ 0 4J cd N .- ~r1 a a C IM4 mg :4 A4 4-) ?r1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 cd  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 Specif ications Gravity at 15?C g/cn3 Sp. g. (59?F) Aromat. C, wt Z Naphth. C, wt % Paraff. C, wt Z Carbon, wt 2 Hydrogen, wt Z Sulfur, wt 2 Nitrogen, wt 2 Oxygen, wt 2 Base value, mg NH3/1 g/cc) CFPP, ?C (OF) Flash point, ?C (?F) Viscosity, mm2/S Centipoise Heating value, kJ/kg Btu/lb Fuel value, kJ/kg Btu/lb Phenols, wt 2 Bases, wt 2 Benzene, wt % Toluene, wt Z Ethyl benzene, wt Z Xyl ene , wt 2 ROZ (clear) Boiling range Initial boiling point, ?C(?F) 10 vol 2, ?C(?F) 50 vol 2, ?C(?F) End point, ?C(?F) Light oil Middle oil Crude Refined Crude Refined 0.865 0.865 46 10 43 0.827 0.990 0.993 0.827 0.990 0.993 31.6 64 50.0 27 28 31.3 41.4 28 18.7 85.25 87.80 87.40 88.5 11.15 12.25 9.10 10.75 146 ppm 2 ppm 0.60 0.23 0.24 2 ppm 0.60 0.23 3.5 0.1 3.0 0.4 1100 3 8800 2900 1.1x10-3 3x10-6 8.8x10-3 2.99x10-3 -26 (-15) -47 (-53) 93 67 3.1 2.1(50?C)(12?F) 3.1 2.1 41,000 43,000 38,500 40,900 17,625 8,485 16,550 17,585 43,000 46,000 40,500 43;250 1,455 19,775 17,410 18,595 3.9 5.3 2.0 4.4 76 (169) 43 (109) Z12 (414) 169 (336) 102 (216) 81 (178) 225 (437) 205 (401) 158 (316) 149(300) 253 (487) 244 (471) 206 (403) 211(412) 324 (615) 303 (579) r s  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1 I Relationship to Prior Technology The Ruhrkohle/Veba Oil Process is based on the Bergius Pier Process which was further developed into the IG Farben process in the 1930's. The first IG Farben Process plants started in 1936 and 1939 with an output capacity of 680,000 tons per year of gasoline and middle distillates. Production capacity using this process reached 4 million tons/year before complete shutdown in 1945. Operating Facilities In 1974 RAG and its subsidiary STEAG AG started evaluating coal liquefac- tion technologies with the goal of selecting the best process for further de- velopment. In the same year Veba-Chemie AG began a research program which involved the hydrogenation of coal in a continuously operating bench-scale autoclave unit. A larger process development unith with a capacity of 250 kg/day was designed in 1975 and completed in 1976 by Bergbau Forschung it its Essen facility. In 1977 Ruhrkohle and Veba Oil formed a joint venture to construct a 200 tonne/day pilot plant in Bottrop. The design and construction of this plant, which was completed in 1981, was based on the operating data collection by BF. Major Funding Agencies Early work by both Ruhrkohle and Veba was sponsored by the Ministry of Ecnomics of the State of Nordrhein-Westfalia. The Begrbau Forschung process development unit was completed for a total cost of DM 3 X 106. The operating costs for this PDU have been around DM 3 X 106 per year. This research was also partially funded by the State of Nordrhein-Westfalia. The construction investment cost for the 200 tonne/day Bottrop pilot plant amounts to nearly 200 million DM. The operating cost for this plant is expected to cost another 200 million DM during the three-year demonstration testing period. The State of Nordrhein-Westfalia sponsored 90% of the construction phase costs and will sponsor approximately 80% of the operating phase costs. A decision to proceed with a larger demonstration size plant will be made by the West German Ministry of Science and Technology by the end of 1982. Technical Problems Although no technical problems have been reported, a number of new approaches being tested in the pilot plant still need to be proven. These new  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 technologies are the slurry feed pumps, preheaters, reactors, vacuum distilla- tion units, and upgrading coal-oil equipment. The slurry pumps will be driven by SCR controlled AC motors and operated in parallel. For test purposes. the pumps will be operated in the piston ver- tical and horizontal position. These pumps will be equipped with remote valve boxes with inlet and outlet valves of different design and materials to test for performance in regard to corrosion and erosion. The external valve box will also provide for abrasion free action, although this will result in oil loss which will be made up by clean oil on each stroke. The preheater section will consists of two different units that are each rated to handle the full plant capacity. The first heater is a shell and tube design which is similar to the ones used in the IG Farben process until 1945. At the expense of size and cost this heater provides for gradual feed heating to prevent coking. The second preheater utilizes a radient furnace design which is frequently used in oil refineries. The higher heat transfer charac- teristics of this design increase the possibility of coking but decreases the unit size and cost. The next new area to be tested at the Bottrop plant is reactor construc- tion. The old IG Farben process coal hydrogenation reactors were made from forgings whereas the new reactors will be of a new multilayer design. Insula- tion will be accomplished using a layer of refractory brick which will be protected from abrasion by a stainless steel liner. A new type of reactor is in the design phase which will utilize the multilayer concept but the required insulation will become an integral part of the multilayer wall. The fourth area of testing will focus on slurry bottoms separation using a combination of flash evaporation and vacuum distillation. These methods will be employed to maximize volatile matter separation from the hot bottom slurry which contains 65 to 75% oil. The last area of investigation will determine the best upgrading approach for the coal derived oil. The raw oil from the coal liquefaction process varies from mineral oil in many respects. These include the distribution of boiling range fractions, sulfur, nitrogen and oxygen contents, aromatic and density properties. A comparison of the coal-oil properties to "Arabian light" as shown in Table 4. 1 i 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 4. COMPARISON OF SOME CHARACTERISTIC PROPERTIES OF OIL FROM COAL AND ARABIAN LIGHT spec. gravity at 15?C API gravity carbon hydrogen sulfur nitrogen oxygen H/C ratio gasoline, ibp-200 ?C middle distillate, 200-325?C vacuum gasoil, 325-500?C vacuum residue, 500 ?C oil from coal Arabian light g/ml 0.950 0.856 17.5 34 % wt 86.6 85.5 % wt 9.05 12.6 % wt 0.1 1.7 % wt 0.75 0.2 % wt 3.50 -- 1.26 1.77 % wt 22 23 % wt 70 23 % wt 8 28 % wt - 25 Capital Costs Veba Oil has published the cost of a liquefaction plant capable of both liquefying coal and for processing heavy refinery oil residues into light oil products such as gasoline. The plant would have a coal capacity of 3.7 million tonnes per year with a rated output of 1.95 million tonnes per year of liquid product. The overall efficiency would probably be nearly 55%. The liquid product would consist of 250,000 tonnes per year of LPG, 850,000 tonnes per year of gasoline, and 850,000 tonnes per year of heating oil. According to a Veba study, this plant would require a capital investment of 6 billion DM on a 1981 basis. Design and construction of this facility would take eight years which with interest charge, would bring the final plant costs to 7.8 billion DM. 22(3)/process/ER I N S T I T U T E  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL LIQUEFACTION PROCESS 12. Saarberg Catalytic Hydrogenation Coal Liquefaction Process Process Description The Saarberg coal liquefaction process is a modification of the com- mercially proven IG Farben technology. The main differences are a lower pressure, reduced hydrogen consumption, improved heat transfer techniques and more efficient products separation equipment. A process flow diagram of the 6 tonne/day pilot plant operated by Saarbergwerke AG in Volkingen-Furstenhausen, West Germany is shown in Figure 1. Figure 1. FLOW DIAGRAM OF THE 6 TONNE/HR SAARBERG PILOT PLANT In this pilot plant the coal is first crushed and dried to a particle size of less than 3 mm before it is mixed into a slurry. Only high quality coal with an ash content of less than 15% can be used in this process. The dried coal powder is then fed into a ball mill where it is wet ground to a maximum particle size of 0.1 mm with recycled solvent, and catalyst. The catalyst consists of a mixture of iron based sulfates (FeSO4), red mud (Fe203), and-sodium sulfide (Na2). The catalyst cost was quoted as approximately 54/lb B-82 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 in 1981 dollars. The catalyst mixture composition and quantity depend on the hydrogen pressure used in the process as well as the hydrogenation reactivity of the coal feedstock. With some coals that have a sufficient autocatalytic effect, the additional amount of catalyst that must be added may be negli- gible. This may be true of many non-German coals that have a high pyritic sulfur content. This feature makes the Saarberg coal liquefaction process flexible since the optimal hydrogenation conditions can be adjusted for by changes in the catalyst composition and process pressure. The slurry paste contains approximately 60 weight percent coal, FeSO4 (1.21% of maf coal), red mud (2%), sodium sulfide (1%) and the remainder is chiefly distillate oil which is recycled from the vaccuum distillate section. This thick slurry paste is then sent to a high pressure injection pump before it is mixed with hydrogen and heated by a unique preheating section. The preheat section is designed to heat the paste by injecting hot condensed oil, which is obtained from the hydrocarbon vapors leaving the top of the hot separator feed section. The hot diluent oil, which was collected in an inter- mediate catchpot before injection into the preheat section, helps to heat the slurry and reduced the coal content to 50 weight percent. The paste is further diluted and heated by a second hot oil injection preheat section. By this means much of the exothermic heat generated in the hydrogenation section can be captured in the preheat injection oil and recycled in the process. The slurry which leaves the preheat section has a temperature of 400?C and a coal weight of 38%. The initial boiling point of the diluent intermediate entering the pre- heat section is above 200?C. The remaining oil vapors which enter the preheat section and are condensed in heat exchange with the slurry has a boiling point of about 400?C. This internal hot oil recycle is about the same weight as the incoming fresh coal and helps to eliminate the need for atmospheric distilla- tion of the oil fraction. One benefit of this method is that the oil recycle fraction is kept at a high temperature and pressure. Although this method reduces heat exchanger requirements, a bundle heat exchanger is still neces- sary for slurry preheat. A diagram of this techngiue is shown in Figure 2. Further attempts to simplify the process led to another idea which eli- minates the heat exchangers needed for preheating the slurry. In this method the coal slurry is mixed directly with the overhead vapors from the hot sep- arator. For this purpose the coal slurry is passed to a mixing zone which is B-83 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 B-84 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 I also entered by the hot separator vapors. The vapors are cooled by the coal slurry, the heavy oils are condensed, and the slurry is preheated and diluted by the condensed oil. This also permits the use of coarser coal. Since the coal slurry is being transported only in tubes, there is little danger of sedimentation. Coal particle diameters up to 1 mm (0.04 in.) are possibly applicable. The effluent of the mixing zone is separated into the hot coal slurry which is fed into the first reactor, and into the overheat vapors containing the pro- ducts and the excess hydrogen. Application of this intermediate catchpot results in another advantage. The coal while being heated normally splits off C02, H20, CH4, etc. These compounds enter the reactor and increase the total pressure by their partial pressure. Now these compounds are eliminated from the coal slurry prior to entering the reactor. Also the physically adsorbed water is stripped off and withdrawn from the intermediate separator overhead. This preheating system has the advantage that there is a reduction of the pressure resulting from a higher concentration of the hydrogen in the reactor and a lower pressure drop of the slurry compared with the use of heat exchangers. This new method is pictured in Figure 3. Saarberg believes that this arrangement can help make coal liquefaction simpler and more economic. The final slurry preheat output is sent at a temperature of 430?C to the reaction section which consists of four reactors in series which operate at a pressure of 300 bars. Oil or quench gas in injected into these reactors to maintain an operating temperature range of 470 to 475?C. The reactor product is then sent to a separator which produces a bottom containing oil, ash, cat- alyst and unreacted coal. These bottoms are then reduced in pressure to 50 bars and fed to a vacuum distillation unit. An attempt will be made to recover energy from this pressure letdown stage via a piston engine device. The residual material from the vacuum distillation section which contains 50% solids and 50% bitumen with a melting point of 80?C can be gasified to gener- ate process hydrogen. Gases which exit the top of the separator are used to supply part of the feed preheat energy via a concentric tube hat exchanger. The pilot plant is designed for two different operations to form a dis- tillate synthetic crude oil. In the first technique coal is processed only by high pressure hydrogenation. The expected results are shown in Table 1 as compared to that of the IG Farber process. In the second mode of operation the feed will also undergo carbonization after hydrogenation. The milder B-85 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t ~w N ~R 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 hydrogenation conditions of this second mode of operation seems more attrac- tive from the standpoint of catalyst and hydrogen cosumption. The byproduct char can then be gasified to produce hydrogen. In the bench scale PDU the cut point of the atmospheric distillation was increased from 325?C in the old IG Farben process to 400?C. Classical I.G. Process Saarberg Modified (Bench Scale) Conditions Pressure, bar 700 300 Temperature, ?C 490 475 Catalyst iron iron CHSV(X) 0.62 0.65 Product Distribution wt. % of M.A.F. coal) C1 - C4 hydrocarbons 20.0 15.0 C5 - 200?C distillate 12.1 14.6 200 ?C - 325?C distillate 31.4 30.2 325?C + 17.4 9.4 H209H2, NH3, CO, C02 13.9 11.7 Carbonization: Coke and Gas 12.5 Vacuum distillation: Residual oil -- Unreacted coal; (3) 5.6 H2 reacted (7.3) (5.5) Total 107.3 105.5 (X)coal hourly space velocity I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 This increase reduces the cracking which occurs in the sump phase which is only slightly selective compared to a fixed-bed catalyst. This lowers the reaction temperature 10?C which results in the suppression of undesirable light hydrocarbons which have a higher hydrogen content. These changes have led to an improvement in liquefaction operating conditions. Hard coal has been liquefied at a pressure of 285 bars and a hydrogen consumption rate of 5.5 weight percent of the m.a.f. coal. Oil yields have increased to more than 56%. A technology fact sheet for this process is presented in Table 2. The Saarberg process is a modification of the commercially proven IG Farben (Bergus-Piers) process. The major project goals of the Saarberg pro- cess are to reduce the operating pressure to a maximum of 30 bars compared to the previous 600 bars, reduced hydrogen consumption, and improved heat economy. This will be accomplished by employing novel slurry preheat con- cepts, the use of vacuum distillation, novel energy recovery equipment and a new recycle solvent appraoch. Simultaneously with the experimental program, Saarberg has followed the upgrading of the sump phase oil to marketable products through cooperation with BASF. The main objective is the production of gasoline, particularly of high-octane blending components. For this purpose the coal oil is first refined to eliminate nitrogen, oxygen and sulphur. In a hydrocracker the refined middle distillate is cracked to naphtha. In a subsequent power former, both naphtha from the hydrocracker and sump-phase naphtha are trans- formed into high octane gasoline. The gasoline which was produced from the bench scale oils in the laboratories of BASF had a research octane number (clear) of about 104. Relationship to Prior Technology The Saarberg process is a modification of the IG Farben process. In this process, crushed and dried coal was mixed with a combination of red mud, FeSO4 and Na2S and recycle oil to form a paste. This was done in rotating mills with steel balls as grinding elements in the presence of oil to prevent oxida- tion. The homogenized paste was then fed to high pressure pumps for injection into the slurry feed heat exchangers. The discharge pressure in the injection pumps was 700 bars (10,500 psi). In the heat exchangers, slurry and hydrogen 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 '-' 44 a) 0 o 1.+ 00 Ca 0 O N a) U a) u U 41 ?rl U a) W a7 U) 0 r1 U a) Ui 1J tb O 1a cd P4 cd ~ 0. 0. a) C 0 sa a)' 0 V .A .U) aJ 000 O of r-q u Q) 44 ) aJ a CU 0 $4 $4 o cd o. o ca -H a)I 0. c/ ) a a cU I +.1 ? . 00 [ a) O a) . N U ca a) u-4 co 4-c ca a) 4-I 4-4 a) o 0) 1.4 0 H Ali 0 ca C a) H W y W a) a) .r--I 1-+ N .rq 1?+ ?.1 P I U) 4-1 O A4 00 a) as N U) 14 ca a) 41 UA a) U 0 N 1a 0. a) N cd W 0 ?rl 0 1a 0. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  a 0 41 U tv 4,4 al O r4 Cd 0 U 0 rl 41 ca ai 00 7 U 4J co a.i Ca u 00N a1 m 114 u C/ w Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 l ai 44 Ch ? O ca -W 41 N O 3 0 u 4 4 ,a al td - H 0 b O 4J w a'aa) '? C l) 0 c a P.a H Pj ;-C 52' Z O I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 flowed up outside the tubes with overhead vapors from the hot separator flowing countercurrently inside the tubes. Next, the coal paste and hydrogen were preheated to about 430?C (806?F) in a gas-fired heater. The gas/slurry mixture was then passed through four vertical reactors in which coal liquefac- tion took place at about 480?C (896?F). The exothermic reaction was con- trolled by the addition of cold recycle hydrogen. The effluent from the last reactor was separated into an asphaltene-free overhead product and a bottom product containing the unconverted coal, ash, catalyst, heavy distillate and residue oil. The gases and oil vapors form the top of the separator passed through the tubes of the slurry feed heat exchangers and were finally cooled. While the remaining gas was scrubbed to recycle purified hydrogen back into the process, the liquid was withdrawn from the cold catchpot and passed to an atmospheric distillation tower. All of the 325?C+ (617?F+) distillate was recycled as pasting oil. The main product was middle distillate oil which normally was converted to naphtha by hydrocracking. The hydrocracked naphtha and refined sump-phase naphtha were then reformed to high octane gasoline by the IG DHD (German acronym for pressure hydrogen dehydrogenation) process. In the old system, processing of the hot separator bottoms consisted of two operations, centrifugation and carbonization. Both asphaltene-containing centrifuged filtrate and carbonizer oil were used as pasting media. The application of more severe hydrocracking conditions meant that the ashpaltenes produced had to be recycled to the reactors since they could not be used else- where. In one German plant asphalt was taken out of the sump phase and used as a binder for weakly caking coals. This process was first developed in Germany by Friedrich Bergius. In 1910 he received a Nobel Prize for his discovery of the hydrogenation process. The process was further developed and commercialized by the IG Farben chemical conglomerate. The first commercial size plant started operation in 1927 using brown coal as the feedstock at Leuna. By 1943, 12 plants were in operation with a combined capacity of 4 million metric tons of production. Operating Facilities In 1974 Saarbergwerke AG started the develompent of coal liquefaction technologies. This organization is a conglomerate owned by the Federal and State Governments (Federal Republic of Germany 74%, State Government of the I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Saar 26%) with interests in mining, industrial and commercial operations. These include the mining of coking and steam coals, operation of coal prepara- tion facilities, coking plants, electric power plants, oil and tar refineries, the manufacture of tools and machines, plastic and plastic products, packaging and building materials, construction and operation of central heating plants, sales, distribution, engineering, consulting, insurance, mortgages, and travel-agency activities. In 1975 a continuous 10 kg/hr bench scale unit was constructed by Saarberg for initial testing of improvements to the IG Farben Process. This work led to the construction of a 6 tonne/day pilot which began operation in July of 1981. This pilot plant located at Volklingen-Furstenhausen is a 50-50 joint venture of Saarbergwerke AG and Gelsenberg AG, a subsidiary of Deutsche BP. The new joint venture firm, Gesellschaft fur Kohleverflussigung (GFK), will operate the pilot plant for a total of three years from commission to gather data for a full scale commercial plant. The Saarberg liquefaction plant is located adjacent to the Saarberg/Otto coal gasification pilot plant and near the Furstenhausen coke works, The Saarland oil refinery, the Fenne power plant, and the Saarbergwerke AG central laboratories. Future plans call for the construction of a large demonstration scale plant that will convert 2.3 million tonne/year of coal into one million tonne/ year of synthetic gasoline and other liquids. This would represent nearly 5% of, West Germany's current gasoline consumption. A final decision in the con- struction of this plant will be made in 1983 when pilot plant testing will be nearly complete. This plant will take four or five years to construct. Major Funding Agencies The 6 tonne/day pilot plant at Volklingen-Furstenhausen was constructed at a cost of approximately $21 million. The West German Ministry for Research and Technology sponsored 75% of this cost and the State of Saarland contri- buted an additional DM 1.5 million. Technical Problems No technical problems have been reported. 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Capital Costs The Saarberg liquefaction process and the Ruhrkohle/Veba Oil liquefaction process are both modifications of the commercially proven IG Farben Process. Both processes will operate at similar temperatures and pressures, and both will have similar efficiencies. Based on equipment modification of both these processes it would be logical to conclude that they would have similar capital cost requirements. t f I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 WEST GERMAN COAL LIQUEFACTION PROCESS 13. Rheinbraun Brown Coal Liquefaction Process Process Description The Rheinische Braukohlen Werke AG (Rheinbraun) direct coal liquefaction process (also known as the HVB process - Hydrierende Verflussigung von Braunkohle) is based on the IG Farben (Bergius-Piers) process. In the HVB process, liquefaction of coal is carried out in two stages. In the first stage (called sump-phase hydrogenation), dry brown coal is cata- lytically converted into coal oil. In the second stage (gas-phase hydrogena- tion), the coal oil is converted into motor fuels by conventional oil refining techniques such as hydrocracking and reforming, or into feed materials for the chemical industry. Development work has been centered on improvements to sump-phase hydrogenation stage. In the sump-phase hydrogenation (see Fig. 1), coal with a grain size of 0 -H 4 J cn ran . u Q) U Q) U) Q) U) ca oa ro U) u _I +-' U) .H ca U) a) 4-1 O 0 U 4) P. S-) O N ca U] n, ?r-I d ~ n c c u d H H $4 PA 4-J co Zr' a) .4 O C ) ~+ . 0 t:. +J w v cA Lb a E C/) w W N co H u .rq E cna u go ca V p U1 r-1 O 0.4 0 0 P4 a 0 - 00 ?r? x W 0 Q) r1 ~ rl 4J Iz Q, a) 00 a co r-I a! O i U) ci 0 4-1 4J q aJ n mod H Cl) Q y H ~ 0 O R. cGd .) ~ eG 4-4 i 0 I ?r1 x 4-1 t3 U ~4 I U) U) U) a) a) 00 ci 1J ca a.! U) cd a) v O ' 4J 'S7 a) ' ?rl Cd aj U) a) o" ?rl G U a) 4J r. .r., 0 4J U 4-1 DC a) U) cd 00 3-+ co U w u O rl Ll ul U) ?H 0 w a. a u 0 C 0 0 U) C cn rn -1 1- N I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 U O 0 ~ P. 4J U b 1 401 cA cd a) cn >`+ 4 41 cd k z w c d 41 . 4J J 4- }4 Cu P. r-I r~ z Q) 0 Lr) N I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 11 I  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1 i i t I Proceedings of the Royal Society of London. The enhanced solvent properties of polar gases in the supercritical region was demonstrated by Hagenback in Leipzig in 1901. Work by Frank (1956) investigated the solvent properties of supercritical water and the investigation of Eisenbeiss (1964) and Weale (1967) demonstrated the solubility of solids in compressed nonpolar and polar gases. The solvent properties of supercritical fluids was applied to the deasphalting of petroleum fractions even before 1950. Work at the National Coal Board's Coal Research Establishment at Stokes Orchards in the mid-1960's focused on liquids recovery from coal when heated above 750?F. In 1971 Paul and Wise in London described the principles of gas extraction as a means of liquefying coal. This technique has undergone further research by the National Coal Board in various size test units since the early '70's. Operating Facilities All work on the supercritical gas extraction process is being carried out at the National Coal Board's coal research Establishment facilities, Stoke Orchard, near Cheltenham. This research has progressed from a benchscale unit to the construction and operation of a 5 kg/hr continuous feed process development unit. This unit started operation in 1977. Design of a 25 tonne/day pilot plant have been completed which was to be located at the Point of Ayr in North Wales. The National Coal Board has recently made the decision not to construct this pilot plant. It is not certain as to whether or not research on this process will continue. Major Funding Agencies The National Coal Board has sponsored all funding for this process. However, the NCB has recently announced that it will shelve this process as well as their Liquid Extraction Process. The major technical problems facing this technology is scale-up of the current 0.1 tonne/day PDU to the proposed 25 tonne/day pilot plant. Capital Costs Capital costs for a commercial scale facility have not been published. However, the capital costs for the 25 tonne/day pilot plant have been estimated at # 14.8 m in 1978. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 BRITISH COAL LIQUEFACTION PROCESS 18. National Coal Board Liquid Solvent Extraction Coal Liquefaction Process Process Description The National Coal Board's Liquid Solvent Extraction (LSE) process utilizes anthracene and coal derived solvents to liquefy coal at a temperature of 420 to 450?C and at 20 bars pressure. The process actually consists of two stages, the liquefaction stage, and the hydrotreating stage. In the lique- faction stage the solvent also acts as a mild hydrogen donor. A process flow diagram for the liquefaction and hydrotreating sections is presented in Figures 1 and 2. In this process run-of-mine coal is fed to the coal preparation section where it is cleaned and dried. From here it is sent to a pulverizer where it is reduced to less than 0.2 mm in size. All coals, except for anthricite, can be used as feed regardless of caking properties. However, extract yields can vary widely depending on the coal feed. A cleaned fraction of coal containing approximately 6% ash is then fed to the slurry preparation section. The remaining diameter coal is sent to a gasifier for hydrogen generation or to the boiler for steam and power generation. The pulverized coal entering the slurry preparation section is mixed with a high boiling solvent, recycled from the hydrocracking unit, in the ratio of 3.5 ton of solvent to one ton of coal. This slurry is then pumped to a pres- sure of less than 20 bars and sent to the preheat section. This section consists of a heat exchanger where the slurry is heated by the liquefaction digester effluent, and a fired heater. The slurry enters the digester at 400?C where it is reacted for 30 to 90 minutes. Under optimum conditions as much as 95% of the coal's non-mineral matter can be dissolved. During reaction the solvent acts as a mild hydrogen donor to increase the extract hydrogen content as much as 2 percent. The effluent from the digester is then sent to the feed preheat exchanger for cooling and then into a gas/liquid separation vessel. In this flash vessel the pressure of the slurry is reduced and the lighter products are separated. The overhead stream is then cooled to condense out the C5-250?C fraction and water. The gaseous product can then be recycled or sold while the liquid bottoms from the condenser are separated to 1 t 11 t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I I 1.ellh 420' C EXTRACTION PRESSURE LET-MM NYDROCRACKER FEED (EXTRACT r r INKS M Figure 1. LIQUID SOLVENT EXTRACTION PROCESS SECTION SOLUTION LOW PREASUREISEEARATORN TO FRACTIONATION bm- TO FRACTIONATION _.T OAS Figure 2. HYDROGENATION UNIT FOR LIQUID SOLVENT EXTRACTION PROCESS B-139 O F G A S T E C H N O L O G Y N 5 TApprovedTFor Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 remove the water. The liquid bottoms from the flash vessel, which contain ash, are sent to a holding tank where they are fed batch-wise into a commer- cially available filter. The dried filtrate is then sent to the gasifier for hydrogen generation and the filtered coal extract is sent to storage. From storage the coal extract is mixed with recycled oil to adjust its concentration before it is pressurized and sent to the second stage hydro- treating section shown in Figure 2. This mixture entering the hydrogenation section is heated to 750 to 840?F and pressurized to greater than 2900 psi. Recycled impure hydrogen is added to the high pressure liquid, resulting in two-phase flow through the heat exchange and furnace heating zones. The hydrogen is scrubbed to remove some of the sulfur, nitrogen and chlorine com- pounds prior to injection. Make-up hydrogen for the proposed 25 ton/day pilot plant will be obtained by steam reforming natural gas. However, in a commer- cial size facility much of the required hydrogen will be generated by a gasi- fier from recycled filtrate, pitch and dirty coal. The hot extract and hydrogen gases are passed through a guard reactor to remove hydrocracker catalyst poisons. Two or more of these units will be operated in parallel to allow for continuous operation when one unit is regen- erated. The primary hydrocracking reactors are of conventional trickle bed design. A number of catalyst beds are used to limit temperature rise to a maximum of 45?F in each bed. Intercooling between beds with recycled hydrogen is also used to limit the temperature rise. Facilities are also included to regenerate the hydrocracker catalyst. Effluents from the hydrocracker are cooled by heat exchange with extract feed and are sent to a high pressure separator. Hydrogen rich gases con- taining some methane and other gases are recycled to the hydrocracker units after repressurization and scrubbing. Liquid bottoms are sent to the frac- tionation system. This system contains a vacuum column as well as atmospheric pressure crude fractionation units. The principle cuts include gases, C5(345?F) liquids, 345 to 480?F boiling range liquids and 480?F plus liquids. The primary product cuts are the two lower boiling range liquids. The 480?F + cut is used as recycle solvent. Alternatively, 700?F + cut can be produced and fed to a thermal cracker for production of a premium cut. The material balance for this process is shown in Figure 3. A process technology fact sheet summarizing the process is shown in Table 1. B-140 I N S T I T U T E 0 F G A S T E C H N 0 L 0 G Y I 7 t 1 11  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 pmt 1 ? 11-0 'v I i W c tt ION W W S O O W /lil Z O - ~y yid O ~ flit V Z W ~ O~ -o -a o - it I T I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 G 0 ?rl .0 U co 4 w 4-J rH 0 C co v v u a 0 4- '0 04 4 cd p 0 0 P~ ?rI 4.J 0 0 4~4 U Q) C Cr U 0 ~ V] 0 O LP) 4-1 0 a 0 0 4-1 Cn ?~+ 4J 1J U O N CO CA C 4J 44 0 1< w 0 u (1) 4- r-~ 0 0 4J ro cd 0 ~ 4- 1J 0 v U (n a cd 'd Q) UJ 1J Cn C u r> co u H 0 a CO 4-1 cd r-~ 4-1 v 0 cd 4- cd 0 u H ca 0 Cn Pa y 4-( U '-H ~4O 0 QJ C 3a U '-4 U b0 ro 0 ca C 1J u 0 CO jJ U] 4-J bA cd 0 C v 1J a1 cd H Q) 1-4 JJ 0 (n Q) 4 '0 r-.? 0 u 41 a 4J .n u CO (ll H ' -I r.4 a, It 4-4 0 (n W C 0 C H U u ni C QJ '?d LI xj a Q) cd -c 0 ~J U U) 0 0 ro 1-1 O ' ro LI 0 QJ v ro 0 O U C v 3 cd ro 0 b0 cd O H CU 4.J Ci 0 (n 0 F a1 1J Q) U C Cn % 0 4 1 41 .H 4-1 x 0 lJ O x W U) u U (n rn W U C (n co 'H (d aJ 4-4 H ~ 4- v O v U) 0 0 a1 C- o w 0 N Cn N la c ' -?I oa -d 0 ra 0 a) P. a 4J ..C m C O 1J P . 0 N (A 1J (n JJ aJ co M U C Q ~ 0 0 U w ro H ~ cd 4-I I CA (n U 'd U 1..1 0 0 0 u CI) o aJ H - 0 4_J C 0 u co E k U 4J O C V 0 QJ C1 O C 0 Q) Lf1 U 4-4 CA N 00 -7 +J -r-4 M -H 'd 'd m O LI C ?~ -H 0 4-i (Ti C C r ?I J.J a ~r 0 O (n r+ r+ 0 O 1, N O co r~ r-I U ~O -t N 60 t a t 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914RO J H I U u a 0 b a Pa H 4J 0 cd 0 44 H L7" Ga I 0a cd o z u I W 0 IE4 >~ 0 Ie zz w i E- I cd 4-I xH ca v H v a~ o ca ro cd H aJ a U 0 ai ti G Cd U ti v o a, q 0 x o 0 0 ro 0 0 a 0 w H ro 4i a) v ci .1 0 tl H +.. ca 4j 0 v 0 H P c ri ca a 0 H Pq Cd -0 Cd 0 E N L) ljc~ G CO H .H 0 Cd H a~ Cd 0 d) N ro w d z B-143 T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  pproved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 The overall process efficiency and product slate varies with coal feed type and end product requirements. Tables 2 and 3 present the product mix when using a bituminous coal or lignitic coal. Table 2 also presents process efficiencies for different plant configurations when pitch is used as a gasi- fier feed, SNG byproduct is recycled for process gas, and when both pitch and SNG are recycled. Overall process efficiencies can vary from 68% in the base case using bituminous coal to 60.2% when operating on a lignitic coal with 23% moisture and 20% ash. Process Goals The liquid solvent extraction process is being developed as part of a two-stage coal liquefaction process which involves extraction and product upgrading for the production of transportation fuels and chemical feedstocks. Testing in a 66 lb/hr PDU has been performed to determine operating parameters and performance. Continued research is also being conducted in the extract upgrading stage. The overall goal of this program is to establish the poten- tial of this process to operate on a commercial basis in an integrated self- sufficient mode. Future plans call for the construction of a 25 tonne/day pilot plant. However, construction of this pilot plant has recently been cancelled by the National Coal Board. Relationship to Prior Technology Development of the Liquid Solvent Extraction (LSE) process started in the early '60's at the National Coal Board's (NCB) Coal Research Establishment (formerly called the British Coal Utilization Research Laboratories) in Stoke Orchard, near Cheltenham. This work centered on the extraction of coal liquids by anthracene and other tar oils to produce carbon products and elec- trode coke. A 66 lb/hr process development unit was constructed in the early '70's to make electrode cokes to be used in the steel and aluminum smelting furnaces. This PDU is the basis for the proposed construction of a 25 tonne/ day pilot plant. In general this process is similar to the Solvent Refined Coal (SRC) process which also utilizes a coal derived solvent to dissolve coal at high temperatures and moderate pressures. Operating Facilities All research on the Liquid Solvent Extraction process has been carried out at the NCB's Coal Research Establishment facilities in Stoke Orchard near 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  I 1 1 A 1 a Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 2. EXAMPLE OF INTEGRATED LIQUEFACTION PLANT AND REFINERY PROCESSING A BITUMINOUS COAL Basic Pitch used SNG used for Both pitch case as.gasifier process gas and SNG used feedstock in process Product Slats (ton/100 tom d.a. f. coal) Gasoline 9 91..5 10 11 Diesel and jet fuel 23, 25 27 30 Pitch 6 0 T 0 LPG 4 5 5 6 Substitute natural gas 9- 9- 0 Coal input (ton d.a.f./ba rrel 0 transport fue ls prod uced) - to process 0.25 0'.25 0.25 0.25 - to gasifier 0.14- 0.10 0.08. 0.04. - to boiler 0.03. 0.03 0.03. 0.03 Total: 0.4Z 0.3& 0.36 0.32 Barrels liquid fuels/ ton, d.a.f. coal 2.4 2.6? 2.& 3.1 Overall thermal efficiency (Z) 6& 66- 65 63 Table 3. EXAMPLE OF INTEGRATED REFINERY PROCESSING A LIGNITIC COAL (23% moisture, 20% ash) Product Slate (ton/ton d.a.f. coal) Gasoline 16 Diesel and jet-fuel 19 Pitch 0 Substitute natural gas 0 LPG 2.3 Coal input (ton d.a.f/barrel transport fuels produced) to process 0.27 to gasifier 0.07 to boiler 0.05 Barrels liquid fuels/ton d.a.f. coal 2.6 Overall thermal efficiency 60.2 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Cheltenham. This research has progressed from bench scale studies in the '60's and early '70's to the construction of a 66 lb/hr PDU in the mid- '70's. Photographs of the 1st stage PDU liquefaction unit and the 2nd stage hydrotreating section are shown in Figures 4 and 5, respectively. Future plans called for the construction of a 25 tonne/day pilot plant to be located at Point of Ayr, North Wales This project has recently been cancelled. I 1 t Figure 4. SOLVENT EXTRACTION PLANT AT THE COAL RESEARCH ESTABLISHMENT I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 t a t 1 Figure 5. HYDROCRACKING PILOT PLANT OF THE COAL RESEARCH ESTABLISHMENT Major Funding Agencies The National Coal Board has sponsored all funding for this process to date. Funding for the $100 million 25 tonne/day pilot plant would have come from the National Coal Board, Commission of the European Communities ($10 million) and Phillips Petroleum. Recently British Petroleum which was also a co-sponsor withdrew their support to the project. If pilot plant testing had been successful, future plans called for the construction of a 1,000 ton/day semi-commerical plant in an overseas market in the late '80's. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Technical Problems The two areas of most concern are the solid/liquid separation section and the catalytic hydrocracking/extract upgrading section. In the filtration section hot batch filtration has been tested in a 1100 lb/day unit used for electrode coke production. However, a continuous unit has not been tested. The batch unit was able to reduce ash content in the liquid extract to below 0.1 percent. Although this type of hot filtration is more expensive than other separator techniques it is anticipated that the filtration section will still account for less than 10% of the capital costs. In the PDU a glass fibre cloth with a particle size retention of 0.5 um was used successfully, but its weakness and lack of rigidity make it unsuitable for the continuous high temperature operation required in a commercial facility. An alternative precoated wire screen method has shown promise in experimental runs but screen size and precoat material selection has yet to be optimized. Alternative precoat materials to Celite are being investigated which are made of carbon- aceous materials. The spent precoat containing ash can then be sent to the gasifier or combustion section for disposal, thereby decreasing plant waste. Research on the hydrocracking section has focused on catalyst selec- tion. Over 50 different catalysts have been tested in a stirred autoclave for their lifetime, resistance to contaminates, and kinetic properties. Alter- natives to catalyst poisoning include designing an extract cleaning system to remove deactivating agents before they reach the catalysts. Capital Costs Capital costs for a commercial scale LSE process plant have not been published. The capital cost of the 25 tonne/day pilot plant was expected to be $100 million. 1 t 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t t BRITISH DIRECT COAL COMBUSTION PROCESS 19. National Coal Board Pressurized Fluidized Bed Coal Combustion Process Process Description The Pressurized Fluidized Bed Coal Combustion (PFBC) process is being developed for combined gas/steam cycle utility power generation. Research in this area is being conducted by the National Coal Board (NCB) in a 5 MW test facility at Leatherhead. A typical flow diagram of a PFBC combined cycle utility power plant is shown in Figure 1. The concept involves burning coal in a fluidized-bed of calcium-containing mineral such as limestone to absorb the polluting sulfur in the coal. The sulfated limestone is removed from the combustor and discarded for land fill applications or regenerated for elemen- tal sulfur recovery and reuse in the combustor. In the pressurized combustion concept, the generated hot flue gases are expanded through a turbine to generate electricity. The fluidized-bed boiler furnace section consists of an enclosed space with a perforated base to admit combustion air. Part of the enclosed space directly above the air distribution plate is occupied by a layer of granular material such as sand or limestone. The air, which is forced through the supply plenum is sufficient to lift (fluidize) the bed and suspend it in the airstream. This promotes violent boiling (mixing) and agitation of the bed material. After fluidization has occured the combustible fuel is introduced and ignited. The bed material absorbs the heat of reaction and transfers as much as 50% of it to immersed water tubes and waterwalls. The waterwall tubes, which surround the inner fluidized-bed walls, maintains the wall temperatures within a safe operating range. The optimum operating temperature is between 1500? and 1700?F. When a high moisture content fuel such as wood wastes or municipal refuse is burned, the heat required to evaporate the moisture in fuel maintains the bed temperature within acceptable limits without the use of waterwall cooling tubes. Because of the enhanced heat transfer characteristics of the fluidized bed, the unit is smaller than a conventional boiler of the same output. In order to take advantage of the heat transfer mechanism and to limit the tem- perature, the bed may be divided into a number of cells each surrounded by waterwalls. The heat of the gas leaving the combustion zone is removed by conventional convection heat-recovery equipment. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Figure 1. SUPERCHARGED BOILER COMBINED CYCLE 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 a 1000 hour testing phase. This testing in Leatherhead has recently completed program also involved Stal-Laval, Combustion Systems Ltd., and Babcock International. The fluidized bed com- bustor configuration used in the Leatherhead facilities is shown in Figure 2. This unit incorporates a range of superheater and reheater tube alloys testing at bed temperatures typical conventional boiler. The bed has a can operate at pressures of up to 6 bars to those that would be encountered cross-sectional area of up to 0.84 in a m2 and at heat inputs of 5 MW. 1. Compressed air inlet 2. Water inlets and outlets to tube bank circuits 3. Baffle tubes in freeboard 4. "High level" bed offtake 5. Tube bank 6. Start-up burners 7. Coal nozzle 8. Air distributor 9. Bed offtake 10. Corrosion probes 11. Air cooling supply to corrosion probes 12. Gas offtake baffle 13. Mixing baffle 14. Gas splitter 15. Corrosion indicator probes 16. Zirconia-cell oxygen probes I Figure 2. ARRANGEMENT OF FLUID BED COMBUSTOR Mk VI 1 1 The combustion gases leaving the 5 MW PDU are split into two streams as shown in Figure 3. In the initial testing period each stream had 3 cyclone dust collectors in series for particulate removal. Each stream then proceeded to a cascade of turbine blades that serves as a turbine blade test unit. One cascade was supplied by Stal-Laval and the other by GE to test gas turbine alloys exposed to combustion gases with relative velocities of up to 525 m/s. The gas cleanup cyclones were effective at removing most particles larger than 10 microns. The particles that did not reach the cascade blades were rela- tively soft. After 650 hours of operation the Stal-Laval stream was modified I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 by removing one of the cyclones to increase particulate loading. After 1000 operating hours the cascade systems were dismantled to check for wear and corrosion. With the exception of minor ash buildup which did not affect performance, none of the coated blades or specimens in either streams showed signs of corrosion attack. Stream 1 2? cyclone 1 ? cyclone iet-gown--' - hopper] 2? cyclone 1 ? cyclone 1. Dust sampling (CURL) 2. lkor probes 3. PMS laser and impactor 4. Spectron laser 5. Dust sampling (NYSERDA) and ionization alkali monitor 6. Gas analysis (O,, CO,, CO, SO2, NO,) 7. SO3 analysis 8. Spectral alkali photometer 9. Electrostatic charging 10. Electrostatic charge sampler 11. Propane injection (reheat) Figure 3. TEST FACILITY The 3 foot by 2 foot cross-section bed is usualy operated with an 8 foot deep fluidized-bed. The bed normally operates in the temperature range of 700?C to 950?C and at about 6 bars pressures. Combustion efficiencies as high as 99% have been achieved when operating with 30% excess air and a fluidizing velocity of 5 feet per second. When operating on 3% sulfur coal over 85% of the sulfur was retained in the bed. This bed contained 1.5 times the stoich- iometric quantity of dolomite required to retain the sulfur. Due to the small size of the Leatherhead facility scale up to a 500 MW pilot plant was deemed too risky. Therefore, an 80 MW experimental pilot plant was constructed at Grimethorpe for futher testing. The overall flow diagram for this facility is shown in Figure 4. The combustor (Figure 5) is designed to operate at 12 bars and has a 14 meter height and 4 meter outside diameter. When operating at maximum capacity this 2 m x 2 m cross-sectional area combustor operates with a fluidizing velocity of 2.5 m/s, a bed temper- 1 t 1 s  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 ature of 850?C, and an air mass flow of 31 kg/s. This unit can handle 10 tons/hr of coal with a top size of 6.4 mm. Coal mixed with the limestone or dolomite S02 sorbent is fed into the bed via a Petrocarb feeder at nine injection nozzles. The calcium to sulfur mole ratio to achieve 90 removal of the SO2 is 2.6. Figure 4. OVERALL FLOW DIAGRAM t The fluidized bed has a maximum depth of 4.5 meters and contains a bank of evaporator tubes. The water-cooled walls extend an additional 4.5 meters above the expanded bed height. This 4.5 meter freeboard is designed to pro- vide space for larger entrained particles to settle out and return to the bed. The freeboard area also contains a small band of heat exchanger tubes for com- bustion gas cooling in the event of excessive above bed burning. The combus- tion product leaving the top of the PFBC unit is split into four streams for feeding into four primary cyclones arranged radially around the combustor. Each primary cyclone is connected to a secondary cyclone where the cleaned gas finally exits into a common header. From here the gas is cooled to below 300?C before pressure letdown, silencing and exiting into a 90 meter tall flue stack. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Air inlet Furnace hood Freeboard cooler inlet Support bracket Furnace support steelwork Freeboard cooler bypass_ Pressure shell-30mm thick Internal insulation rated at 150 kW Internal access galleries Coal feed nozzles Distributor plate Furnace water wall inlet Distributor Pressure shell bottom flange- Pressure vessel bottom dome Coal inlets C d e g 3270 h i 4880 Figure 5. COMBUSTOR PRESSURE VESSEL 6000 During testing tube bundle configurations and dust collection equipment will be modified to record system performance. Part of this testing will involve passing combustion gas through a tertiary cleaning system and then expanding it through a cascade of gas turbine blades to obtain additional performance data. These gases leaving the cascade will be cooled and depres- surized in a separate system. The first phase of testing is envisioned to require 2900 hours and take 24 to 30 months to complete. Testing started in April 1981. A technology fact sheet for this process is shown in Table 1. 1 1 1 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I zO i W a) 0 0 Co a) E r4 b 0 ro r1 cO o ?r1 N 1- 1n C) b r1 P: a) co U) 'G 41 U CO a) 0 ,n I ?r1 0 \ O O O1% Ln N 0' O1 r1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 aD U 0 ' -I U ?r1 cd 4I O 0 U 4-I H m a a) a -J 0 CO 4-I G 0 O a) U U Ln r, 0 r.{ >4 lJ ca C7 O ca O U 4) a) C O .ty a. 0 Pa O Iz b 0 4-4 ---I O 44 a) - 1 P q U z a) ca O co 0 a) Sa O N 4-3 a) En >-1 cd U 0 U Pq a) a) r, u a 41 z 41 p a) H a) 4J tw U cd ca 4-4 4-I O a) a) M r-I P. a) 0 ' -I 41 )a p co O 3-i aq a) a) w 0 a 0 co c7 u .r1 ? G a) G H G H ca a) aI 4J{ N 0 0 0 1 1 1 t t I I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  1 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Process Goals Testing in the 5 MW PFBC reactor at Leatherhead has established the steady state operating performance of this technology at 6 bars pressure. The 80 MW pilot plant at Grimethorpe is designed to provide a wider range of operating conditions for pressures up to 12 bars. This testing program is designed to: ? Determine combustor performance and pollution emission levels of a wide range of operating conditions at elevated pressures ? Establish system performance for different coal feedstocks; two different U.S. and West German coals will be tested in addition to U.K. coals ? Provide part-load data and dynamic response data for systems control design. Assess system performance effects when design changes are made, for example, elimination of some of the coal feed nozzles or changes in bed or freeboard heights. 1 1 ? Determine corrosion behavior of tubes submerged in the fluidized bed as well as those subjected to particulates in the freeboard. Relationship to Prior Technology Though fluidized-bed combustion is often divided into the two distinct areas of atmospheric and pressurized technology, the two technologies have common development roots and several common research concerns. Because of the similarities of the technologies, in this report they will be treated in an intermingled manner. The concept of the fluidized-bed was invented in the 1920's as a means to promote chemical reactions. By the early 1940's, the fluidized-bed concept was in commercial use for petroleum cracking. By the late 1950's the fluidized-bed technique was commercially successfully for metallurgical heat treatment and ore roasting. Hundreds of these units have been sold. In the late 1940's, several U.S., British, German, and French companies began development of fluidized-bed combustion sytems. A French design, which features two-staged coal combustion, was not a market success. In the late 1950's, the British National Coal Board's (NCB) Coal Research Establishment operated by the British Coal Utilization Research Association I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 (BCURA) continued earlier work by Douglas Elliott of Britain's Central Electricity General Board (CEBG). General lack of interest in coal due to low cost oil and gas slowed research. By the late 1960's, however, interest in fluidized-bed coal combustion was prompted in Britain by the NCB's desire to sell coal worldwide and by the emergence of future oil supply problems. In 1968, Elliott developed the concept of pressurized fluidized-bed combustion. Under his direction, a 5 MW (thermal) unit was commissioned in 1969. Though the NCB proposed a 20 MW pilot facility in 1971, the British Government and the CEGB refused funding. In the United States, Michael Pope of Pope, Evans, and Robbins (PER) won support from the U.S. Office of Coal Research (OCR) in 1965 to build three atmospheric fluidized-bed test units. The largest of these units, a 0.5 MW (thermal) unit, was first operated in 1965 at Alexandria, Virginia. Foster Wheeler Corporation and Combustion Power Company were carrying out limited fluidized-bed combustion research by 1970. The phenomenon of greatly reduced sulfur emissions was first reported as a result of PER's work with OCR in 1968 using the Alexandria, Virginia test facility,. In 1972, OCR provided funds for PER to build three protoype atmospheric fluidized-bed boilers. The first was built at Alexandria, Virginia. Environmental concern and the EPA led to a joint EPA/NCB program aimed at sulfur dioxide and nitrogen oxides control using fluidized-bed combustion. The program indicated that up to 95% of the sulfur in high sulfur coal could be captured by fluidized-bed combustion. With OCR funding, PER built a 30 MW unit at Rivesville, West Virginia in 1972. The formation of ERDA after the OPEC oil embargo resulted in $19.8 million in U.S. Government funding for fluidized-bed combustion in 1975. Recent development in Europe has had a more commercial orientation than in the United States. In 1972, Douglas Elliott of the NCB and a partner founded Fluidfire Development, Ltd. The company has developed and success- fully marketed heat treatment furnaces, refuse burning boilers, and flue heat recovery units using fluidized-bed designs. The company has been aggressive in concept development; one development has been a fluidized-bed boiler with a bed depth of only a few inches. In one configuration, a novel method of con- trolling the boiler was developed by varying the position of the fluidized-bed around the heat exchangers. 1 1 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Similarly, with commercialization intended, the NCB sponsored converting the boiler at the Babcock and Wilcox, Ltd. factory in Renfrew, Scotland to fluidized-bed firing in 1974. By August 1975, the 40,000 lb/hr unit was in operation. The 10 ft2 bed operates at 400 psi and 560?F. The unit which is started up by oil-fired overhead burners now operates on oil. However, its original testing program included coal firing; up to 98% sulfur retention was noted with 3.6% sulfur coal and a limestone bed. After testing, and to date, no loss in bed tube material has been observed. The unit's turndown ratio is 4:1. In 1976, Babcock and Wilcox, Ltd. announced that units would be made available with a warranty for production of up to 500,000 lb/hr of steam. The NCB has sponsored other small conversions as well as including the conversion of an 80,000 lb/hr boiler operated by British Steel Corporation. This unit was to be commissioned in 1978. Operating Facilities The National Coal Board has operated a PFBC unit with a 5 MW rated capa- city at its Coal Utilization Research Association Laboratories (BCURA, now CURL) in Leatherhead. Over 3000 testing hours have been logged on this unit with operating pressures of up to 6 bars. Initial bench scale studies at the NCB's Coal Research Establishment (CRE) labs provided the data for the Leatherhead facility. In 1977 the International Energy Agency started construction of the 80 MW Grimethorpe facility which is based on the research data from the Leatherhead facility. Cold flow commissioning began in October 1979 and hot commissioning started in September 1980. Cold flow tested required an additional two month period due to mechanical problems in the ancillary equipment. The first phase of the experimental program at Grimethorpe started in April 1981 which will involve 2900 hours of testing over a 2 to 2-1/4 year period. Major Funding Agencies PFBC studies which started in 1969 and much of the laboratory work since 1972 has been sponsored by the U.S. DOE in cooperation with other U.S. organi- zation. These include the Electric Power Research Institute, American Electric Power (AEP) and General Electric. Funding for the 80 MW PFBC facility at Grimethorpe in Yorkshire was provided by the International Energy Agency.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Technical Problems Although much of the experimental work to date has concentrated on the reactor design, material problems and turbine blade performance, little research has been done on coal feeding problems. In the current approach, coal is dried and crushed to a compatible size dependent on the pressurized fluidizing gas velocity. For example, for a fluidizing velocity of 1.2 m/s a coal and dolomite mixture with a top size of 3 mm would be required as feed. Based on the current use of nozzles to inject the coal into the PFBC reactor, one nozzle is required for each 1.5 m2 of bed area. Therefore, for a 200 to 250 MW(e) plant over 50 coal nozzles would be required to feed the coal into the reactor. Larger nozzles or a less complicated feed system is required to make large commercial plant operation feasible. In addition to reducing the number of nozzles required, it would be advantageous to increase the maximum allowable coal size range to 30 mm. Large coal of this size has been experimentally combusted in a fluidized bed with no problems. However, if noncombustible materials accumulate within the bed, performance can be degraded. A larger coal size distribution will require new nozzle design, especially when handling wet run of mine coals. This large size distribution will also require better fluidizing bed con- trol. In may be desirable to use a circulating bed which will recycle the dust overflow back into the bed. The final area of concern is increases to overall plant efficiency for the PFBC combined cycle plant. Current efficiency is estimated to be in the range of 39 to 40 percent with reheat of the steam system and a gas turbine inlet temperature of 800?C. This performance is 5 percent better than a conventional coal burning power plant with flue gas desulfurization to reduce S02 while burning a 3 to 4 percent sulfur coal. Higher efficiencies of 45 percent can be obtained by increasing gas turbine inlet temperatures to 1100?C. However, slag formation which will bond to turbine blades is likely at this temperature. A secondary combustor may be required to reach this temperature by heating the PFBC reactor output. Fuel for this after burner stage may be produced in a preliminary pyrolysis/gasifier stage of the PFBC reactor. t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 Capital Costs Reduction of capital costs of 12 percent and a decrease of operating costs when compared with conventional coal combustion power generation have been predicted. The 80 MW pilot plant at Grimethorpe was constructed at an estimated cost of $10 x 106 in 1978.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 BRITISH COAL GASIFICATION PROCESS 20. Esso Chemically Active Fluidized Bed Coal Gasification Process Process Description The Esso Chemically Active Fluidized Bed gasification process (CAFB) has been tested in a 150 kg/hr reactor. A schematic of this pilot plant is shown in Figure 1. The pilot plant consists of a fluidized bed reactor where fuel is partially oxidized at 900?C within a bed of lime particles fluidized by air. A top coal size of 3000 microns can be fed into the gasifier. Over 80% of the sulfur in the fuel, either oil, gas or coal, is retained by the lime when it is converted to CaS. In addition to sulfur, metals within the coal structure such as V, N, and Na are also retained in the lime bed. The spent lime material is then transferred from the gasification reactor to the ad- joining regeneration fluidized bed reactor. In this reactor the CaS which was formed in the gasification reactor is oxidized back to lime and SO2 at 1050?C. Cyclone Coal -? Air - Lime 900 ?C Gasifier -~ Raw Gas 1050 ?C Regenerator 1 Bed Drain Air Bed Drain Cyclone Figure 1. FLOW DIAGRAM OF ESSO CHEMICALLY ACTIVE FLUIDIZED BED GASIFICATION PROCESS During the reaction in the gasification vessel the coal undergoes pyrolysis to release large concentrations of condensible hydrocarbons. In actuality only partial gasification occurs and large quantities of low sulfur char is produced as a by-product. Tests results using Illinois No. 6 and the Texas lignite coals shown in Table 1 are presented in Table 2. A summary of the sulfur removal affectiveness of this process when operating on the Illinois and Texas coals is shown in Table 3. A technology fact sheet summarizing this process is presented in Table 4. B-162 G A S  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. ANALYSIS OF ILLINOIS NO. 6 AND TEXAS LIGNITE FED TO CONTINUOUS UNIT Illinois No. 6 Texas Lignite Actual Dry Basis Actual Dry Basis x x x x 1 Moisture 4.63 - 14.02 - Ash 7.36 7.80 18.50 21.50 Carbon (corrected) 70.3 73.64 51.20 59.50 Hydrogen (corrected) 4.61 4.83 3.60 4.20 Sulphur (total) 1.78 1.90 0.82 0.95 Nitrogen 1.44 1.50 1.00 1.20 Oxygen+errors (by 9 85 10 40 10 90 12 60 difference) Gross calcries/GM . 6936 . 7260 . 5004 . 5817 Gross Btu/lb 12486 13068 9007 10470 CO2 (x) 0.16 - 0.51 - Table 2. COMPARISON OF GASIFIER GAS QUALITY FROM FUEL OIL AND COAL Gasifier Fuel Heavy Fuel Oil Illinois No.6 Coal Texas Lignite Nitrogen + inerts 58.4 59.2 59.0 Carbon monoxide 10.2 12.2 12.2 Carbon dioxide 10.2 9.9 12.1 Methane 7.7 4.2 2.2 Ethylene 5.0 0.8 0.7 Ethane 0.1 0.1 0.1 Hydrogen 8.4 13.6 13.7  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 3. SUMMARY OF DESULPHURIZING PERFORMANCE DURING MINI-RUN ON COAL Coal (type and size) Mean % SRE on Coal Expected Result on Oil (X SRE) SO Emission (16502 per 10 Btu) Illinois No. 6 (1405p. down) Texas Lignite 74.8 73.8' 0.73 (800 down & 64.0 68.5 0.76 1405 down) Texas Lignite (1/8" down) 82.4 67.2 Process Goals The objective of this development is to develop a commercial coal or oil burning gasifier which can remove sulfur from pollutants from the fuel and can be easily integrated with existing gas-fired boiler plants. Research on the operating range and performance of this gasifier is underway. Also being examined in the long term affect of coal ash on the sulfur absorbing proper- ties of the line bed material. Relationship to Prior Technology The concept of the Catalytically Active Fluidized Bed process was first developed in 1967 and was originally applied to the desulfurization of fuel oils. In 1975 this concept was extended to the use of coals in a batch test at Abingdon, U.K. However, the concept of removing sulfur compounds from gas using a limestone absorbent is not new. This approach has been applied to sulfur removal from stack gases as a pollution abatement process. Operating Facilities Esso Petroleum Company Ltd., Abingdon, Oxon, U.K. has operated a 150 kg/hr process development unit at the Abingdon test facilities since 1975. A 20 MW pilot plant unit has been proposed for operation at the Texas Central Power and Light Company which will operate on Texas lignite. 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 ro .n u -4 0 co 0 Cu Lr) ' -I 1J Cu ?H 4-i 3 4a Cu U) c/] H 0 4.4 b a Cu .r, m a) b co .H 'C M N V 'C N N N N -H ?rl U) , I 0 }a :j cd C ca rl 0 0 C 4-I U CT U  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 . a ?a a a  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Major Funding Agencies Esso Petroleum Company Ltd. and the U.S. Environmental Protection Agency have provided the funding for this process. Technical Problems No technical problems have been reported in the literature. Capital Costs Capital costs for this process have yet to be published. 32(3)/process/ER t I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 AUSTRALIAN COAL CONVERSION PROCESS 21. CSIRO Flash Pyrolysis Coal Liquefaction Process Process Description The Commonwealth Scientific and Industrial Research Organization - Division of Fossil Fuels (CSIRO) high speed pyrolysis process utilizes a fluidized bed reactor to convert pulverized coal (0.2 mm in size) to tar, gas and reactive char. The reactions occur in an oxygen-free atmosphere at about 600?C and atmospheric pressure. Reaction times of about 1 second are main- tained followed by rapid quenching of the product. The tar, which can amount to more than 30% of the m.a.f. coal feed, is then hydrogenated to lighter grade liquid fuels. Some of the product gas and char are used to produce hydrogen for the hydrogeneration reaction. A plant layout chart and flow diagram of the flash pyrolysis process are shown in Figures 1 and 2, respec- tively. The goal of this program is to determine the technical and economic fea- sibility of the flash pyrolysis process on Australian coals for the production of liquid fuels. The CSIRO process is also being tested for the pyrolysis of wood wastes, the production of olefins from coal pyrolysis, and the production of carbon anodes from coked flash pyrolysis tars. Relationship to Prior Technology The flash pyrolysis process has been studied by various groups for the last 30 years or more. Experiments have been performed in laboratory bench- scale units to nearly commercial scale-pilot plants. Electric power has been produced by electric utilities in the U.S. and West Germany using char pro- duced by the pyrolysis process. Operating Facilities The CSIRO research effort on flash pyrolysis started in 1974. A 1 to 3 gram/hr fluidized-bed pyrolysis reactor and a 100 gram/hr entrained bed pyrolysis reactor have been in operation since 1975. In 1977 a 20 kg/hr process development unit capable of operating in either the fluidized bed or entrained bed mode was commissioned. This unit was converted to an integrated facility in 1980/81 incorporating the pyro- lyzer, a char-burning heat generator and an on-line tar hydrogenator. B-168 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I COAL PREPARATION HEAT GENERATOR TAR COLLECTION 1 TAR HYDROGENATOR HYDROGEN PRODUCTION I GAS I I SYNTHETIC CRUDE OIL Figure 1. LAYOUT OF COUPLED PYROLYSER - POWER PLANT INSTALLATION PROBE DISTRIBUTOR PLATE Figure 2. FLOW DIAGRAM OF 20 kg h f FLASH PYROLYSER I N S T I T U T E O F G A S T E C H N O L. O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Operation of this facility, which started in late 1981, will provide the necessary data for the construction of a 1 tonne/hr pilot plant. The CSIRO work has been carried out within the Organization mainly by the Division of Fossil Fuels and and Division Applied Organic Chemistry. Outside CSIRO, support has come from the Australian Mineral Development Laboratories, and the Universities of Sydney and Queensland. A version of the CSIRO laboratory-scale reactor has been built at the University of Waterloo, Ontario, for the pyrolysis of wood-waste. Another version has been built by DuPont at Wilmington, Delaware, to study the production of olefins by flash pyrolysis of coals at temperatures around 900?C. In the CSIRO laboratories a second PDU-scale rig has been operated for the Aluminum Development Council, by COMALCO, to determine if flash pyrolysis tars can be coked to produce a substitute for petroleum coke used in carbon anodes for aluminum smelting. COMALCO are also building a version of the laboratory-scale rig as part of the carbon anode project. Major Funding Agencies Funding on all synthetic fuels programs in Australia amounted to about $10 x 106 in 1979-80. The CSIRO spent $5.07 X 106 in 1979-80 in synthethic liquids fuels research. Part of this money ($420,000) came from the National Energy Research, Development and Demonstration Council (NERDDC) which itself total budget that research. Technical Problems Agglomeration of small scale reactor. pyrolysis. Oxidative year of $5.05 X 106 for synthetic liquid fuels coal in the fluidized bed reactor was a problem in the Nearly all coals show some plastic behavior during flash pre-treatment will reduce agglomeration but will also reduce tar yields. However, agglomeration did not appear to be a problem in the larger size reactors. In addition to caking tendencies, the coals cation content effects yields. In general, for a given coal, as the cation content increases, the tar yield decreases. Acid washing of the coal can be used to decrease cation content. Capital Costs The capital costs and operating costs for the CSIRO flash pyrolysis process are shown in Table 1. All costs are in late 1980 dollars. An Australian Millmerran coal was assumed to be the feedstock. B-170 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. CAPITAL AND OPERATING COSTS FOR 40,000 BARRELS PER DAY CSIRO FLASH PYROLYSIS COAL LIQUEFACTION PLANTS Capital Costs ($106)* Feed preparation 60 Pyrolysis and product recovery 274 Primary liquid hydrogenation (1) 448 1 1 1 2. Offsites, utilities, engineering and design 312 3. Estimating contingency, work capital, initial catalysts and chemicals, and start up costs 4. Total capital investment 1483 Operating Costs ($106 p.a.)* 1. Raw materials Feedstock 137 (2) Water 4 2. Other Maintenance 44 Taxes, insurance and overheads 33 Operating labor and supervision 11 Catalysts and chemicals 12 Purchased fuel gas and electricity - (3) 1 3. Credits for ammonia and sulphur byproducts -4 4. Net operating costs 237 Notes. (1) Includes H2 production (2) Cost at $1/GJ, based on $28/tonne dry, opportunity cost. Cost shown net after allowing byproduct char credit at $1/GJ. (3) All requirements produced from pyrolysis gas and coal char.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 b 0 U U) U) (3) U 0 P a) U) 0 ,.{ 0 U) i.j ri J-) 0 0 r-L E co U) cc co U) H U .r{ 4-1 U) 0 U a) v r1 U) .r{ 3 cd a) ro 3a a) H U 4J a) H O 0 U 0 O O ~O ~"+ E-4 a C13 .u U U) ?r1 0 P a Vl W O U 0 H X00 U 00 o ,n Z C 0' U) a) ?rl -I 34 l H 1J 0 0 1 'O b 0 U U) I U) d -i N 00 It Ln N N N -I N r4 O O O O O N "t o O -O O 1O O -t -t .-1 O U'l M O -1 O O N O 1O N N 00 00 -t N It U-) N r-I 0 0 O O CI) Lrl 00 O N CY) Lfl 00 It M N 1t N O O O O cV M irl o -t M O ~.O 00 Lr, M L( -I -D N O O O O O N ~O 00 a, 1J U ~ o co 4J O 0 ,-I O U ?rI tO t- m 4-J CD -I U I co -0 0 - a) 3 cc ca w w m >-+ ?~ ~4 41 +-J s x x x x ro cu 0 0 = cV N m m a H H H U U U U U U  Approved For Release 2 1 a U)I Cu .rq U) > ca 0 ~,? 1J a? u v as w a o ,-i 0 H o a 4 44 a~ 7~+ N a) N b 4-4 H ~y U a) E tV - ~ .c s W 0-4 0 H 4-1 r-1 a) U) 8 co 0 Q) lJ Q ?r E a) v u 0 N 0 0 a -0 a) cd U) 3 N o a) .u u ai cd v a) x v cd N g ?,~ b b ca 44 n7 a) 'ca ~ o U a) P4 O u to 4- o G 0 4.1 ca J..) 0 I N S T I T U T E 0 F Approved For Release 2007/02/20: 6IASRDP83Mb0514cRC61a06b6b0'P8-  POLISH COAL LIQUEFACTION PROCESS 22. Polish Central Mining Institute Catalytic Hydrogenation Coal Liquefaction Process Process Description The Central Mining Institute, Division of Carbochemistry, has developed a catalytic hydrogenation coal liquefaction process. In this process, coal is first crushed and dried before entering a ball mill where it is ground to less than 0.5 mm. The prepared coal is then fed to a mixing tank where recycled process solvent is form a slurry. The slurry contains approximately 28.6 wt % coal and 71.4 wt % recycled solvent. The recycled solvent is actually a mixture of .44 vol. % anthracene oil and 56 vol % high boiling range recycled oil. The properties of this solvent are presented in Table 1. From the slurry preparation tank the mixture is heated and sent to the extract mixer column where the coal is reacted with the solvent. Coal reac- tion time in this reactor is about 50 minutes. The reaction proceeds at 410?C and at 45 atm. The mixture exiting this reactor is then hot filtered to remove mineral matter and unreacted coal residue. After filtration the coal oil enters a vacuum distillation unit where the more volatile oils are separated. Bottoms from the distillation unit and filtrate cake are sent to a carbonize r. 1 I I Table 1. PROPERTIES OF RECYCLED OIL SOLVENTS (Hydrogen Donor) Specific gravity at 20?C, g/ml Ultimate analysis (maf),wt% 1.02 Carbon 90.92 Hydrogen 8.64 Sulfur First drop boiling/initial boiling point ?C Fraction boiling to 360?C, vol% 0.31 Fraction boiling to 400?C, vol% 97.8 T E C H N O L O G Y I NA~$prbv6dFoP RIlease 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t The low-ash extract produced in the vacuum distillation unit is then processed in a catalytic hydrogenation unit. The coal extract entering this unit contains about 50% liquids with a boiling range above 400?C. Hydrogena- tion occurs in the presence of a nickel-molybdenum catalyst at 240 atm and at 400?C. The hydrogenated liquids are then sent to an atmospheric distillation unit where the low and middle boiling range liquids are separated from the high boiling range (>400?C) liquids. The high-boiling range hydrogenation product is then vacuum distilled. Recovered oil from the vacuum distillation unit is recycled to the slurry preparation section for use as the hydrogen donor solvent, and the bottom residue is carbonized. The property of the coal used in pilot plant testing is shown in Table 2. When operating on this coal the properties of the low-ash extract and liquid products from the hydrogena- tion unit that can be expected from this process are shown in Table 3. These properties reflect operation of the process under the conditions in Table 4. The technology fact sheet for this process is in Table 5. The light liquids products are reported to be suitable for further refining into motor fuel products. Process Goals This process is being developed in Poland by the Central Mining Institute's division of Carbochemistry at Tychy-Wyry. Research is being per- formed to determine the operating parameters of the process under various operating conditions. Particular attention has been focused on the selection of a sulfur-tolerent catalyst for use in the hydrogenation reactor. The following process steps are also being investigated. ? Coal/solvent slurry preparation ? Coal extraction with and without hydrogen ? Extract residue separation ? Extract solvent recovery/distillation ? Extract residue low-temperature carbonization ? Extract hydrogenation ? Hydrogenation product distillation. Research has also been conducted on the production of electrode coke, binders, and carbon absorbents from the coal liquids products. B-175 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Moisture, wt% Ash (dry basis), wt% Volatile matter (maf basis), wt% Elements (maf basis), wt% Carbon Hydrogen Sulfur Petrographical composition, wt% vitrynite Egzynite Inertynite Mineral matter Heating value, kcal/kg 79.33 5.52 0.58 73.0 9.0 13.0 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 3. THE PROPERTIES OF THE COAL EXTRACT AND LIQUID PRODUCTS AT THE 1200 kg COAL/DAY PLANT Products Property Coal Extract Light Liquid Product Heavy Liquid Product Water content, wt% trace 0.3 trace Ash (dry basis) wt% 0.10 trace 0.16 Specific gravity at 20?C, g/ml 1.22 1.08 1.13 Ultimate anlysis (maf basis), wt% Carbon Hydrogen 6.50 7.56 6.95 Sulfur Benzene insolubles, wt% 14.6 1.2 9.5 Asphaltene, wt% 5.6 1.3 12.3 Oils, wt% 79.8 97.5 78.2 Initial b.p., ?C 262 93 247 Fraction boiling to 200?C, vol% -- 3.0 -- Fraction boiling to 320?C, vol% 1.5 46.4 7.5 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 4. PROCESS CONDITIONS OF THE CENTRAL MINING INSTITUTE CATALYTIC HYDROGENATION COAL LIQUEFACTION PROCESS 1. Extraction 1.1. Coal content in the slurry wt % 28.6 1.2. Feed rate of the slurry 1/hr 14.8 1.3. Reaction time min. 50 1.4. Pressure atm. 45 1.5. Temperature ?C 400 2.1. Temperature ?C 233 2.2. Filtration rate kg/m2/hr 287 3. Carbonization 3.1. Max. temperature ?C 550 4. Filtrat Destillation 4.1. Pressure mm 40 4.2. Max. temperature column top ?C 265 5. Hydrogenation 5.1. Catalyst Ni-Mo 5.2. Pressure atm 250 5.3. Reactor temperature ?C 430 5.4. Through-put kg feed/ liter of 0.37 catalyst/ hour Relationship to Prior Technology This process is based on the Bergius-Piers process (IG Farben Process) which was developed in Germany. However, hydrogenation of the coal without the addition of a catalyst or hydrogen in the first reaction step represents a significant deviation from the original concept. It was not stated directly in the literature, but one can conclude that hydrogen generation for the cat- alytic hydrogenation step of this process will be produced by the gasification of coal residue from the process. This has not been technically demonstrated and is another different modification of this process. 1 1 1 I N S T I T U T E O F G A S T? E C H N O L 0 G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 a) r-1 0 rn U .H co $4 cA 0 D, to ~+ 0 0 0 CO U 4 O 4J ai V w CO a):. O 4J 0 1a 0 .+ ? ++ u O ~, 4-1 W 00 w 4A a) b R1 0 H 0 0 a cT a) a) 00 ?HI 4-1 0 a 0 U) U) -H Ca 0 4 U ?HI .~ cd W cd 0 O 43 ? 0 v w U G 0 0) H 0) 0 ?r4 $4 H-I '0 H-I O >, cd P4 x 0 U O U) 0 a) $.1 U W 0 s~ 43 0 a7 . 0 H a b ?HI H~ ca a) U .b 0 a 0 N 0 0 ?rl a) h0 0 >a U ?HI 4I H~ L I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 U ?r1 CO -1 a) 3.4 ca u 4 4J O C cd 4-+ v U a) ~ v- O i-+ 4J 4-J ?ri U yJ 4J CO ro (1) W H ~ Q) 4-J ou -H Co as U ?r-I O ~i O a) r-1 cd O JJ -H C 4-1 Cd j a) cd r1 U q ,.C b0 - O O r-3 .-I b ?rl O >, a x Co b Iw' 14 C C N r-4 a) r-I ca al 4-I ;>, 1 r4 Co U O 0 U G ca i Cd C-) Co U a) t 1 1 I N 5 T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Operating Facilities A bench-scale unit with a coal capacity of 120 kg/day was constructed at the Carbochemistry Institute of Tychy Wyry in the mid-70's. This unit was used to gain operating information for the construction of a 1200 kg/day pilot plant in 1977. This unit is also located at the Carbochemistry Institute. Major Funding Agencies This process is supported by the Polish Government. Technical Problems No technical problems have been reported in the literature. Capital Costs The capital costs for this process have not been published. T E C H N O L O G Y I N S T T U T E O F G A S Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83MOO914ROO SOUTH AFRICAN COAL LIQUEFACTION PROCESS 23. SASOL (Lur i/Fischer-Tropsch) Coal Liquefaction Process Process Description Sasol I SASOL (South African Coal, Oil, and Gas Corporation, Ltd.) was founded in 1950 for the production of synthetic liquids from coal. Their first synthetic liquids plant was completed in 1955 and is located at Sasolburg, 50 miles southwest of Johannesburg, South Africa. In 1979 Sasol was reoganized into Sasol Limited with 70% of the government owned company sold to the public. The new corporate structure which includes the two new synthetic liquids plants and the South African government's Industrial Development Corps.' involvement is presented in Figure 1. OWNERSHIP (SHAREHOLOING) - - - LOANS Figure 1. SASOL GROUP STRUCTURE I N S T I T U T E O F G A S T E C H N O !_ G Approved For Release 2007/02/20: CIA-RDP83M00914R001000060t~18-  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 r South Africa's first coal to liquids plant, Sasol I, utilizes Lurgi/ Fischer-Tropsch technology to produce a broad range of synthetic products. A block flow diagram of this facility as it exists today, is shown in Figure 2. This facility contains 17 Lurgi gasifiers; 13 Mark III, 3 Mark IV units, and one experimental Mark V gasifier. The Mark III, IV, and V Lurgi gasifiers have a 3.68, 3.85, and 4.7 m internal diameter, respectively. The Mark IV gasifiers were installed in 1977/8 and the Mark V unit was commissioned in 1980. In the Sasol facility coal is delivered from the adjacent Sigma mine in two coal sizes, -12 mm and 12-50 mm. This low grade bituminous coal, analysis shown in Table 1, is split about 40% fines and 60% coarse material. The fines are fed to two power plants and the remainder is gasified. The coal is deliv- ered from the mine by conveyors and stored in bunkers before entering the gasifier lockhoppers. These lockhoppers located at the top of the gasifiers hold between 6.5 and 10 tonnes of coal depending on their age. After pressur- ization with raw gas the coal is fed by gravity through conical valves into the distribution grate of the Lurgi gasifier (Figure 3). Gasification is carried out at approximately 375 psig and 1200?C. Total facility gasifier inputs include 9,000 to 11,000 tonne/day of coal, 65,00 to 95,000 m3/hr of oxygen, and 329,000 to 438,000 kg/hr of high pressure steam. Total raw gas production ranges from 450,000 m3/hr to 600,000 m3/hr. Overall availability of the gasifier plant is nearly 85%. The raw gas leaving the gasifier at about 500?C is scrubbed and cooled to 20 to 25?C to remove higher boiling point tars, oils and entrained ash dust. All tars and oils are filtered before undergoing further processing. The cooled raw gas is then sent to one of three Rectisol trains where carbon dioxide, hydrogen sulfide and organic sulfur are removed. Rectisol utility consumption averages 35.7 kWhr of electricity, mostly used for methanol recirculation pumps, and 79.2 kg of steam per 1000 m3 of pure gas produced. The pure gas leaving the Rectisol units is sent primarily to the Fischer- Tropsch sections; a Ruhrchemie-Lurgi Arge fixed bed design and the other and M. W. Kellog Co. Synthol entrained bed design. A small fraction of the pure gas is also sent to a methane-reformer where the methane content is reduced before entering the Synthol reactors. The synthesis gas composition entering the two types of Fischer-Tropsch reactors is shown in Table 2. I N S T I T U T E O F G A S T E C H N O L 0 G. Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 s x z v s .. o z S19 I0 i co SIS3HINAS MC = .zI W C . ?Z O~ ~ sl t9 C- 110 j 031NV330 ? , a a m 2 N ~y h U F7 7 t5~ J V. a ? r O C C7 2 a 5 2 - O O U m Z C Pf O ` V s _ n z o o O i ~ - U a ~ ~D wo . 8 Q Z CW7 O O . ~- C 01 ? iZ. _ C) Z H a Z ____ O a C ~- a C7 ? G U U U C W S a7 U O W = - Q W ? C C O 2 N C O S U a w, O. V Z O O N / C U C C1n S C -o_ ~ - r S79 11 VI SIS3HINAS i31VSN30N00 I 0100 317SN30N0O I 1OH XYM a010V3a ` ul ~'Io = >i_e B-184 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 a r Z G.: U C^. i 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I I Type Bituminous a Moisture (as received) 10.7 wt % I Volatiles (dry basis) 22.3 wt % Ultimate Analysis (dry basis), wt %, Ash 35.9 I Sulfur 0.5 Nitrogen 1.2 Carbon 50.8 Hydrogen 2.8 Oxygen 8.8 Ash fusion Temperature, ?C: Softening point 1340 Melting point 1430 Fluid point 1475 Energy Content, MJ/kg (dry) O FEED COAL Figure 3. LURGI MARK IV GASIFIER I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 2. RAW GAS COMPOSITIONS, VOLUME % Component Arge Synthol H2 39 40 CO 22 18 C02 28 31 CH4 9 9 N2 H2S 1 1 The Synthol reactor system has been developed to the commercial stage by Sasol, which today owns all the rights. This process produces predominantly lower-boiling point hydrocarbons in the gasoline and diesel oil range and the Arge process produces high-boiling point hydrocarbons, including a range of solid waxes. A breakdown of the product mix from these two reactors is shown in Figure 2. Both processes use an iron-based catalyst activated with certain promoters. These catalysts were manufactured in West Germany prior to 1969 when Sasol commissioned its own catalyst preparation plant. Production compo- sition can be varied somewhat by charging catalyst properties and reactor con- ditions. Part of the synthesis gas can be blended with industrial gas which is distributed by the Gascor subsidiary in a pipeline system. Some of the Synthol tail gas is also blended with synthesis gas as feed for an ammonia synthesis unit. Before entering the ammonia synthesis section the feed gas is shifted in a water-gas shift reactor and the carbon dioxide and hydrocarbons are removed. Nitrogen for the ammmonia synthesis reaction is supplied as a byproduct of the gasification section air separation units. Ammonia produced can be further converted to ammonium nitrate, nitric acid and limestone ammonium nitrate. Also linked to the Sasol One plant is an olefin section. Fuel gas, LPG and gasoline from Sasol I are the primary feedstock. Here, two naphtha crackers produce nearly 125,000 tonne/yr of 98% pure ethylene. In addition to r  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 r r Approximately 25,000 tonne/yr of styrene and 30,000 tonne/yr of 1,3-butadiene are produced in this facility. Sasol II and III After the Arab Oil embargo South Africa re-evaluated its synthetic-oil production potential. This re-evaluation resulted in the contruction of two new synthetic oil production facilities located at Secunda, 140 km northeast of Sasolburg and 130 km east of Johannesburg. Like Sasol I, Sasol II and Sasol III utilize Lurgi/Fischer-Tropsch technology and are mine-mouth facilities. Figure 4 is a simplified flow diagram of Sasol II which was commissioned in 1981. Sasol III is located adjacent to Sasol II and is a mirror image of this facility. Commissioning of Sasol III is scheduled for mid-1982. A view of Sasol II in the construction phase is shown in Figure 5. Figure 5. A VIEW OF SASOL II PLANT. TOGETHER, SASOL II AND III WILL OCCUPY 6 SQUARE MILES  W W - Approved For Release 2007/02/20: CIA-RDP83MOO914ROO100 f B-188 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 {~ W 4 J W O 1' W 2 - W W S O CA O t N O = Z Q ]nnlw].. cm vwiAdVN ii39I1 I Om HI wI . H lv03 03ZIS i sno~nor t t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Coal for the Sasol II and III facilities is being produced at the Bosjesspruit mine just south of the facilities. Total production of the four shaft mine which started operation in 1979 is estimated to be 27.5 million tonnes/yr. The mine, operated by Sasol I, is part of the Highweld coalfield and employs 6,600 people. The life of this mine at anticipated production levels has been estimated to be over 70 years. The typical coal properties for this relatively high quality bituminous coal are shown in Table 3. Coal from the mine is delivered to the synthetic fuels facility by conveyor. Type Bituminous Moisture (as received) 5.5% wt Ash (moisture free) 22.5% Volatiles (moisture free) 24.8% Fixed carbon (moisture free) 52.7% r Heating value 23.9-24.5 Mj /kg Carbon (daf) 76.9% Hydrogen (daf) 4.3% Sulfur (daf) 1.3% Nitrogen (daf) 2.0% Oxygen (daf) 13.6% Ash properties Softening point 1290?C Melting point 1330?C Fluid point 1360?C Sasol II is equipped with 36 Lurgi Mark IV high pressure gasifiers; 30 on line and 6 standby units. These gasifiers, which were tested for 3 years at Sasol I, weighed 140 tonnes each, have a 3.85 m internal diameter and operate at 27 bars pressure. A total of 1.65 million m3/hr of raw gas will be produced by these gasifiers with the composition shown in Table 4. Total gasifier section coal consumption will be from 25,000 to 30,000 tonne/day., In addition to coal these gasifiers will also require 30,000 to 36,000 tonne/day of high pressure steam and 8,000 to 9,000 tonne/day of 98.5% pure oxygen. Total oxygen requirements for Sasol II is nearly 12,000 tonne/day at approximately 500 psig (8,600 to the gasifiers and 3,400 to the reformers).  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 4. RAW GAS FROM GASIFIERS AND PURE GAS FROM RECTISOL UNIT COMPOSITIONS Raw Gas Composition Pure Gas Composition r I H2 38.1 volume H2 56% by volume N2 0.3 CO 28% CO 19.0% CO2 1.5% CO2 32.0% CH4 13.5% CH4 9.4% C2H4 0.02% C2+ 0.5% C2H6 0.20% H2S 0.7% N2 0.08% A 0.46 S 0.07 ppm Gas produced in the gasification section will be scrubbed in a Phenosolvan plant to recover approximately 120,000 tonne/yr of anhydrous ammonia. Tars and oils separated from the raw gas stream before di-isopropyl treatment in the Phenosolvan plant (about 200,000 tonne/yr) will be used to produce creasotes, road tars, pitch and coal tar fuels. Naphthas will be recovered for further processing to high octane gasoline components. After the raw gas has been scrubbed it is sent to the Rectisol section which consists of 4 process trains. These units produce about 1,100,000 m3 of pure gas with the composition shown in Table 4. Gases absorbed by the Rectisol units -70?C methanol wash are sent to a Stretford section where 90,000 tonnes/yr of elemental sulfur are recovered. Pure gas from the Rectisol section and reformed tail gas from the Synthol section are blended from the fresh feed stream to the Synthol section. Based on Synthol and Arge operating experience at Sasol I it was decided that the Synthol Fischer-Tropsch technology was most appropriate for Sasol II and III. The Badger Companies scale up and designs were used to construct eight Synthol units at the Sasol II facility. Each unit has a capacity of about 300,000 to 350,000 m3/hr of raw gas. The Synthol reactors operate at 340?C and approximately 340 psia. It is estimated that these Synthol reactors i I 1 t 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 s I r A I will consume 1.5 million m3/hr of pure gas. Catalyst for these reactors is prepared on site. The product slate produced by the Synthol section is presented in Table 5. Unreacted pure gas and tail gases from the Synthol unit are recycled to a cryogenic separation section before sending the 225,000 m3/hr of 90% pure methane output to eight methane reformer units. Methane reformer output is recycled into the Synthol reactor section. Table 5. PRODUCT SELECTIVITY FOR THE SASOL TWO SYNTHOLS (mass % basis) Methane Ethane/Ethylene Propane/Propylene Butanes/Butylenes C5 to 195?C fraction 190?C to 400?C fraction 400?C to 520?C fraction Heavier than 520?C fraction Chemicals 0.5 6.0 100.0 The liquid output of the Synthol reactors is sent to an oil upgrading section after oil stabilization. This section, shown in Figure 6, consists of a fractionation, vacuum distillation, naphtha hydrotreating, catalytic reforming (Platforming), catalytic condensation/polymerization, polymer gasoline hydrogenation distillate finishing and gasoline blending section. Process design for this section was done by Mobil, UOP and Linde. Total liquids production from Sasol II is estimated to be 2.1 million tonne/yr. This breaks down to 1.5 million tonne/yr of motor fuels, 160,000 tonnes/yr of ethylene, 200,000 tonnes/yr of tar product, 100,000 tonnes/yr of ammonia and 90,000 tonne/yr of elemental sulfur. Sasol III production will be similar, but emphasis will be placed on maximizing motor fuel production and minimizing other byproducts. A summary fact sheet of the Sasol technology is presented in Table 6. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I r- I a a, a ra b0 0 U) cd 0 c4 O a O Q' H Cl) O-+ H H O a w E ca ? H b U U U ?,I L?) O CL ?ri b N \ O Ld P a ?H Ln oo cv r- cd It 1 I r-I 0 a) o G aa)i J~J U)) U) ?H a) u a) in. o C ?cr4 a) ?A o C -11 a r-1 JJ L(') H d' M 0 Q) u ad O r-I M 4-4 L 4J 0 ., ' cd 4 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I 1 I I O U) H U I 0 a En 0 .r r{ W 1J \ U ?rl td bA W I4 V 0 f a 0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I Decanted oil Vacuum Distillate distillation Figure 6. SASOL II OIL UPGRADING SECTION The South African government has recognized the country's dependence on imports of transportation fuels as far back as 1927. Research on German indirect liquefaction technologies in the '30's and '40's culminated in the government support of Sasol I. This facility has been in operation since 1955 producing a broad range of chemical and transportation fuels. It is the gov- ernment's goal to increase transportation fuel production from coal in South Africa to lessen the countries dependence on foreign imports. Sasol I, II, and III are expected to supply an estimated 40 to 50% of South Africa's liquid fuel needs by 1985. Relationship to Prior Technology Sasol Technology is based on Lurgi gasification and Fischer-Tropsch syn- thesis. The Lurgi gasification process was developed in Germany in the 1930's and the Fischer-Tropsch synthesis reaction was discovered in 1925. Within 10 years of the Fischer-Tropsch discovery the first plant was in operation. By 1944 nine F-T plants were producing 560,000 tonnes/yr of fuel in Germany. Total world F-T capacity at that time is estimated to be 1.1 million tonnes/yr. South Africa has an abundance of minerals but in all the exploration activities no discoveries of important oil deposits have been found. In 1927, a South African White Paper was published discussing the available processes for production of oil from coal. Developments in Germany were closely fol- lowed with particular interest in the Fischer-Tropsch process. One of the 'hydrotreating ,?,'.,.... j 1 H,L t Distillate I J I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t r 11 F I South African mining corporations, the Anglo Transvaal Consolidated Investment Co., better known as Anglo Vaal, acquired in 1935 the South African rights to the German Ruhrchemie/Lurgi Arge Fischer-Tropsch process and the American Hydrocarbon Research Inc. Hydrocol Fischer-Tropsch process. During the next few years Anglo Vaal devoted much attention to the devel- opment of a scheme for the production of oil-from-coal. During the war and in the post-war years, Anglo Vaal remained in close contact with developments. In 1943, negotiations were held in America which led to the procurement of the rights of the American M.W. Kellogg Synthol variation of the Fischer-Tropsch process. In 1946 a new study was made and an application made to the govern- ment to create a suitable framework within which a long-term industry could be established. During 1947 the Liquid Fuel and Oil Act was passed and in agree- ment was reached between the South African government and Anglo Vaal in which the Anglo Vaal rights were taken over by the government. The South African Coal, Oil and Gas Corporation Ltd. was formed and incorporated under the companies' act as an ordinary public company. Though it was clear that the plant would be based upon the synthesis of hydrogen and carbon monoxide as invented and developed by Fischer and Tropsch, it still had to be decided which processes to choose for the individual steps in this integrated complex. For gasification the Lurgi pressure gasification with steam and oxygen was selected because this process had already been dem- onstrated in gasifiers of a smaller size. It had the advantage of being able to work on the rather low grade, high ash coal available to Sasol. The fact that it operated at a pressure of approximately 350 psi which is also the desired operating pressure for the Fischer-Tropsch plant, was an additional advantage. This avoids cumbersome compression of large volumes of gas arising from low pressure gasification. The raw gas from such a gasification system contains, of course, apart from the hydrogen and carbon monoxide, appreciable quantities of undesired components such as unsaturated hydrocarbons, sulphur compounds, etc. More- over, the raw gas contains a large percentage of carbon dioxide which has to be brought down to a lower level. A number of possibilities to purify the gas existed, all involving at least two or three different process steps. How- ever, in the late '40's Lurgi in cooperation with Linde of Germany, had devel- oped a combined gas purification process (Rectisol) which used one solvent, I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 methanol, at low temperatures as the single absorption agent to remove all undesired components from the gas. A full size plant did not exist, but the pilot plant work was convincing enough to justify its selection for the Sasol plant. The gasification process produces as a side-stream a gas liquor in which components such as ammonia and phenols are dissolved. Obviously, such a gas liquor cannot be disposed of before treatment and for this treatment another "first" was chosen, the Lurgi Phenosolvan process in which phenols are extracted from the water with a solvent such as butyl acetate. The ammonia can then be recovered by stripping with steam and converted into, for instance, ammonium sulphate. An additional advantage of having the gasifi- cation, gas purification and gas liquor treatment all from one process know- how supplier, was that the responsibility for the performance of these plants which are all to a certain extent inter-related, was concentrated with one company. On the Fischer-Tropsch process itself the choice was not easy. On the one hand there was the German Arge design which used a fixed bed reactor system which was developed by Lurgi in Germany and known to work. The reac- tion took place in long tubes surrounded by a bath of boiling water for tem- perature control and the only difference between the small demonstration reactors and the proposed reactors for the Sasol plant, was in the number of tubes in one shell. This was not expected to give scale-up problems. On the other hand there was the American Synthol developed moving bed reactor type using a fluidized catalyst on which only pilot plant data was available but which offered the opportunity of building reactor units with a much higher capacity. Though the basic chemistry for both reactor types is the same, the fixed bed reactor produces in general straight chain hydrocarbons with a high average molecular weight and most of the production is in the range of diesel oil and paraffin waxes. The fluid bed process produces branched olefins of a low average molecular weight and the production is mainly in the range of LPG and gasoline. In view of the uncertainties the wise decision was taken to build two synthesis plants in parallel using both systems. The original flow sheet made provision to send approximately two thirds of the pure synthesis gas to the fixed bed reactors and to send the tail gas of that system with the increased methanol content, to the reforming plant 1 1 1 1 t I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1 I where it was converted together with the remaining one third of the pure gas into feedgas of the right composition for the fluid bed plant. The tailgas of this plant is also recycled to the reforming units after removal of carbon dioxide. Detail design of the plants was done by M. W. Kellogg. Construction started towards the middle of 1952 and the first units were put into operation towards the end of 1954. By the end of 1955 all the main construction work was completed. Operating Facilities Sasol technology is being commercially utilized at Sasol I in Sasolburg and at Sasol II and III in Secunda, South Africa. Sasol I produces a host of products ranging from synthesis gas, chemicals, motor fuels to waxes, tars, and pitch. Total output is in the range of 14,600 to 18,000 bbl/day of liquid fuels and chemicals. Output for each of the Sasol II and III facilities is estimated to be 30,000 bbl/day of motor fuels 160,000 tonnes/yr of ethylene, 50,000 tonnes/yr of other chemicals, 200,000 tonnes/yr of tar products, 100,000 tonnes/yr of ammonia, and 100,000 tonnes/yr of elemental sulfur. Major Funding Agencies Anglo Transvaal Consolidated Investment Ltd. (Anglovaal) turned over the rights of the Sasol technology to the South African government in 1950. The government in turn formed the South African Coal, Oil and Gas Corporation Limited with funding coming from the treasury via the Industrial-Development Corporation (IDC). The IDC is the state corporation that has provided much of the venture capital to such high risk projects. The first Sasol facility at Sasolburg was constructed with this government funding at an estimated cost of $230 million in 1952-1955. The IDC also provided the loan capital for expan- sion activities at Sasol I throughout the years. As sole owner of Sasol I the IDC received all profits. The financing of Sasol II will come from the State Oil Fund (1.711 billion Rands), export credits (492 million Rands), and parliamentary grants (300 million Rands). Export credits will provide 20% of the financing of Sasol III; the balance will be provided by the State Oil Fund, parlimentary grants, and the proceeds of two stock issues in a newly formed company called Sasol Ltd. The issues were made in September and October of 1980. 245 million shares were offered to institutional investors and 17 million  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 shares to the public. Cost per share was 2 Rands. The response was tremen- dous, with more than $1 billion offered for each of the two issues. These shares account for 70% of the stock in the new company Sasol Ltd.; the remaining 30% is assigned to the Industrial Development Corp. (IDC) and its subsidiary Konoil Ltd. Sasol Ltd. will have 100% ownership in Sasol I and 50% ownership in Sasol II and III; the balance will be controlled by the state through IDC/Konoil. Once Sasol II and III are operative, further shares will be offered to the public from time to time. This dilution of government involvement reflects policies aimed at limiting the government's role in the economy. In 1979 when Sasol was restructured, Sasol Limited was created as the new holding company. The new corporate structure is shown in Figure 1 along with ownership percentages. The old Sasol is now known as Sasol I and is a wholly owned subsidiary of Sasol Limited. The Sasol I subsidiaries that have developed throughout the years to give the company its diversified energy business are shown in Table 7. This table presents the Sasol I subsidiaries and their principal activities. In addition to the companies presented in Figure 1 and Table 7, Sasol also oversees South Africa's strategic petroleum reserve which has been stored in underground coal mines. Sasol I has been commercially proven with over 25 years of operation. Sasol II which started full operation in 1981 did not experience any major startup problems. Sasol III which will by fully commissioned in 1982 is not expected to have any startup or operating difficulties since it is based entirely on technology used in Sasol II. Capital Costs See Major Funding Agencies section. R t t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 7. SASOL ONE SUBSIDIARY COMPANIES 1 r I r a 1 1. Sasol Marketing Company (SMC) - markets petroleum products of the Sasol group excluding road binder material, tar and bitumen. 2. South African Gas Distribution Corporation (Gascor) - Distributes industrial gas by pipeline from Sasol One to the industrial complex of the Witwatersrand and Vaal Triangle. It has also been designated as the distributor of any natural gas that may be discovered in South Africa. 3. National Petroleum, Refiners of South Africa (Natref) - Refines crude oil which is pumped by pipeline from the coast 600 km away for Sasol One into LPG, gasoline, diesel oil, kerosene, jet fuel, bitumen and other products. Sasol One owns 52.5%. The other partners are the National Iranian Oil Company (NIOC), 17.5% and Compagnie Francaise des Petroles (Total), 30%. 4. Sasol Dorpsgebiede (SDB) - Undertakes township development at Sasolburg and provides housing for the Sasol's group's employees. 5. Inspan Beleggings - Holds the major portion of the coal rights of Bosjesspruit's coal fields. 6. Leslie Coal Development Company - Holds Sasol One's longer-term coal rights. 7. Allied Tar Acid Refiners (Atar) - Refines tar acids in one of Sasol One's factories. Atar also markets phenols and cresylic acid through SMC. 8. Tosas - Holds a 50% interest in FTS Binders which in turn markets road binder material, tar, and bitumen. 9. Southern Oil Exploration Corporation (Soeker) - Sasol One has a 50% share of Soekor which is to lead and coordinate the search for oil in South Africa on behalf of the government with state funds. 10. Fedgas - Markets industrial gases such as oxygen nitrogen and argon some of which are supplied by Sasol One. Sasol One has a 20% interest in Fedgas. 11. Inspan Bedryf, Sasol Konstruksiemaatskappy and naftachem are dormant companies.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 SASOL ONE AND SUBSIDIARIES INDUSTRIAL DEVELOPMENT CORP. I 5oz 50% OWNERSHIP (SHAREHOLDING) LOANS Figure 7. SASOL GROUP ORGANIZATION r I 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 r s 1 24. Modderfontein (African Explosives and Chemicals Industries Ltd.) Coal-to-Methanol Process Process Description The AECI Ltd. has proposed to produce 800,000 metric tons/yr of methanol from coal for blending into gasoline stocks. The approach now being employed at their Modderfontein facility to produce methanol uses commercially avail- able Koppers-Totzek (K-T) and ICI technology. Current capacity of the Modder- fontein facility is 1,000 metric tons/day of ammonia and approximately 90 metric tons/day of methanol. The K-T gasifiers currently used at the Modderfontein facility are of the two-head design, but future expansion plans will probably employ the four-head design. Both designs are based on high-temperature, atmospheric-pressure, entrained-bed concepts which utilize pulverized coal. This process was first developed in Germany in the 1930's. The gasifier's characteristics enable it to use most types of coal to produce a clean synthesis gas consisting of chiefly CO and H2, with few if any hydrocarbon contaminants. The coal feedstock for the Modderfontein facility is delivered by rail from a mine 90 km away. A typical analysis of the feed coal is shown is Table 1. The coal is unloaded by one person from the incoming coal cars to a conveyor belt which is also operated by one person. Coal is stored in bunkers which is typically sufficient for two weeks of operation. During winter months the coal storage is larger due to increased regional demand. From coal storage the coal is pulverized and simultaneously dried to about 1.5% moisture in two ring and ball mills. The resulting coal dust particles are typically sized 90% less than 90pm. The pulverized coal is transported to a network of bunkers, and fed to the gasifier via screw feeders. The prepared coal entering the gasifier is entrained into a stream of premixed oxygen and steam and the reaction mixture enters the gasifier via burner nozzles located in the gasifier heads. Very rapid exothermic reactions occur causing the temperature in the flame to exceed 2000?C. Subsequent endothermic reactions and cooling by the steam jacket gasifier wall reduces the overall temperature within the gasifier to 1600?C. Residue time of the coal in the gasifier is typically about 0.5 to 1 second. The Modderfontein facility currently utilizes six two-headed K-T gasifiers. A diagram of the K-T two headed gasifier is shown in Figure 1. B-201 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Ultimate analysis (dry basis) % m/m C H N 0 S Ash Inherent moisture, % m/m Volatile combustible matter, % (air dry basis) 64.3 3.7 2.3 8.6 0.6 20.5 1.9 t 1 1 .. a Figure 1. K-T GASIFIER  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 t 1 I A portion of the mineral matter in the coal is slagged in the gasifier and impinges on the walls where it accumulates and flows down to a slag outlet in the base. The molten slag is then quenched and granulated in a water bath and removed by a continuous scraper system. The remaining mineral matter leaves the gasifier as fly ash with associated unreacted carbon. The exit temperature of 1600?C requires that the still molten fly ash be quenched with direct water injection to about 900?C. This avoids fouling in the waste heat boiler system where steam is raised at 55 bars. The gas is further contacted with water in a washing tower where most of the solids are removed. The synthesis gas is subjected to further dust removal before passing to a raw gas recompression section prior to gas purification. A typical composition of the raw gas at this point is shown in Table 2. Typical Analysis of Raw Gas by Volume I (Dry Basis) CO 58% H2 27% C02 12% CH4 100 ppm H2 0.5% COS 0.04% S02 0.1 ppm HCN 100 ppm NO 30 ppm NH3 15 ppm N2 0.9% Ar 0.6% 02 100 ppm A block flow diagram of the whole coal to methanol process is shown in Figure 2. The dust-free raw gas from the gasification plant is compressed to 30 bars in 2 parallel stream turbine-driven raw gas compressors. The com- pressed gas is then sent to the first stage of the two-stage Rectisol gas purification unit. Gas entering this stage is first treated by a water absorber to remove HCN and then scrubbed with cold methanol to remove H2S and I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 COS to less than 1 ppm. Significant amounts of CO2 are not removed in this unit. Oxygen plant Co., prep, drying and pulverizing Coal Raw gas comp. Gasification and heat recovery T Agh r. ASh Shift conversion Sulfur plant and tail gas treatment Acid gas removal Flue gas Sulfur Figure 2. COAL-TO-METHANOL PROCESSING USING KOPPERS-TOTZEK GASIFICATION PROCESSING MEOH synthesis loop Crude MEOH The gas is then recompressed to 50 bars before injection into the water- gas shift unit where the CO-to-H2 ratio is adjusted for the methanol synthesis reaction. The methanol synthesis process used in the Modderfontein plant is of the ICI design. This unit, shown in Figure 3, consists of compressing the makeup gas, mixing this makeup gas with recycle gas, and then feeding the mixture to the methanol converter. The two overall reactions in the catalyzed bed occur as follows: CO + 2H2 + CH3OH C02+H2;CO+H20 The hot effluent is cooled by a waste heat recovery unit, heat exchange with incoming feed, and cooling water. The liquid-rich stream is finally flashed to remove gases, which are then recycled to the reactor. The cata- lytic methanol reactor uses a copper based catalyst to operate at a tempera- ture of 400? to 575?F and a pressure of 750 to 1,500 psig. The crude methanol requires further distillation to produce a pure product for more fuel blending or can be sent to a Mobil MTG reactor to produce gasoline. B-204 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 r 1 In the Mobil process, shown in Figure 4, methanol is partially dehydrated to an equilibrium mixture of methanol, dimethyl ether, and water over a dehydration catalyst in a limited reactor. In a second reactor, a zeolite conversion catalyst is used to convert both methanol and dimethyl ether to high-octane gasoline. During this operation recycled gas is used as a heat sink to remove the exothermic reaction heat. In the overall process the reaction can be described as follows: 2CH3OH + CH3 -O-CH3 + H2O CH3 -O--CH3 + 2(-CH2) + H2O Typical yields of the raw product from this process are presented in t Table 3. The hydrocarbon product is primarily gasoline which must undergo further treating to add butanes and alkylate the butenes and propylenes. The finished gasoline product in Table 4 typically has a Rvp of 9 psig and unleaded RON of 93. Figure 3. METHANOL SYNTHESIS I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Yields. wt % of charge Methanol + ether Hydrocarbons Water Co. C06 Coke, other Hydrocarbon product, wt % Light gas Propane Propane i-Butane n-Butane Butanes C. + gasoline Gasoline (including alkylate) LP-gas Fuel gas TYPICAL YIELDS FROM CRUDE METHANOL USING FIXED BED PROCESS Components, wt. % 0.0 Butanes 39.2 Alkylate 93.2 C. + syethasizsd gasoline 0.3 0.2 100.0 Composition, vol % Paraffins Olefins 1.4 Naph hen. 6.6 Aromatics 0.2 8.9 3.3 1.1 70.9 Research octane Clear Leaded, 3 cc TEL/U.S. gal 100.0 Reid vapor pressure, psig Specific gravity Sulfur. wt % 85.0 Nitrogen. wt % 93 RON clear, 9 Rvp) Corrosion, copper strip 13.0 ASTM distillation, 'F 1.4 10% About 3000 stpd tnatltanol (100% basis) are raquind b produce 10,000 bpd total liquid products (90so1Mts plus LPG) 30% 60% g0% 2.T a2 11a.1 gS . 100 9.0 0.730 Nil Nil 1A 114 146 198 330 1 I 1 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Crude methanol Hydrocarbon liquid product t Conversion Cooler Separator reactor Figure 4. MOBIL METHANOL-TO-GASOLINE PROCESS - FIXED BED OPERATION In the spring of 1980 AECI Ltd. announced plans to construct an 800,000 metric ton/yr methanol facility based on coal gasification technology. This decision stemmed from a South African government announcement to grant private-enterprise fuel-from-coal tax breaks similar to those granted SASOL. The methanol produced in the AECI Ltd. facility would be used as a blending feedstock (up to 10%) to stretch existing gasoline and diesel supplies. How- ever, reports from the AECI Ltd. in 1981 indicated that methanol may not be more desirable. Plans to go ahead with this development have yet to be announced. Relationship to Prior Technologies The technology used to produce methanol has already been commercially developed. This includes the K-T gasifier which was developed in Germany in the 1930's and the ICI methanol process developed in England in the late 50's and early 60's. If gasoline is to be the final product, the Mobil MTG process will also be required. This process is currently in the pilot plant phase, but, a large commercial facility is being built in New Zealand using the Mobil MTG process. Operating Facilites AECI Ltd. currently operates a 1000 metric ton/day ammonia plant and a 90 metric ton/day methanol plant which uses coal as the feedstock. This  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 facility at Modderfontein, South Africa, started operation in 1972. This complex, which is the largest ammonia plant in South Africa, took 30 months to construct. Major Funding Agencies Privately financed by AECI Ltd. Technical Problems The Modderfontein plant can exceed its 1000 metric tons/day design capa- city. The plant consists of six gasifiers, but five gasifiers are sufficient to reach the ammonia plant design capacity. The gasifiers are arranged in a pair of three. At start-up, the gasifiers ran at 70% of capacity, and even- tually reached 130% of design capacity. They expect greater turndowns are possible with the four-headed gasifier. AECI personnel felt that a spare gasifier would have been a desirable feature. Of course, this is easier to justify on large plants. Gasifiers can easily be taken on and off stream for brief periods of time (say, one hour); they are kept hot during standby by means of integral burners. They said the gasification efficiency varies with the type of coal. They strongly recommend full-scale testing of coals prior to selection system. They found the gasifiers sensitive to the type of coal fed. They estimate that the No. 4 plant has twice the amount of equipment a conventional natural gas or oil based ammonia plant would have. Thus one would expect more difficulty in maintaining high reliability. (They did not want to discuss on-stream factors.) A chart on the meeting room wall during a trip there in 1981 indicated that actual production was nearly equal to scheduled production for the previous few months. Their main problems are associated with the stoker-type boiler. No redundancy was built into the system, hence they often have difficulty supplying adequate steam. There are also considerable time delays when addi- tional steam is demanded, further complicating operations. Cycling the steam output is hard on the boiler components and contributes to increased mainten- ance. They reminded us that the pulverized coal alternative to a stoker is more difficult to operate. Another plant problem mentioned is erosion of process surfaces. These repairs are made during their overhaul period, which occurs every two years (standard practice for the chemical process industry). r 1 1 f 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 t 1 They have solved the refractory lining problems that were encountered earlier. They stated that in general their plant experiences more corrosive contaminant than a natural gas-based ammonia plant. They have been able to slowly increase the intervals between certain maintenance procedures through the years as they became more familiar with the plant. In their opinion gas is easy to make compared to the remaining processes in the plant. They strongly felt that all portions of the process should be highly instrumented because of the inherent possibility of fire, explosions, and toxicity dangers. They are currently in compliance with all environmental regulations, although they were having some recent dust problems from the coal milling section (that had been previously reported in the literature as well, indicating a possible chronic problem). They must obtain an operating permit from the Air Pollution Control Officer, who has the power to shut down the facility. They enjoy amiable relations with the environmental authorities. South African law requires that pressure vessels be tested every four years; this is done during one of the overhauls scheduled every two years. They currently burn the hydrogen sulfide removed from the process. They envision two alternatives to burning: production of sulfur from the gas via a Claus plant, or production of sulfuric acid. They warn that heavy metals in coal ash may be a problem in the U.S. (they are not experiencing problems). They see no reason not to recycle about 20% of their process water. They store a minimum coal supply of two weeks. Turing winter, when demand is high, they prefer to have a larger supply. Coal supply problems have not occurred. The plant has not suffered from labor problems. Labor is represented by unions according to race. The plant is a closed shop, but not all labor is unionized. The plant uses a four-shift system with three shifts per day. Gasification labor requires a part-time foreman, one supervisor, one operator in the control room, two outside laborers, and less than one auxilliary laborer. The coal supply section is less sophisticated and requires one laborer to unload the coal cars, one laborer to oversee conveyor operations and one laborer in the coal mill. They estimate skilled labor receives a net salary of R12,000 ($15,000) and unskilled, R6,000 ($7,500). If labor were more expensive they postulated that they might increase automation in the coal I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 handling section to eliminate one or two positions, or simply require each worker to be responsible for more process operations. They feel that their labor productivity is typical for South Africa. The major process industry differences they see between the U.S. and South Africa are coal and electricity prices. Typical coal prices are R6 and R9 per ton (this is about $0.50 to $0.70 per million Btu). Electricity in the vicinity of the plant costs about R0.01 per kWh (13 U.S. mills/kWh) and in the Cape about R0.021 per kWh (26 U.S. mills/kWh). Capital Cost Construction of the 800,000 metric ton/yr methanol plant was estimated to be $549 million in 1980. t I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t r f SOUTH AFRICAN COAL LIQUEFACTION PROCESS 25. Sasol Direct Coal Liquefaction Process Process Description Little, if any, information has been published on Sasol's direct lique- faction technology development program. Information published by the Nippon Brown Coal Liquefaction group of Japan has indicated that Sasol has developed an SRC-II type pilot plant process which utilizes catalytic hydrogenation technology. However, published verification of this facility has not been found. In addition, Sasol officials indicated in mid-1981 that direct coal liquefaction technologies were not superior to their indirect process, espe- cially when taking South Africa's poor coal quality into consideration. However, bench-scale experiments have been conducted by the Fuel Research Institute of South Africa on catalytic hydroliquefaction of South African bituminous coals. In these experiments four different liquefaction reactors were tested on one South African coal type. The proximate and ultimate analysis of the bituminous coal used in these experiments is shown in Table 1. Table 1. ANALYSIS OF WATERBERG TRANSVAAL COAL USEDa Moisture (wt % air dried basis) 3.4 Ash (wt % air dried basis) 12.7 Volatile Matter (wt %, air dried basis) 34.8 C (wt % daf) 80.7 H (wt% daf) 5.5 N (wt % daf) 1.5 S (wt % daf) 1.0 0 (wt %, daf) (by difference) 11.3 Vitrinite (vol %) 83.2 Exinite (vol %) 4.2 Inertinite (vol %) 5.7 Ro (mean maximum reflectance of vitrinite) 0.720 a 0.5 - 0.25 pm (30 - 60 mesh) The first process is hydropyrolysis (dry hydrogenation) with a "hot-rod" reactor, 2-5 operated in a semi-continuous mode. In this reactor the coal is I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 heated at about 200?C min-' while secondary reactions are minimized by removing and quenching the products. The second process was hydropyrolysis in a rotating autoclave with a heating rate of about 7?C min 7l and retention of the product at reaction conditions for 1 hr. The other processes were super- critical gas extraction using toluene with and without hydrogen. These extractions were carried out in an autoclave with a lengthy heating-up period and in a modified "hot-rod" reactor with reasonably rapid heating. Identical temperatures and pressures were used either with the same concentration of catalyst or without catalyst. In all the experiments, sand was mixed with the coal to limit agglomeration.6 Thermolysis of supercritical toluene is a problem; however, the products of the thermal breakdown are known.7 Liquefaction Procedures Method A (Runs 1 and 2). Hydrogenation was carried out in a "hot-rod" reactor.2-5 The coal (25 g), impregnated with stannous choloride catalyst (tin 1 wt % of the coal) for the catalyst run, was mixed with sand (1:2 by weight). The reactor was heated (about 200?C min-') to 450?C and maintained at this temperature for 15 min. Hydrogen (20 mPa; 221 min-') was passed through the fixed bed of coal/sand/catalyst. The products were condensed in high-pressure cold traps. Method B (Runs 3 and 4). The reactor was a 1 liter rotating autoclave fitted with a glass liner. Coal (50 g) sand catalyst preparation procedures were the same as in Method A. The charge was heated (about 7?C min-') under hydrogen to 450?C and maintaned at this temperature for 1 h (pressure 20 MPa). The product was washed from the cooled reactor system with toluene. The solid residue was extracted with boiling toluene (250 ml) in a Soxhlet extractor for 12 h. The toluene solutions were combined and the toluene removed under reduced pressure. Hexane (250 ml) was added to the extract and it was allowed to stand for 24 hr with occasional shaking. The solution was filtered to leave a residue (asphaltene) and the hexane was removed from the filtrate under reduced pressure to give the oil. The residue in the Soxhlet thimble after toluene extraction was extracted with pyridine in a Soxhlet extractor to give pre-asphaltenes (toluene-insoluble pyridine-soluble product). 1 1 1 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I t A t Method C (Runs 5-8). Supercritical gas extraction was carried out in a stirred 1 liter autoclave. Coal (100 g) sand catalyst mixtures were the same as that for Method A. In the runs without hydrogen, the autoclave was charged with coal/sand/catalyst and 600 ml of toluene and heated. It took about 1 h to reach the required temperature and pressure. On reaching the desired temperature (450?C) and pressure (20 MPa), toluene (about 2 liter l i-1) was pumped into the reactor through the coal bed via a dip tube. The toluene extract was cooled at atmospheric pressure in a water-cooled condenser. The runs with hydrogen were similar except that only 300 ml of toluene was loaded into the autoclave, which was then flushed and pressurized with hydrogen to a cold pressure of 5 MPa. After attaining the reaction temperature and pressure (450?C and 20 MPa), the autoclave was maintained at these conditions for 1 h before starting to pump the toluene. The extraction condensate was filtered to remove material which precipi- tated on cooling. This residue was soluble in pyridine and designated as pre- asphaltene. The toluene was removed from the filtrate under reduced pressure, and this product was then treated with hexane as described to give the asphaltene and oil fractions. Method D (Runs 9-12). The apparatus used was the same as for Method A except that provision was made for the introduction of toluene as well as hydrogen. Coal/sand/catalyst preparation procedures were as for Method A. In the runs without hydrogen, toluene (4 liter h 1; 20 MPa) was passed through the reactor for 15 min on attaining the reaction temperature. In the runs with hydrogen, hydrogen (8 liter min-') was simultaneously passed through the reactor. The pressure was maintained at 20 MPa. The toluene extract was collected in the condenser system. The conversions and product distributions are shown in Table 2. In the case of supercritical gas extractions without hydrogen (Runs 5, 6 and 9), the yield of extract was greater than the conversion due to the thermal breakdown of toluene. The gas yields (including water) were obtained by difference and in the experiments where supercritical toluene was used, these will be low owing to errors caused by formation of toluene pyrolysis products. G.I.C. analysis of the oils from supercritical amounts of bibenzyl and the other toluene pyrolysis products. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Molecular weights, viscosities, and sulphur analysis are given in Table 3. Sulphur analysis was not carried out on the supercritical gas oils (Runs 5-8) because of the large amount of toluene pyrolysis product in the oils. Thermogravimetry in nitrogen of the four hydrogenation oils (Samples 1-4) were very similar. About 60% weight loss had occurred at 200?C and essentially 100% weight loss had occurred by 400?C. Thermogravimetric analysis in nitrogen of the asphaltenes showed that the asphaltenes from the supercritical gas extraction without hydrogen assistance were less volatile than the other asphaltenes. The fractions from the silica gel chromatographic separation were grouped as aliphatic hydrocarbons, aromatic hydrocarbons, and polar compounds. The results for the oils from the hydrogenation samples are summarized in Table 4. The samples from the rotating autoclave contain a lower percentage of polar compounds than those obtained from the equivalent "hot-rod" experiment. Because of the large quantity of toluene pyrolysis product in the oils from the supercritical extractions, these oils have not been grouped as aliphatic, aromatic, and polar compounds. Table 2. PROCESS. CONDITIONS. CONVERSION AND PRODUCT DISTRIBUTION Conversion Extract yield oil Asphaltene Pre-asphaltene Gas 1 HR HR H2 38.7 - 13.2 13.2 6.8 5 5 2 RA H2, SnCl2 90.6 - 29.4 10.9 5.9 . 44 4 3 H2 56.1 - 13.0 3.5 3.1 . 36 5 4 RA H2, SnCI2 79.6 - 24.5 6.8 1.8 . 46 5 5 SCGE 32.4 39.6 14.7 13.8 10 2 . 6 7 SCGE SCGE SnCI2 H2 29.0 41 7 36.0 4 32 14.4 16 8 11.6 . 8.2 8 SCGE H2, SnCI2 . 69.5 . 52.1 . 19.9 13.1 25.1 2.7 4 4 9.3 17 4 9 10 SCGE/HR SCGE/HR SnCl 31.2 32 6 32.6 4 31 8.6 15.4 . 8.6 . 11 SCGE/HR 2 H2 . 34.0 . 24.0 7.3 7.7 15.6 13.2 8.5 1 3 1.2 10 0 12 SCGE/HR H2. SnCI2 49.2 44.5 12.0 26.4 . 6.1 . 4.7 a HR, Hot-rod reactor; RA, rotating autoclave; SCGE, supercritical gas extraction using autoclave; SCGE/HR, supercritical gas extraction using hot-rod reactor Table 3. MOLECULAR WEIGHT, VISCOSITY AN SULPHUR ANALYSIS OR PRODUCT Molecular wt. Viscosity of oil wt % S Run Oil Asphaltene (mPa s) in oil 1 221 398 62 0.40 2 197 330 40 0.33 3 194 352 33 0.30 4 194 351 17 0.24 5 214 487 15 6 215 49. 13 7 222 427 34 8 210 428 22 9 237 0.52 10 235 0.51 11 248 0.46 12 230 0.32 1 1 1 t 1 B-214 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I 1 1 Run Alphatics (wt % oil) Aromatics (wt % oil) Polar compounds (wt % oil) 1 8 48 44 2 6 55 39 3 5 59 36 4 4 70 26 The conversion of coal to liquid and gaseous products was highest for the "hot-rod" reactor when a catalyst was used (Table 2). The conversion was much lower without a catalyst. Using the rotating autocalve the effect of the catalyst was far less pronounced presumably owing to the much longer residence time. As expected, when the product is held in the autoclave, gas production at the expense of liquid product increases. The amount of asphaltenes and pre-asphaltenes22 (or asphaltols23) is higher for the "hot-rod" reactor experiments than for the autoclave experiments. With time, asphaltenes and pre-asphaltenes are converted to oil and gas. The higher conversion obtained with the "hot-rod" reactor with a catalyst compared to the equivalent rotating autoclave run may indicate that polymerization of part of the product does occur to give mainly a pyridine-insoluble char. However, it is possible that the higher rate of heating in the "hot-rod" reactor may produce more intense thermal fragmentation and thus higher conversion. Different hydrogenation processes even when carried out at the same pressure and temperature on the same coal, give considerably different products. The liquid product from hydrogenation in a rotating autoclave contains less hetero-atoms and is more aromatic than the product from a short residence time semicontinuous reactor working at the same pressure and temperature. These differences may have important implications for the further processing of the product to transportation fuels and petro- chemicals. The long residence time of batch autoclaves tends to "mask" the effect of a catalyst compared to short residence time reactors. Therefore, catalyst screening in batch autoclaves may only be of limited value when applying these result to short residence time reactors. Supercritical gas extraction gives a more aliphatic liquid product, and even in the presence of hydrogen and catalyst is a milder process than hydropyrolysis at the same I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 temperature and pressure. The work with supercritical gas extraction has shown the problem that solvent breakdown can have on the yield and the nature of the liquid obtained in a batch process. Relationship to Prior Technology Based on catalytic hydrogenation and other technologies; however, a process configuration has not been established. 0 erating Facilities Bench-scale studies are being carried out at the Fuel Research Institute Laboratories at Pertoria, South Africa. Technical Problems Technology is not mature enough to project technical problems. Capital Costs Technology is not mature enough to project captial costs. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t 26. Central Fuels Research Institute (Lurgi) Coal Gasification Process Process Description The conventional Lurgi process pilot plant was installed and commissioned in 1962. The plant has a capacity to gasify 1 tonne of coal per hour. The gasifier is a conventional rotary grate type gas producer designed to operate up to a pressure of 32 kg/cm2. The gasifier shell, 1000 mm dia. and 5800 mm length, is a double-walled alloy steel vessel of welded construction. In the annular space between the walls, steam is raised at gasification pressure. The inside of the gasifier is partly lined with refractory bricks in the com- bustion zone. A rotating coal distribution (speed 7-45 rpm) is fitted inside the gasifier at its top for maintaining a fuel bed of constant height. The grate at the base of the generator can be rotated at speeds varying from 4 to 24 rpm. A coal lockhopper chamber for feeding the coal and an ash lockhopper for ash discharge are provided at the top and bottom of the gasifier, respec- tively. The tar-laden hot gases emerge out of the gasifier at a temperature of 400?-500?C. The plant is equipped with gas cleaning system, tar recovery system, and safety devices with adequate instrumentation wherever necessary. The flow diagram of the system is given in Figure 1. The performance of this gasifier on a number of Indian coals is presented in Table 1. The goal of this research effort is to study the gasification character- istics of noncaking Indian coals with steam and oxygen. The primary appli- cation of this conventional technology is the production of ammonia. The gasification characteristics of the following noncaking coals were studied in detail: ? Talcher, bottom seam of Talcher coalfields in Orissa. ? King seam coal of Singareni (Kothagudem) field in A.P. ? Dobrana seam coal of Raniganj field in West Bengal. e Burhar seam coal of Shahagpur in M.P. Relationship to Prior Technology This project is based on the commercially available Lurgi gasification I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. SOME TYPICAL OPERATION DATA OF PRESSURE GASIFICATION TESTS Gasifier pressure, kg/cm'(g) Dry coal feed rate, Kg/hr Oxygen/coal (dry), Nm'/kg Steam/coal (dry), kg/kg Dry coal input on cross-sectional area of Gasifier, kg/m'/hr. Gas (raw) make rate, Nm'/hr. Raw gas compo-ition, % by volume CO5 CnHm Surkachar Lower Kenda 10.6 14.0 21.1 21.1 21.1 363 486 518 453 556 0.201 0.217 0.278 0.281 0.257 1.276 1.306 1.834 1.668 1.552 462 619 660 577 708 617 648 830 709 917 27.8 0.6 O s 0.0 CO 19.2 H, 42.7 CH4 N, 8.8 0.9 Calorific value of purified gas .CO2=2%) K. cal/Nm, 4207 Thermal efficiency cold gas, % 73.8 Carbon gasified, % 76.4 Consumption per 1000 Nm' of raw gas Coal (dry), kg 587 Steam, kg 749 Oxygen, Nm' 118 Consumption per 1000 Nm' of purified gas (COs=2%) Coal (dry), kg 799 Steam, kg. 1016 Oxygen, Nm' 160 Yield of tar/1000 kg of dry coal, litre - Coal Steam Gasifier Oxygen Ash Dobrana Sample 'A' Sample 'B' 21.1 21.1 25.0 390 359 450 0.346 0.322 0.284 1.720 1.995 1.747 497 457 573 635 582 794 27.3 30.4 31.2 29.3 29.9 31.2 30.9 1.2 0.4 08 0.8 0.4 0.9 0,8 0.0 0.0 0.0 - 0.0 0.0 0.0 17.4 16.0 15.2 19.8 19.1 15.4 17.2 41.5 39.6 40.5 37.9 38.1 38.9 38.7 12.2 13.1 11.9 11.7 11.8 11.9 11.7 0.4 0.5 0.4 0.5 0.7 1.7 0.7 4242 4228 4218 4159 4074 4178 4176 75.5 75.1 78.3 78.1 75.7 76.0 74.4 75.4 79.7 81.7 83.1 86.3 82.9 82.8 750 624 639 606 615 617 567 980 1171 1066 941 1057 1231 991 163 173 180 156 212 199 161 1011 879 910 840 860 879 804 1321 1649 1519 1305 1478 1734 1406 220 244 256 216 296 283 228 - 48.0 44.0 35.0 - 53.0 57.5 Par Removal Hot Potash Wash Plant Figure 1. LURGI PRESSURE GASIFICATION PILOT PLANT - Raw Gas 1 Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 Operating Facility The 1 tonne/hr Lurgi gasifier has been in operation since 1962 at the CFRI in Dhambad. Major Funding Agencies Council of Scientific and Industrial Research, Government of India. Technical Problems None. Capital Costs The project is not expected to be scaled up; therefore no large scale capital cost projections have been made. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 27. Central Fuels Research Institute (Bergius) Coal Liquefaction Process Process Description CFRI claims that they have completed experiments to liquefy coal by the Bergius process in a bench-scale unit at a capacity of 18 kg/hr. They are looking for foreign cooperation to scale up the process to 1 TPH capacity. Solvent extraction of -5 mesh coal with aromatic oils was attempted in small batch reactors. The extraction was carried out for about 3 hours at 300 to 360?C (572? to 680?F) at the vapor pressure of the solvent (10 to 15 kg/cm2 or 140 to 210 psi). No hydrogen or catalyst was added, and about 50% of the coal was extracted. CFRI claims that the coarse coal feed enables easier filtration of the extract. The extract could be used as a substitute petroleum feed stock. Delayed coking of the extract produces a low ash coke suitable for anodes (less than 0.5% ash) in electrometallurgy or a petroleum coke substitute. Feedstock requirements for this process include lignites, subbituminous, and bituminous coals with high vitrian and fusain content, but with low ash content. Higher sulfur coals are an advantage for this process since the sulfur promotes catalyst activation. The primary output of this process is middle distallates, particularly diesel oil, which is the preferred product in India. In addition, hydrocarbon gases, naptha, and kerosene are also produced. The estimated process efficiency is in the range of 65% to 70%. Process Goals The goals of this program are to develop indigenous coal liquefaction technology within India to offset foreign oil imports. Relationship to Prior Technology This development is an offshoot of the Bergius-Piers process (I.G. Farben Process) developed in Germany prior to World War II. Operating Facility The CFRI has conducted tests in an 18 kg/hr bench scale unit in Dhambad since the mid-70's. A larger facility has not been built due to lack of funding support. B-220 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 Major Funding Agencies This small-scale development work is being supported by the Central Fuel Research Institute. Technical Problems Materials of construction, especially in vessel lining material, and valve life are considered the major problems. Hesser problems include separation of heavy oils from ash solids and the production of an economical source of hydrogen, which is required as a feedstock to this process. Oil loss from the process has also been indicated as a problem. Capital Costs Capital costs for a 1 million tonne/yr liquid product facility has been estimated to be Rs 11,000 million (Base year 1980-Rs 8.00 = $ 1 U.S.). Oper- ating costs for such a facility are estimated to be roughly Rs 1150 million/yr, excluding feedstock costs. Coal feedstock costs were estimated at Rs 675 million/yr. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 INDIAN COAL GASIFICATION PROCESS 28. Bharat Heavy Electricals Ltd. (BHEL) Combined Cycle Coal Gasification Process Process Description The BHEL process utilizes a high-pressure, Lurgi-type fixed-bed reactor in a combined-cycle layout to generate electric power. In this process lumpy coal of graded size is gasified with air and steam at a pressure of 10 bars (106 N/m2) to yield a low calorific value gas of 4960 KJ/Nm3. In addition to the gas, tar, oil, and liquor are obtained as by-products. The process flow diagram, shown in Figure 1, comprises the gasifier, mixing vessel, gas cooler, and scrubber. Coal of graded size is fed to the gasifier through a suitable feeding system. Air and steam mixed in the mixing vessel are led into the gasifier through the tuyeres located in the rotating grate of the gasifier. Coal coming in contact with air and steam undergoes successive processes of carbonization, gasification, and combustion yielding a low calorific value gas and ash. The ash is continuously withdrawn from the gasifier through the rotating grate and ash discharge chamber. The gas leaves the gasifier through the gas exit line. As the gasifier operates continuously under pressure it is necessary to have some means of introducing coal and discharging the resultant ash from the process at atmospheric pressure. The coal feeding system and ash discharge system provide these means, respectively. The grate and coal distributors are two other parts in the gasifier which regulate a uniform distribution of gas, air, steam, and coal in the gasifier. The gasifier is also provided with a feedwater jacket where part of the steam needed for gasification is produced. The raw gas leaving the gasifier at about 540?C traverses through the gas cooler and drops down to a temperature of 350?C. In the process it superheats the steam circulated from the main waste heat boiler by indirect contact, and in addition dust particles and part of the tar vapors are condensed and col- lected. Part of the superheated steam is led to the mixing vessel where it admixes with air fed from a booster and saturated steam from the gasifier. The rest of the steam is led to the steam turbine for power generation. B-222 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Coal Bunker Flare Coal - 1 Steam ~ i 1 Steam Stack Ash Lock t Waste Water Ash Pump + AL Dust,Tar, Dust,Tat Make up Liquor Liquor Figure 1. HIGH PRESSURE FIXED-BED GASIFICATION I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 The gas enters the scrubber where it is contacted by either cooling water or/and gas liquor spray. Tar and the other liquor products get condensed here and are withdrawn from the bottom of the scrubber. The liquor is recycled back to the scrubber. The final gas leaving the scrubber is free of tar and alkali vapours. The clean gas from the gasification plant is the starting material for the gas/steam turbine combined cycle operation. This gas has a calorific value of around 4960 KJ/Nm3. This process has been tested using Singareni coal with the properties shown in Table 1. The cleaned synthesis gas which is fed to the combined cycle process has the expected properties shown in Table 2. Process Goals The program has the following objectives: - To undertake technical and techno-economic evaluation of advanced power cycle concepts. - To identify the more promising cycle configurations, define know-how gaps regarding hardware and systems, and initiate R&D Projects. - To design, develop and install a combined cycel demonstration power plant based on coal gasification to establish engineering, product nad systems designs, operating conditions and generate reliable cost data. A combined cycle demonstration plant of about 5 MW capacity is being installed at BHEL, Tiruchirapalli, for which the system design has been completed and hardware design is underway. The plant evisages a new fixed bed pres- surized gasifier, a gas turbine of about 3 MW capacity, a waste heat recovery boiler, and a conventional steam turbogenerator of 2 MW in a BHEL-patented power cycle. Relationship to Prior Technologies The gasifier used in this process is based on the Lurgi fixed-bed design. BHEL used the operating experience of the 1 ton/day Lurgi pilot plant gasifier at the Central Fuels Research Institute to design a modified version of the moving-bed gasifier using indigenous materials and components. Joint efforts with Lurgi of West Germany were abandoned due to high costs. Operating Facilities A 5-MW combined cycle facility using the high-pressure Lurgi type gasi- fier was to have been commissioned in 1980. This gasifier is located at I I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Table 1. SINGARENI COAL FEEDSTOCK CHARACTERISTICS AND MATERIAL INPUTS Coal: Singareni coal Particle size 6 t/h 6-30 mm Ash fusion temperature: 1280?C Net CV (KJ/kg): 17,640 Proximate analysis (Wt X): Moisture 4.80 Ash 36.90 V.M. 25.44 F.C. 33.48 Ultimate analysis (Wt 7.): 42.82 2.82 S 0.62 N 1.00 0 5.97 MM 40.59 Moisture 4.18 7.2 t/h; 14 bar (14x105N/m2); 100?C 2.05 t/h; 14 bar; 380?C Net CV 4930 KJ/Nm) Steam 1.8 t/h; 10 bar (106Nm2)saturated Tar 0.29 t/h; 9 bar (9x105Nm2); 110?C 14.76 t/h; 9 bar (9x105Nm2); 110?C Gas analysis (Vol. %): CO2 15.48 CO 9.20 H2 19.48 H2O 19.42 CH4 4.58 N2 31.81 H2S 0.02 B-225 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Trichy, India. BHEL is also developing a single-stage fluidized-bed gasifi- cation unit at Hyderabad and a Koller-type single-stage gasifier at Trichy. These two developments are summarized in Table 3. Major Funding Agencies Bharst Heavy Electrical Ltd. is funding the above mention gasification development programs. Technical Problems The technial problems involved with the this process include hot gas cleanup, mechanical problems associated with gasifier grid rotation, scale-up, and lock-hopper coal feeding. In addition, ball valves are being substituted for cone-type valves used by Lurgi the gasifier. These new valves have yet to be proven. Capital Costs Capital costs for the BHEL process combined cycle facility have not been published. However, because of the relatively dirty gas produced by the Lurgi-type gasifier it is believed that this process will be more expensive that other combined cycle projects such as the Cool Water Texaco project in California. 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 i. Single-Stage fluidized bed gasification unit (Hyderabad): Coal throughput: 750 kg/h; particle size: 0-6 mm Max. operating pressure: 10 bar Operating temperature range: 1000-1300?C Gasification media: Steam + air Gas cleaning: cyclone, quenching pipe and venturi scrubber Product gas: low-heating valve gas with a net heating value of 4200 kcal/kg [17.58 MJ/kg) Status: Conceptual design finalized; detailed engineering and design in progress. ii. Koller-type Single-Stage Gasifier (Trichy): Capacity: 4000 N3/h Product gas temp.: cooled from 350-450?C to 100-110?C in a water-sprayed pre-cooler C.V.?f product gas: 1384-1694 kcal/Nm3 at full load operating pressure: atmospheric Air supply: 2600 Nm3/h Max. hot gas efficiency: 89% cold gas efficiency: 79% at 100% full load Steam generated by jacket boiler: 330 kg/h at 0.5 ata Additional details: Water-cooled jacket; automatic charging and weighing equipment; rotatng ash pan, at 0-2.5 rev/ Status: pilot plant under performance tests. 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 JAPANESE COAL LIQUEFACTION PROCESS 29. Mitsui Solvent Refined Coal Process Process Description The Mitsui Solvent Refined Coal (SRC) process was developed to produce a clean burning solid fuel from coal. This solid fuel, which has low melting characteristics, is low in ash and sulfur content. The characteristics of this solid fuel product are presented in Table 1. Testing of this process has been performed in a 5 ton/day pilot plant since 1977 by the Mitsui Coke Co. In this facility coal is sized to less than 25 mm for storage in a coal bin. From storage the coal is sent to a dry grind pulverizer and reduced to a maximum of 100 mesh before storage in a coal weighing hopper. This hopper is capable of feeding 5 tons/day of coal to a slurry preparation tank at a con- stant rate. In the slurry tank a uniform slurry containing one part coal and three parts recycled process solvent is produced using an agitator and a cir- culation pump. Ash Sulfur Carbon Hydrogen Low Heating Value Specific Gravity Softening Point Grindability (Hardgrove Index) 0.1 wt. % max. 0.3 wt. % max. 88 - 90 wt. % 5 - 6 wt. % ca. 9,000 kcal/kg 1.25 approx. 150?C 150 The slurry is continuously pumped from the slurry mixing tank to a slurry preheat section prior to entering the dissolver reactor. Pressurized hydrogen is added to the slurry stream at the inlet of the preheat section. The slurry entering the dissolver unit is reacted at 420? to 430?C at 1075 psi for ap- proximately 1 hour. Most of the coal entering the dissolver is decomposed to a liquid product with the exception the coal's ash and other unreactive con- stituents. The coal extract is then sent to a separation system, which 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 t 1 t consists of a high- and medium-pressure separation process. The coal extrac- tion is separated into vapor phase products and liquid phase products, which include residue. The vapor phase products are then condensed to separate the light hydrocarbon and water from the gaseous products. The liquid condensate is stored and the recovered gases are recycled to the preheat section. Before recycling these gases are purified in a caustic soda and water wash system. A part of the washed gases are purged to maintain the hydrogen content in the gases at the dissolver. The remaining gases are compressed and mixed with make-up hydrogen before entering the dissolver preheat section. The liquid phase products are depressurized, cooled and sent to the filter feed tank. The stored liquid products are put into a pressurized leaf filter. The operation is a repetition of precoating, filtering, rinsing, and drying, to process 6 tons of liquid products per one cycle operation. Solid free filtrate which is obtained from the filter is sent to the light end column feed tank. The stored filtrate is charged to the light end column and distilled under atmospheric pressure, then separated into naphtha, wash solvent, and SRC plus process solvent. The naphtha and the wash solvent are transferred and stored in tanks. The SRC plus the process solvent are heated in the vacuum flash preheater and sent to the vacuum flash column where the SRC is separated from the process solvent. The SRC is sent by gravity to the solidification unit where the SRC is quenched by water and solidified. The solidified SRC is conveyed and stored as product. The process solvent is stored and used as recovered process solvent. A process flow diagram for this process is presented in Figure 1 for the 5 ton/day pilot plant. This facility has been operated on Miike Coal (Japanese) as well as Millmerran and Victorian Australian Coals. The pilot plant test results for these coals are presented in Tables 2, 3, and 4. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 a z Q J 0 N ? Y S ? ZI U J HI N { . jh  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 (1) Ultimate and Ash Analysis of Coal (dry coal basis) Carbon Hydrogen Nitrogen Sulfur Ash (2) Test Result Solubility 97% (moisture ash free basis) Chemical Hydrogen Consumption 2 wt. % (dry coal basis) Distillate Yield 10 wt. % (dry coal basis) SRC Yield 63 wt. % (dry coal basis) (1) Ultimate and Ash Analysis of Coal (dry coal basis) Carbon 64.0 wt. % Hydrogen 5.5 Nitrogen 1.1 Sulfur 0.5 Ash 19.7 (2) Test Result Solubility Chemical Hydrogen Consumption Distillate Yield SRC Yield 91% (moisture ash free basis) 3 wt. % (dry coal basis) 10 wt. % (dry coal basis) 50 wt. % (dry coal basis) (1) Ultimate and Ash Analysis of Coal* (dry coal basis) Carbon Hydrogen Nitrogen Sulfur Ash * Used as Baiquettes with 15 wt. % water. B-231 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Process Goals The goals of the Mitsui SRC Development Co. Ltd., are to develop this process for the production of a clean fuel source as well as a source of car- bon material for electrode production and as a source of coking additives. As an energy source, even coals of high sulfur content, if turned into SRC, can be converted to a clean energy source of low ash and sulfur content. This is an important feature of SRC. In comparison with other coal lique- faction methods the SRC process is less costly because it consumes less hydro- gen and in addition, SRC, if heated, can be used as a liquid fuel. By pro- cessing through hydrocracking SRC can be converted to light fuels such as gasoline. Light and middle distillates produced from SRC process contain some chemical industry feedstocks such as benzene, toluene, xylenes, and phenols. Various raw materials for chemical industry can also be produced by hydrocracking of SRC. As a carbon source, needle coke can be produced, with high yields through delayed coking and calcining of SRC. This high-quality calcined coke can be raw material of ultra-high-power electrodes (UHP). In producing blast furnace coke, the raw material blended with SRC can produce coke which has a high strength at elevated temperature. Therefore, from the viewpoint of utilizing unused coal resources (noncaking coal, brown coal) to counter the future shortage of supplies of strongly coking coal, this application of SRC has great significance. Relationship to Prior Technology In 1971, perceiving the promising future of coal liquefaction by a new solvent extraction method, namely, the Gulf Oil Corporations Solvent Refined Coal (SRC) process, the Mitsui Mining Company was quick to proceed with a study of the new technology. In June, 1972, the Mitsui SRC Research Consortium was organized by four enterprises, Mitsui Mining Co., Ltd., Mitsui Coke Co., Ltd., and Mitsui & Co., Ltd., to establish an SRC process research and development organization. The consortium started liquefaction tests with more than fifty kinds of domestic and foreign coal by the autoclave method at Mitsui Coke Company's 1 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Ohmuta Works, followed by the completion of a bench plant for continuous operation in 1973 for further study of the process. In December 1974, for the utilization of overseas leading technology, the Consortium made a contract for joint SRC development with Gulf Oil Corporation, the parent company of the Pittsburg and Midway Coal Mining Co., the originator of the SRC process. In 1975 the consortium developed its own SRC process for the purpose of producing not only SRC as a clean coal but SRC as a substitute for strongly coking coal and coking additive for use in the production of iron-manufacturing coke. In 1973 the consortium built Japan's first coal liquefaction plant using the SRC process (coal feed 5 T/SD) at Mitsui Coke Company's Ohmuta Works with technical assistance from Gulf. While the products of Gulf's SRC process and Mitsui process are both in the form of pitch-like solid, the raw material can be all kinds of coal, lig- nite, and brown coal, except anthracite. In addition, the product contains little sulfur with its heating value reaching as high as 9,000 kcal/kg, which proves its usability not only as a clean energy but also as a substitute for coking coal and high grade carbon material. Development is also under way to use SRC as a substitute for strongly coking coal and coking additive under a joint research contract made with Nippon Steel Corp. which started in April, 1979. In the meantime, Gulf Oil Corp., the Consortium's partner, upgraded the SRC-I process to the SRC-II process capable of producing a clean liquid fuel. Gulf further experimented with the improved process at a 50 T/SD pilot plant in the suburbs of Tacoma. Plans called for the construction an operation of a 6,000 T/SD plant in West Virginia for large-scale demonstration of the process with financial support of the U.S. Department of Energy (DOE). This plan called for the involvement of the United States, West Germany, and Japan (cost borne by the governments of these countries). Gulf invited Ruhrkohle AG of West Germany and Mitsui SRC Research Consortium to organize a private joint venture corporation to carry out this plan. On the understanding that it is Japan's only private enterprise qualified to join the venture and at the request of Gulf and Ruhrkohle, the Mitsui Consortium decided to participate in the project. The private joint venture corporation, SRC International, Inc. was formally established in July, 1980. But the governments of the three I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 countries decided to terminate this SRC-II project because of financial' pro- blems in June, 1981. The SRC International, Inc., however, will be continued to develop further coal liquefaction studies as a private joint venture cor- poration. Operating Facilities A 5 ton/day pilot plant has been in operation since March 1978 at the Mitsui Coke Company's Ohmuta Works, Goseimachi, Ohmuta-City, Fukuoka. Con- struction, which started in September 1976, was completed in December 1977 at a cost of 1.8 billion Yen. Operating costs have been estimated to be 400 million Yen per year. This facility has a 5 ton/day coal input and, will produce approximately 3 tons/day of SRC. The plant is operated by four groups, each of five persons, on three shifts. The operation is controlled and observed from the control room except for a part of the coal handling. Major Funding Agencies To cope with the domestic and overseas situation, the four consortium members established Mitsui SRC Development Co., Ltd. in February 1980 to take over the consortium's business for the further development of SRC under a substantially complete system. In addition, the seven companies which took part in building the 5 T/SD SRC plant held shares in the new company to strengthen the arrangements for further SRC commercialization. The organiza- tional outline of this new company is presented in Table 6. In preparation for SRC commercialization, Mitsui conducted basic tests of Victoria Brown Coal samples and developed a special dehydration technique for brown coal and a process of treating woody tissue. This development confirmed that brown coal is both technically and economically advantageous as an,SRC feedstock. The State Government of Victoria, which evaluated Mitsui's techni- cal level, has agreed to perform a feasibility study by Mitsui after June 1980 for the construction of a commercial SRC plant in the vast brown coal field area. Capital Costs Australia's CSR and Japan's Mitsui SRC Development Co. have agreed to a 50-50 joint venture to evaluate commercial production of solvent-refined coal and liquid fuels from lignite in Australia's Latrobe Valley in Victoria. They will spend more than $3.5 million in studying a 6,000 ton/day SRC plant using t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 The Mitsui process. The study is expected to be completed by June of 1982, and a $1.7 billion plant could be onstream as early as 1987. However, the most recent information indicated that MITSUI/CSR has postponed the construction of this facility. In addition MITSUI/CSR has expanded their development goals to include coal gasification technology through Germany's Ruhrkohle. The Mitsui SRC process is similar to the Gulf SRC development and there- fore these processes should share common problems. Most of the major problems have been resolved in pilot plant research. Table 6. ORGANIZATIONAL OUTLINE FOR THE MITSUI SRC DEVELOPMENT CO., LTD. Founded: February 20, 1980 Head Office: Mitsui Main Building, 1-1, 2-chome, Nihonbashi-Muromachi, Chuo-du, Tokyo 103, Japan Plant Location: 1-banchi, Goseimachi, Ohmuta-shi, Fukuoka-ken 836, Japan Chairman: Toshikuni Yahiro (President of Mitsui & Co., Ltd.) President: Shingo Ariyoshi (Chairman of Mitsui & Co., Ltd.) Number of Employees: 72 Capital: Y500,000,000. Shareholders: % Mitsui & Co., Ltd. 28.5 Mitsui Mining Co., Ltd. 23.5 Mitsui Coke Co. , Ltd. 5.0 Toyo Engineering Corporation 12.0 Mitsui Engineering & Shipbuilding Co., Ltd. 8.0 The Japan Steel Works, Ltd. 8.0 Ishikawajima-Harima Heavy Industries, Co., Ltd. 6.0 Mitsui Construction Co., Ltd. 3.2 Mitsui Toatsu Chemicals, Inc. 3.0 Mitsui Miike Machinery Co., Ltd. 2.0 Yamatake-Honeywell Co., Ltd. 0.8 B-235 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018- 30. Nippon Brown Coal "Kominic" Hydrogenation Direct Coal Liquefaction Process Process Description In 1972 the Japanese firms of Kobe Steel, Ltd., Mitsubishi Chemical Industries, Ltd., and Hissho-Iwai Co., Ltd., formed the Kominic group. The purpose of this enterprise was to exploit the vast brown coal (lignite)' deposits in Victoria State, Australia, to produce a solid solvent-refined coal (SRC-I) fuel. With this in mind, Komonic group entered into a research relationship with the South African Coal, Oil and Gas Corp. (SASOL) to investigate the liquefaction characteristics of brown coal in SASOL's SRC-I liquefaction process. In 1977 Kobe Steel constructed 500 kilogram/day process development unit for further SRC-I studies on Victoria brown coals at the Iwaya Works west of Osaka.5 During the late '70's Japan's as well as the Kominic group's goals shifted away from solids production (for metallurical coke) toward liquid fuels production. To meet these goals, Kobe Steel developed an additional high-pressure hydrotreating stage which when added to the original SRC-I type process produces a liquid with approximately 70% heavy oil and 30% light oi1.2 During this development period (1979) the Komi;nic group ran tests on Victoria brown coal in SASOL's SRC-II liquefaction process. After these tests, Kominic modified their SRC-I process at Osaka to an SRC-II type process using the group's new high pressure hydrotreating stage. It is believed that the Kominic process has been developed by the joint partner company of Kobe Steel, Ltd. In this process (Figure 1) coal is pulverized, preferably 200 to 300 mesh, and mixed with recycled pulverized catalyst (cobalt-molybdenum and/or iron, iron-sulfur) of the same consis- tency. The recycled catalyst is presumably recycled ash residue, depending on the coal properties. However, the catalytic effects of this ash residue are highly dependent on the coal type and coal deposit location. In addition to pulverized coal and catalyst, a hydrocarbon solvent such as anthracene oil, having a boiling point of over 150?C, is added and slurried in a slurry tank. This slurry is then pumped, at a flow velocity of from 10 to 400 m/hr to a preheater.. The slurry is mixed with a high pressure, hydrogen-rich gas, and this mixture is then heated to a temperature of 420? to 440?C. 1 I N 5 T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 M C rl C 0.0 O 0 C7 n.7 P~ ~ W  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 The hot slurry mixture is then introduced into the base of the hydro- genation reactor at a pressure of 100 to 150 atm. The stream leaving the top of the reactor consists of dissolved gases in a light oil/solid residue slurry. This mixture is then sent to a solid-liquid separator. The solid-liquid separator consists of a liquid cyclone and a solid accumulating tank. Connected to the top of the liquid cyclone is a gas-liquid outlet pipe. The solid-liquid separator is operated in a batch mode and therefore a second solid-liquid separator is utilized in an alternating pattern. The solid residue discharge from the separator is collected in a slurry tank where part of it is recycled. The liquid that is withdrawn from the separator is then sent to a dehydrogenation cyclopolycondensation reactor for further processing. The dehydrogenation-cyclopolycondensation reactor is operated at ~20? to 440?C and 100 to 150 atmospheres. In this reactor the liquid is subject to treatment under noncatalytic conditions in the presence of a small amount of hydrogen gas with a total partial pressure of 7 to 70%. The reaction time within the reactor is 5 to 90 minutes, as was the case in the hydrogenation reactor. With this treatment the higher oil liquid entering the reactor is converted from an oil having naphthenic or paraffinic-rich properties to a heavier oil having aromatic-rich properties. This oil is then sent to a gas- liquid separator for further processing. The aromatic rich oil produced in the NBCLP process can then be sent to a refinery for further processing. To achieve the atomic ratio of hydrogen to carbon of liquid fuels, direct liquefaction processes rely on doubling or tripling the ratio from that of coal. Unlike gasification processes, which produce hydrogen internally by the water-gas shift reaction, direct liquefaction processes require the outiside addition of hydrogen. About 1000 SCF of hydrogen is needed per 100 pounds of coal (MAF) feedstock. Therefore, for a 25,000 ton/day facility, about 5 X 108 CF/day of hydrogen is required. To meet this demand, hydrogen must be produced by steam reforming of methane or light oil feedstock, partial oxidation of heavy crude, or coal gasification. About 26,000 bbl/day of naptha would be required for the process to produce a nominal 60,000 bbl/day of products. Because naptha is not likely to be available in adequate supply in Japan, hydrogen production via coal gasification is more likely. I  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 ' 1 1 1 A U.S. patent that as recently been awarded to Kobe Steel for this process is shown as an Exhibit. A technology fact sheet for this process is presented in Table 1. To further promote to commercialization of this direct liquefaction process, the Komonic group was reorganized with the addition of Idemitsu Kosan and Asia Oil on August 12, 1980.6 The new company, Nippon Brown Coal Liquefaction Co., is capitalized at $2.1 million with equal 20% investments from each of the five participating companies. This new company has recently entered into negotiations for a joint Japan Australia brown coal liquefaction project with the Victoria state government and the Australian government. Future plans call for the construction of a 50 metric ton/day pilot plant for which construction was started in 1981 with operation expected in 1983. This plant will be constructed near the coal mines in Victoria state at an estimated cost of $150 to $175 million (U.S.). About 90% of this plant will be funded by the Japanese government as part of its national Sunshine program. In return for government support all technologies and know-how gained through the operation of the pilot plant will be made available to the government. The Australian government will supply the basic infrastructure, plant site, electric power, industrial water, and feedstock coal.7 A second phase is currently envisioned that calls for the construction startup of a 5,000 ton/day demonstration plant in 1985 at a cost of between $833 million and about $1 billion (U.S.). This demonstration plant would then be expanded into a commercial size facility by 1990 with the addition of five, 5,000 ton/day units, The Victoria state government has pledged to the Japanese full coperation in supplying the feedstock brown coal for the 30,000 ton/day commercial plant. The total project cost for the first three phases is estimated at over $4 billion (U.S.).6 Relationship to Prior Technology This development is not directly related to any commercially developed process. However, the general principals of the NBCL process are similar to the SRC-II process developed in the U.S. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018- 1 1 u Ca cu u CU u cd cd 4a L, 1 Ed O 3 , 0 U ?H lt~ a) 1.4 ul ppa E ?v~ OI 0 co 44 . 1~I E a1 Pq u G 1~ 0 N a) U O a U ?rl a) ?r1 ,-1 u z Cl ri 0 E O CU a) U t 1 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 CO m 0 1 1 W G 0 0 ?ri 1.1 4J co m 00 0 m v b m a) u x u Cn 0 v u a, .~ G ?-1 0 El r4 0 u w 0 a' 0a 0 c0 PCB 0 0 G aJ ''. 10 C 0 L V-1 0 G iJ U G 0 W 00 0 m m 1J 0 G co 10 ,--1 0 C/] aJ 0 ?-4 G G N 00 0 f u aJ u CO 44 G 'ty CC 0 LJ a) C u r-1 0 00 0' U 44 G ?r1 G 0 rl ,-a 0 0 b cO m v-1 0 m 0 a) 0 0 a G, 0 U u O C U .0 m 0 G 0 0 I H $4 m b 0 0 a) 1?+ a) 0 0 0 a) 4 U r14 z - a) a) 0 C7 b Cl) z a, a) ?,-4 m 00 0 1-4 G a) v a 0 G U a) ~J I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Operating Facilities In 1977 Kobe Steel constructed a 500 kg/day process development u the Iwaya Works west of Osaka to test Victoria brown coals. Major Funding Agencies The NBCL liquefaction process has attained the status of a nation project and as such is being partially funded by the Japanese government to a commercial level. The Nippon Brown Coal process is currently in the pilot plant sta e of development. Due to the lack of available data and operating experience, critical problems for this process have yet to surface. However, due to the similarity of this process to other coal liquefaction processes, in particular the SRC process, parallel problems might be expected to occur. In the SRC process corrosion/erosion problems occur in four main process areas that are similar to those found in the Nippon Brown Coal liquefaction process. These areas include coal receiving and preparation, preheating and dissolvin filtration and mineral residue drying, and solvent recovery. In the area of coal receiving and preparation, typical problems associated with similar facilities occurred in coal slurry centrifugal pumping equipment and high-pressure plunger-type slurry preheater charge pumps These problems centered on packings and seal leakage, as well as check valve and plunger erosion. In the preheating and dissolving sections few materials problems developed. These minor problems involve nozzle sleeve lining corrosion and scale formation. However, in the area of high- and intermediate-pressure separator equipment, severe stress corrosion cracking of Type 304 stainless steel linings occurred. attributed to polythionic acid and chloride stress corrosion cracking 'at weld sites. Corrosion was not experienced in any of the other materials inithe separators, including carbon steel. Corrosion/erosion material problems also occurred in the filtration and mineral residue drying areas. Most problems occurred in the heat exc1anger material where severe erosion of metal tubes was encountered as well as tube bulging due to carburization in the 3/8 inch thick 304 SS dryer shell. 1 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 _  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 I Severe corrosion/erosion problems have also occurred in the reboilers, air coolers, fractionation equipment, piping, and tower walls of the solvent recovery section of the SRC process. These problems have caused several major shutdowns. The most severe corrosion occurred in moving parts and materials that came in direct contact with the liquid solvent. Most of the problems required a change in material specifications to eliminate the situation. However, acceptable corrosion rates have yet to be achieved in areas such as the stainless-steel trays used in the separator towers. Capital Costs The investment cost of the Nippon Brown Coal Liquefaction process developed by Kobe Steel, Ltd., has not been published. However, based on a process flow sheet comparison with other coal liquefaction processes, the Nippon Brown Coal process does not differ significantly from the SRC-II process which is being developed by the Gulf Oil Corp. in the U.S. Based on this comparison, the two processes should have similar capital cost requirements. The total plant investment costs for the SRC-II process are shown in Table 2. These costs include engineering, land, plant, and G&A costs. Also included is a 20% contingency factor based on the state of the technology readiness. Make-up hydrogen production will cost about $7.50/million Btu based on capital costs and coal requirements in addition to residues. This amounts to a product cost content for liquids of about $3.50/million Btu. Hydrogen at $10.00/million Btu would result in a product cost content of about $4.50/million Btu. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' Table 2. TOTAL PLANT INVESTMENT, NIPPON BROWN COAL LIQUEFACTIOJ 1978 $ 1980 $ (Millions) (Millions) Major Liquefaction Equipment 675 810 Other Equipment and 245 295 Labor and Erection 530 635 Hydrogen Productirn Plant (Coal Gasi`ic;ation) 825 1000 Analysis cost basis: $2.7 billion (1980 $) Coal Requirement: 25,000 tons/day @ 12,500 Btu/lb (including 2500 tons/day added to 7500 tons/day residues for hydrogen make-up) 1 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-a  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' United States Patent [)9) Nakako et al. [54] COAL LIQI ! F ~CT1ON PROCESS AND APPARATUS THEREFOR Inventors: Yukio Nakako, Nishinomiya; Shizuo Yokota, Kobe. both of Japan [73] Assignee: Kobe Steel. Ltd., Kobe, Japan [21) A ppl.N o.: 915,575 [22] Filed: Jun. 14, 1978 Related U.S. Application Data (63) Continuation-in-part of Ser. No. 801,920, May 31. 1977. abandoned. (30] Foreign Application Priority Data May 28. 1976 [JP] Japan .................................. 51-62811 May 28. 1976 [JP] Japan .................................. 51-62812 May 28, 1976 [JP) Japan .................................. 51-62813 May 28, 1976 [JP) Japan .................................. 51-62814 May 28, 1976 [JP] Japan .................................. 51-62815 (51] Int. C1.1 ................................................ C10G 1/06 [52] U.S. CI ...................................... 208/10; 208/8 R [58] Field of Search .......................... 208/8, 10 (56] References Cited U.S. PATENT DOCUMENTS Re. 25,770 6/1961 Johanson ................................ 208/10 2.913.397 11/1959 Murray et al ............................ 208/8 3.018.242 1/1962 Gonn ....................................... 209/8 3.117,921 1/1964 Gorin ....................................... 208/8 3.594.303 7/1971 Kirk et a! ................................. 208/8 3.644,192 2/1972 Li et al ..................................... 208/8 3.932.266 1/1976 Sze et al ................................... 208/8 4,219,403 Aug. 26, 1980 FOREIGN PATENT DOCUMENTS 20957 of 1929 Australia 8303 '/1932 Australia Primarv Examiner-C Davis Attorney, 4gent. or Firm-Oblon. F sher. Spi%ak. McClelland & Mater (57] ABSTRACT A coal liquefaction apparatus whit. comprises a siurrn mixing tank. a preheater, a hydrogenation reactor. anc a gas-liquid-solid separator or separators in series anc a gas-liquid separator and at least one solid-liquic separa- tor are interposed between the hydrogenation reactor and a dehydrogenation cyclopolyc ndensation reactor which is positioned upstream of t e finai gas-liquid- solid separator. The coal liquefaction process corn nses the steps of heat treating a slurry prepared by mi ing coal fines with a hydrocarbon based solvent having a boiling point greater than 150' C. in the present of hydrogen at a temperature of 300' to 500' C. and pressure of 50 to 700 atms. thereby forming a gas-liquid-solid mixture: separating and removing solids from said gas-liquid- solid mixture as a reaction product: separating and re- moving a residuum liquid fraction rom said mixture: and heat treating said residuum liq id fraction in the presence of hydrogen at a low partial pressure at a temperature of 300' to 500' C. and pressure of 50 to 700 atms. 12 Claims. 12 Drawing Figures HIGH PRESSURE HYDROGEN-RICH GAS Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 U.S. Patent Aug. 26, 1980 Sheet I of 5 4,219,403 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' U.S. Patent Aug. 26, 1980 Sheet 2 of 5 4,2 ~ 9,403 1 I 1 FIG.2 i. HIGH PRESSURE HYDROGEN-RICH COAL F1NEI f GAS FIG.3 24 2I-. I HIGH PRESSURE HYDROGEN RICH GAS Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 U.S. Patent Aug. 26, 1980 Sheet 3 of 5 4,219,403 HIGH PRESSURE REDUCTIVE GAS COAL FWE A F_b~ KX I GS 106" ~05  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-q U. S. Patent Aug. 26, 1980 Sheet 4 of 5 4,~ 19,403 1 11 t 1 r  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 U.S. Patent Aug. 26, 1980 Sheet 5 of 5 4,219,403 HIGH PRESSURE 313 HYDROGEN-RICH GAS 1 I COAL FINE 0 301 303 312 FIG. 10 J t i  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018- COAL LIQUEFACTION' PROCESS AND APPARATUS THEREFOR This application is a continuation-in-pan application of co-pending application Set. No. 801,920. filed May 31, 1977. and now abandoned. BACKGROUND OF THE INVENTION I Field of the Invention The present invention relates to a coal liquefaction process and an apparatus therefor. and more particu- larl% to a coal liquefaction process which can be per- formed efficiently to improve the yield of reaction products. particularly, the heavy oil product which is well suited as a metallurgical carbonaceous carbon ma- terial. 2. Description of the Prior Art A coal liquefaction process is known in which coal fines ara treated in the presence of hydrogen to liquify the coal. The coal fines used in the coal liquefaction process include low grade coals such as bituminous, semi-bituminous, and sub-bituminous coals and lignite as well as similar solid carbonaceous materials such as shale. According to the conventional process of the type described. coal fines, a hydrocarbon solvent hav- ing a boiling point of over 150' C., and a suitable cata- lyst such as a ferro-sulfuric system catalyst, if desired. are mixed in a slurry, (The use of a catalyst may not be necessary or essential because the ash in coal functions as a catalyst), and then the slurry is preheated in a pre- heater. A high pressure hydrogen-rich gas is added thereto preferably prior to the preheating of the slurry. The preheated slurry and a high pressure hydrogen-rich gas are passed into a reactor where a hydrogenation reaction is conducted at a high temperature and pres- sure, e.g., 300' to 500' C., 50 to 700 atms. Then. a mix- ture of reaction products of reactor effluent is intro- duced into two or more separators connected through pressure-reducing valves to each other, wherein the pressure is progressively reduced and gas. liquid and solid are flash distilled. At the present time, the objective in the liquefaction of coal is to form a heavy oil product having a high boiling point for use as a metallurgical carbonaceous material for use, for instance, in the manufacture of steel-making coke or carbon electrodes for alumina electrolysis. The liquid product or effluent. generally, includes solids such as ash, unreacted coal, catalysts. and insoluble reaction products. Accordingly, the re- moval of these elements would improve the quality of the heavy oil product for its intended use. In general. a metallurgical carbonaceous material should have an ash content of less than 10%. Coal liquefaction process hitherto has been beset with many formidable problems. which will be described as follows: - Problem I Because of excessive hydrogenation. the yield of a heavy oil fraction in the liquid reaction product is not high enough. Moreover. solids condense along with a heavy oil fraction. in the final stage separator. where solids and heavy oil are to be separated. However. in the conventional method. a mixture having a high sis- cosity results at this stage. so that much time and effort must be devoted to filtering in the ,cpantion stage to sroarate solids from the ,il. Far !hi' reaso n..i ueb:ml s 2 added to lower the viscosity of the mixtu e. and if re- quired, the mixture is heated. followed b centrifugal separation, sedimentation separation, or s paration by means of separators such as liquid cycl nes. In any 5 event, a light oil in the case should be added to the oil in a considerable amount. and this resul s in an un- wanted increase in the amount of the mixture to be treated, which causes an increase of the n mber of ap- paratus for separating the solid and liquid and deterio- 10 rates an economic effect In addition, upon flash distilla- tion, a solid fraction and a heavy oil fracti n both pass through pressure reauc:ng vaives. so that i the pressure is instantaneeusiy reduced to a considerably lower level, then wear of the pressure reducing v lues occurs. 15 To avoid this, many separators and pressure reducing valves have to be used in order to gradually reduce the pressure of the system. The use of many such separators and reducing valves increases the expense of capital equipment. 20 Problem 2 In the coal hydrogenation reactor, a m xture of hy- drogen gas or a high pressure reductive gas such as CO+H20, CO-H2O-H2, CO-- or H rich gas and 25 the coal slurry which has to be preheated is subjected to a liquefaction reaction at a high temperature and pres- sure, followed by flash distillation to separate the prod- uct obtained into gas. liquid, and solid p oducts. It is advantageous to introduce the slurry and t e high pres- 30 sure reductive gas into the reactor from it bottom and expel the products from the top of the re ctor. In this case, the viscosity of the solvent is decreas d because of the reaction at high pressure and temperat re, so that a tendency arises for the settling of solids s ch as unre- 35 acted coal fines, catalysts and ash from t e liquid. To avoid this problem. the upward rate of flow of the mix- ture is increased relative to the settling r to of solids during reaction. However, in order to achieve this ob- jective, it is necessary to reduce the cross ctional area 40 of the reactor to some extent, and the nur ber of reac- tors connected in series should be increas to achieve sufficiently long residence times of the mix ure for reac- tion in the reactors. This is uneconomical t cause many pieces of apparatus such as gas-liquid sep rators. pipe. 45 and couplings must be used. Moreover, ore mainte- nance problems arise because of the more xtensive use of equipment. One of the attempts to solve his problem has been to reduce the number of reacto s while the liquid effluent from one reactor is recycle to another. 50 thereby extending the residence time o the slurry within the reactors. Alternatively, a reductive gas in great amounts is injected into the reactor to retard the settling of solids in the liquid reactant. Ho ever. in this technique, the concentration of unreacte coal in the 55 reactor is equalized both at the entrance a d exit of the reactor. so that the reactor itself changes i type from a piston flow reactor to a complete mixing reactor. with the result that the reaction efficiency decre es substan- tially relative to the reaction space or v lume of the 00 reactor. Problem A high boiling point and high viscosity reaction prod- uct is obtained from the bottom of the sep rator in the 0! final stage of the multipie stage flash distillation. Ac- cordingt.. the .tezree of condensation of lids is not ,ufficientt% high. thereb% requirine further eparation ..situ. 'ram :he iiQut,, Hov e%er. because of the hizh I A 1 I r  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 I I t I viscosity of the reaction product, satisfactory separation of solids cannot be attained by a filtering process. For this reason, as has been described earlier, a light oil is added to the liquid product to decrease the viscosity of the mixture or heat is applied thereto, followed by cen- trifugal separation, sedimentation separation or separa- tion in a liquid cyclone. Accordingly, the amount of the mixture to be treated is increased, thus failing to meet practicability requirements. It is therefore evident that no satisfactory separation process for solids has yet been found. SUMMARY OF THE INVENTION Accordingly, one object of the present invention is to provide a coal liquefaction process and an apparatus 15 therefor, which improves the yield of liquified product suitable for use as a metallurgical carbonaceous mate- rial, while avoiding the wear of pressure reducing valves, and dispensing with multiple stage separators and pressure reducing valves. 20 Another object of the present invention is to provide a coal liquefaction process and an apparatus therefor, which provides an improved reaction efficiency rela- tive to the space within the reactor, without using many reactors and couplings. 25 Still a further object of the present invention is to provide a coal liquefaction process and an apparatus therefor which improves the separating efficiency of solids from the liquid in separators after the hydrogena- tion reaction. 30 Yet a further object of the present invention is to provide a coal liquefaction process and an apparatus which eliminates the public nuisance problem caused by the disposal of catalysts. Still a further object of the present invention is to 35 provide a coal liquefaction process and an apparatus. in which solids may be efficiently separated from a high boiling point, high viscosity reaction product obtained from the bottom of a final stage separator, in a reason- able manner. 40 According to the first aspect of the present invention, solids are separated from a reaction mixture of low viscosity and at high temperature immediately after the hydrogenation reaction, and the reaction mixture from which the solids have been removed is then subjected to 45 a dehydrogenation-cyclopolycondensation reaction under a low partial pressure of hydrogen at a high tem- perature under non-catalytic conditions. The dehy- drogenation-cyclopolycondensation reaction is a reac- tion in which a light oil is dehydrogenated under non- 50 catalytic conditions at a low hydrogen partial pressure, thereby being converted into a heavy oil, while the fraction of the reaction product which has been given a naphthenic or paraffinic-rich property because of the addition of an excessive amount of hydrogen, is dehy- 55 drogenated and cyclicpolycondensed. More particu- larly. the reaction mixture from the hydrogenation reac- tor is introduced as it is or after passing through a gas- liquid separator, into a solid-liquid separation system consisting of solid-liquid separators having pressure 60 reducing valves, with the lower portions of the separa- tors being connected to solid accumulating tanks, and with the top portions thereof connected to gas-lined outlet pipes. The liquid fraction separated therein :s subjected to a non-catalytic heat treatment in the pres- e5 ence of hydrogen at a low partial pressure. Suitable solid-liquid separators employable in the present in-, en- tion are :,.:.ones. sand cones. and the like 4 The non-catalvn: heat treatment .s ,u:ii trur :he reaction product is maintained at a given temperature for a given period of time in the presence of hydrogen at a low partial pressure. Any type apparatus may he used, as long as the above described conditions an he maintained. For instance. a device having the same construction as that of the reactor, or heating Besse: which is used for preheating may be used as the non- catalytic heat treatment vessel. More specifically. the duced as it is, or after passing it through gas-;iyuid ,er.,i? rators into solid-liquid separators at a temperature euu.i. to or less than the temperature at the ex;r :,f a reactor but, in any case. a temperature 100? C no less than the latter. In the solid-liquid separators. solids accumulate in the lower solid-accumulating tank. while liquid and gas. if any, overflow and are withdrawn through oser- head gas-liquid outlet pipes. The liquid fraction thus withdrawn is mixed with a hydrogen-rich gas. as re- quired, and then introduced into a dehydrogenation- cyclopolycondensation reactor. Meanwhile, the reac- tion product from the hydrogenation reactor contains an excessive amount of a high pressure hydrogen-rich gas, so that hydrogen need not be added in this stage. However, when the reaction product passes through a gas-liquid separator. the addition of hydrogen is re- quired, or a small amount of high pressure hydrogen- rich gas should preferably be introduced into the dehy- drogenation reactor. In the dehydrogenation reactor, a reaction mixture devoid of solids is maintained at a high temperature in the presence of a small amount of hydro- gen or at a low partial pressure under non-catalytic conditions so that the portion of the product which possesses naphthenic or paraffinic properties. is dehy- drogenated and cyclopolycondensed, thereby being converted into a heavy oil fraction which imparts an aromatic-rich property to the, oil which in turn yields a heavy oil well suited as a metallurgical carbonaceous material. In this respect. the presence of a small amount of hydrogen or a low partial pressure of hydrogen is mandatory for preventing an excessive amount of dehy- drogenation-cyclopolycondensation. The reaction mix- ture subjected to the dehydrogenation reaction is with- drawn from the top of the dehydrogenation- cyclopolycondensation reactor, then passed through separators and then flash-distilled by reducing the pres- sure through pressure-reducing valves. However, be- cause the reaction mixture is devoid of solids in this stage, the pressure-reducing valves are not damaged and there is no longer the need to separate solids from the liquid in the separator. Meanwhile, in the solid-liquid separating system. when one solid accumulating tank becomes filled with solids, then the solid-liquid separating system therefor shut off from the reaction-mixture-inlet passage. s here- upon the pressure in the separator is reduced to atmo- spheric pressure by means of a pressure-reducing s aive. and then, the accumulated solids are discharged through a bottom outlet port, as required. The solids thus discharged contain materials having a catalytic function, and thus may be used again in the coal slut-r At least two solid-liquid separating devices in naralle! are provided for one reaction system so that two-sohd- liquid separating devices may be used aiternate!,. i.e according to the so-called batch system operation More particulariy. the reaction mixture from the hvcr:- genauon reactor ,s first introduced .ender high ^ressur :nto one ?oiid-'ieuid separating JCs ice. and w n.e- '`.e  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 4.219,403 device is tilled with solids, then the connection is switched from the filled device to the other solid-liquid separating device in order to introduce the reaction mixture into the latter, while the pressure in the first solid-liquid separating device is reduced to atmospheric pressure in order to discharge solids therefrom. This cycle of operation is repeated for an efficient continuous separation of solids from liquid. In the second aspect of the present invention, the diameter of the reactor is increased and the number of reactors is reduced, while retaining the desired level of efficiency required for liquefaction or the hydrogena- tion reaction. In other words, the upward flow velocity of the reaction mixture in the reactor is adjusted in order to accelerate the settling of solids therein, and solids thus settled are discharged from the bottom of the reactor, while a fresh catalyst is supplied, as required, thereby maintaining the desired hydrogenation reac- tion. More specifically, in the present invention, at least two reactors each having a solid outlet port in the bot- tom of the reactors are connected in series, and a pre- heated mixture of a coal slurry consisting of coal fines, catalyst and a high pressure reductive gas is introduced into the first reactor through its bottom port so that it passes through the reactor at such a flow velocity that solids may settle in the reactor. In this case, the reaction mixture is separated into a relatively solid-rich layer and a relatively solid-lean layer. The solids which settle are discharged from the solid outlet port provided in the bottom portion of the reactor. In this respect, one or two solid accumulators are connected to the bottom of the reactor, so that solids may be stored therein in a sufficient amount, followed by flash distillation, and then the withdrawal of the solids. At the same time the solids present in the reaction mixture cannot be com- pletely separated in the first reactor, and hence, over- flow of solids occurs along with the reaction liquid, which are separated in the succeeding reactor in the same manner. In the second embodiment of the present invention. the catalyst substantially separates from the liquid and is removed in the first reactor, so that fresh catalyst should be supplied to the second reactor and thereafter through pipes leading to the catalyst accumulating tank to promote the hydrogenation reaction. Accordingly, the reaction is conducted in an efficient manner because of the supply of fresh catalyst. In addition, different kinds of catalysts may be used in reactors. For instance. a catalyst of the cobalt-molybdenum system, iron or iron-sulfur which possesses a high activity in the lique- faction reaction, is used in the first reactor for a highly efficient reaction, while a catalyst of a low activity is used for the second reaction and also thereafter when the reaction medium contains a relatively small amount of unreacted coal. Furthermore, no catalyst is supplied to the final reactor, so that a product possessing a naph- thenic or paraffinic property, because of excessive hy- drogenation is heated in the presence of a low partial pressure of hydrogen under non-catalytic conditions for the dehydrogenation-cyclopolycondensation reaction. thereby converting the liquid product into a heavy oil product having aromatic characteristics, which is well adapted for use as a metallurgical carbonaceous mate- rial. The flow velocity of the reaction mixture of the pres- ent invention depends on the kinds ana grain sizes of coal fines and :atalvsts used In short, the flow velocity 6 should be selected such that the solids in t mixture may settle. thus leaving a solid-rich solid-lean layer therein. For instance, w h oxide catalyst is used, and the grain sizes of 5 and the coal fines are 200 mesh, then the 1 velocity of the slurry stream should be about to prevent settling of the solids. i.e.. 360 m/ the flow velocity of the reaction mixture fluidize the same is about 1.5 m/hour In a 10 type of reactor, the flow velocity should about 1.2 m/hour to 360 m/hour. If the flow excessively low, then the liquefaction reacts proceed satisfactorily, but instead. coking oc the flow velocity should preferably be over 15 On the other hand. if the flow velocity is g 3600 m/hour, then the undesirable excessiv e reaction ayer and a !n an iron he catalyst )west flow 10 cm/sec our. while n order to ebullated ange from velocit, , is n does not urs. Thus. 0 m/hour. ,eater than overflow of solids takes place. The grain sizes of the coal fines and the catalyst particles should range fro 50 to 400 mesh, preferably from 200 to 300 mesh. Fo the grain 20 sizes in this range, the flow velocity of the lurry may range from I to 3600 m/hour, preferably from 10 to 400 m/hour. In the third aspect of the present invention, the reac- tion mixture is separated into a solid-rich layer and a 25 solid-lean layer, with an interface betwee the two layers being maintained at a given equilibria level. In the solid-rich layer of a given volume, ash and unre- acted coal fines are present which promote he hydro- genation reaction. On the other hand, in the solid-lean 30 layer, the dehydrogenation-cyclopolvconde cation re- action occurs which results in the yield of heavy oil product having an improved aromatic property, which is preferable from the viewpoint of a desirable metallur- gical carbonaceous material. In addition, the formation 35 of two layers permits the separation of solids of a lower ash content in an increased amount. Furthermore, the solid-rich layer thus separated may be wit drawn, as required. so that solids may be added to the slurry for reuse as a catalyst, thus saving the amount of catalyst to 40 be used. More particularly, in the present invention. in the hydrogenation reaction of coal fines, a t be having an opening tip is inserted into the hydrogenation reac- tor, while the other end thereof is connecte to an ash accumulator which is maintained substanti ly at the 45 same pressure level as that of the hydrogenation reac- tor. Then, the pressure in the accumulator is djusted so that a solid-rich layer may be introduced into the accu- mulator in order to maintain the interface between the two layers at a given equilibrium level. such that the 50 volume ratio of the solid-lean layer to the solid-rich layer falls between 1/6 to 2. In still another feature of the present iven ion. a tube having an open tip is inserted into the reactor through the base of the reactor, while the other end of the tube 55 is connected to ash accumulators, which have a solid withdrawing means at the base of the react r. The ash accumulators have gas pressure, flow rate control means and gas injection means in the tops o the accu- mulators. As a mixture of slurry and high p essure hy- 60 drogen-rich gas is introduced into the reactor, only the solid-lean laver is withdrawn from the top of the reac- tor, so that the interface between the twol layers as- cends. When the interface between the tw o layers passes over the open tip of the tube to a desired height 05 therefrom. which depends on the reaction conditions. the size of the reactor and the like. the soud-rich layer is introduced into an ash accumulator in an amount proportionai to the amount of the react:. n mixture I 1 t E t t t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 4.219.403 t t I 1 r r 1 I 7 being fed therein. Upon the introduction of the solid- rich layer into the ash accumulator, a high pressure hydrogen-rich gas or hydrogen is charged into the ash accumulator substantially at the existing pressure level in the reactor, and then the pressure in the accumulator 5 is adjusted to a level somewhat lower than the pressure in the reactor so as to allow the introduction of a solid- rich layer into an ash accumulator. i.e., by continuously bleeding a gas at a given rate therefrom. As a result, the interface between the solid-rich layer and the solid-lean 10 layer may be maintained at a given equilibrium level. The solid-rich layer introduced into the ash accumula- tor is flash-distilled and added to the slurry for reuse. In the ash accumulator system, two ash accumulators may be used in an alternate embodiment. 15 According to the fourth aspect of the present inven- tion, the interface between the solid-rich layer and the solid-lean laver is maintained in close vicinity to the open tip of a tube which is inserted in the reactor by withdrawing the solid-rich laver through the open tip of 20 a tube. thereby providing an equilibrium between the solid-rich layer and the solid-lean layer. The tube, as used herein, may be fixedly or movably inserted into the reactor, with the end thereof being connected via a pressure reducing valve to a slurry tank 25 or a solid-liquid separator, such as a liquid cyclone. In this case, as well, the volume ratio of the solid-lean layer to the solid-rich layer should preferably range from 1/6 to 2. If ash, catalyst and unreacted coal fines are separated 30 from the solid-rich layer, then the hydrogenation reac- tion efficiency decreases, and unreacted coal undergoes a coking reaction, thereby adversely affecting the yield of an intended product. Upon adjustment of the level of the interface between 35 the solid-rich layer and the solid-lean layer to a vicinity close to the open tip of the tube in the reactor, when a mixture of slurry and a high pressure hydrogen-rich gas is continuously introduced into the reactor, the solid- lean layer alone is withdrawn from the top of the reac- 40 tor. so that the interface between the two lavers ascends to the open tip of the tube. In this stage, the solid-rich laver is withdrawn through the tube in order to main- tain the interface between the two layers at an equilib- rium level which is close to the open tip of the tube. The 45 solid-rich layer thus withdrawn is flash-distilled as it is. and then added to the slurry for reuse as a catalyst. or otherwise separated into liquid and solids, while the liquid fraction is added to the solid-lean laver again, and the solid fraction is recovered so that it can be added to 50 the slurry for reuse. In this case, the solid-rich layer thus withdrawn is of low viscosity, thus facilitating the sepa- ration into liquid and solid phases. According to the fifth aspect of the present invention. the reaction mixture from the hydrogenation reactor is 55 introduced as it is, or via a gas-liquid separator. into a solid-liquid separator having a solid accumulator con- nected to the bottom thereof. In this respect. the reac- tion mixture contains a solvent or a light oil and is of a low viscosity because the reaction mixture is preheated. 60 thus providing ease of separation. In addition, a pres- sure-reducing valve is provided on the gas-liquid with- drawing pipe connected to the top of the solid-liquid separator. so that upon pressure reduction for flash distillation. solids will not pass through the pressure- t,5 reducing valve. thus avoiding errosion of the valve. This permits pressure reduction at a rapid rate. In this respect. part of the gas withdrawn from the solid-liquid 8 separator may be cooled for liquefaction for further distillation in a distilling column. When the solid-liquid separator is filled with solids. then a pressure-reducing valve on a gas-liquid withdrawing pipe is opened in order to reduce the pressure to atmospheric pressure instantaneously, for flash distillation. The cycle of oper. ation can be repeated for efficient solid-liquid separa- tion. BRIEF DESCRIPTION OF THE DRAWINGS FIG. I is a flow sheet illustrative of a prior art lique- faction process for coal fines. FIG. 2 is a diagrammatic view of a solid-liquid sepa- rating device within the scope of the present invention FIG 3 is a flow sheet illustrating a liquefaction pro- cess according to the present invention, which employs two solid-liquid separating devices: FIG. 4 is a flow sheet illustrative of one embodiment of the liquefaction process according to the present invention; FIG. S is a view illustrative of one embodiment of a reactor of the present invention; FIG. 6 is a view illustrative of another embodiment of the reactor of the present invention: FIG. 7 is still another embodiment of a reactor of the present invention: FIG. 8 is a flow sheet of the hydrogenation process of the present invention which employs the reactor of FIG. 7; FIG. 9 is a yet another embodiment of the reactor of the present invention; FIG. 10 is a flow sheet illustrative of one embodiment of the liquefaction process of the present invention which employs the reactor of FIG. 9; FIG. 11 is a diagrammatic view of another enibodi- ment of the solid-liquid separating device of the present invention: and FIG. 12 is a flow sheet illustrative of the liquefaction process of the present invention which employs two solid-liquid separating devices. DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 illustrates a prior art liquefaction process. Coal fines and a solvent such as a hydrocarbon having a boiling point of over about 150' C.. and a catalyst. if required. are slurried in a slurry tank; and then the slurry thus prepared is delivered by a slurry pump 2 to a preheater 3. Before the slurry is passed into the pre- heater it is mixed with a high pressure hydrogen-rich gas. The mixture of slurry and a hydrogen-rich gas. which have been preheated to about 300' to 500? C.. is introduced under pressure into a hydrogenation reactor 4 through its base for reaction at a temperature of about 300? to 500' C., and a pressure of about 50 to "00 arms. The reaction mixture from the reactor 4 is passed through separators 5.6 and 7 which are connected in series in the indicated order, and then pressure-reducing valves 8. 9. provided on pipes which connect the sepa- rators in series, are opened so as to reduce the pressure gradually for flash distillation of the slurry into solids and liquid The gas effluent withdrawn from the top of the first separator 5 is cooled for liquefaction. as desires. while a light oil fraction is distilled in a distilling l- umn A mixture of light and medium oils. and s, ivent withdrawn from the top% of separators 6 and 7 is .ii- tilled in a distilling column. and then the solvent tt-,u> recovered is recycled for use as a Murry term rc crl- B-255 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' 9 4,219,403 'est. Meanwhile, the heavy oil fraction withdrawn from the bottom of separator 7 contains a considerable amount of solids, which generally should be separated from the heavy oil. This is referred to as a de-ash opera- tion. In the first embodiment of the liquefaction process of the invention, as shown in FIGS. 2 and 3, a solid-liquid separating device 10 is positioned downstream of the reactor 4. so that the reaction mixture from the reactor 4 may be separated efficiently The solid-liquid separating device 10 consisting es- sentially of a liquid cyclone 11 which is a type of solid- liquid separator, and a solid accumulating tank 12 con- nected to the bottom of the cyclone 11. Connected to 10 terms of liquid cycline 11). while the liquid is with- drawn through outlet pipe 13 by overflow into reactor 21. The solids thus separated accumulate in solid- accumulating tank 12. When solid-accts ulating tank 12 is filled with solids, then stop valves 6' and 14 are opened. The stop valves 16 and 14 are closed. so that the introduction of the solid-liquid mtxt re is switched from the first separating device 10 to the second sepa- rating device 10'. for the separation of lids and liquid as well as for the accumulation of solid On the otner hand, the pressure reducing valve 17 oft the first separat- ing device 10 is opened to reduce the pressure inside to atmospheric pressure, and stop valve I is opened so that the solids which accumulate therein are withdrawn through outlet pipe 19. The solids thus thdraAn are delivered to slurry tank 1 for reuse en. all stop valves and pressure reducing valves in separating de- vice 10 are closed. When the second separating device 10' is filled to capacity with solids, then the introduction of the solid-liquid mixture is switched fr m the second separating device 10' to the first separa ing device 10 This cycle of operation can be repeated for a continuous operation. The liquid to be delivered to reactor 2 is introduced into reactor 21 which is maintained subs antiaily at the same temperature and pressure as that of reactor 4. wherein the liquid is subjected to treatment under non- catalytic conditions in the presence of a small amount of hydrogen which is fed into reactor 21 through gas inlet pipe 23. The treatment conditions deper. on the size of the apparatus. the quality of the desired liquefaction product, and the like. In order to prods e a heavy oil product which is well adapted for use as metallurgical carbonaceous material, preferably th temperature ranges from 400' to 500' C., a total pressure of from 70 to 150 atms in the presence of hydrogen f a low partial pressure, the hydrogen partial pressur is preferably from "r to 701% of the total pressure. and t e reason nme should be as long as that of the hydrogenation reaction. for instance. 5 to 90 minutes. With this treatment. a further lighter oil fraction or a reaction product having naphthenic or paraffinic-rich properties. whicn is pro- duced by the addition of an excessive am unt of hydro- gen. may be subjected to a dehydr geration cy- clopolycondensation reaction and con cried into a heavy oil fraction. which has the desired aromatic-rich property at an increased yield of I to 30 'c in compari- son to the amount of starting coals (tit. F or med,u:n abrasion furnace black). The liquid thus treated 's with- drawn through outlet pipe 24 which is connected to the top of reactor 21 and is delivered to th set arator for further processing. which is well known It :s apparent from the above discuss., n ccncerning the liquefaction process of the in%enti n. a reac;:cr. mixture devoid of solids is heat-treated i . the presence of hydrogen. which results in an improved vie:1 of a heavy oil fraction. while solids may be separated under low viscosity conditions at high temperature inc pres- sure. thereby providing improved ~,eoarai:nz efficiency and minimizing the ash content of the i utd procuct The liquefaction process achieved by tydrog_naticn the top of the liquid cyclone 11 is a gas-liquid outlet pipe 15 13. while a stop valve 14 is provided on pipe 13. A reaction mixture inlet pipe 15 is connected to the upper portion of liquid cyclone 11 at a position lower than the joint of the gas-liquid outlet pipe 13. while a stop valve 16 is also provided on pipe 15. In addition, a pressure 20 reducing valve 17 is connected to the upper portion of solid accumulating tank 12, while a solid outlet pipe 19, having a stop valve 18, is connected td 'a bottom portion of tank 12. In the liquefaction process of the invention, a non- 25 catalytic heat treating device is positioned downstream of the solid-liquid separating device to reform the lique- faction products, thereby improving the yield of the heavy oil fraction which is suitable for use as a metallur- gical carbonaceous material. In the first embodiment of the invention, as shown in FIG. 3, two or more solid-liquid separating devices 10 and 10' are provided directly or through a gas-liquid separator 20 downstream of the reactor 4. In FIG. 3 the primed reference numerals are used to distinguish the 35 second solid-liquid separating device and parts associ- ated therewith for common use with those of the first device from the first device. Gas-liquid outlet pipes 13 and 13', which are attached to solid-liquid separating devices 10 and 10'. are con- 40 nected to a gas-liquid inlet pipe 22, which is connected to the bottom portion of the non-catalytic heat treating device, or reactor 21. A high pressure, hydrogen rich. gas injection pipe 23 is connected to reactor 21. while an effluent outlet pipe 24 is attached to the top of reac- 45 tor 21. which leads in turn to separator S. In the operation of the apparatus for the liquefaction process of the present invention, as shown in FIGS. 2 and 3, the reaction mixture from the reactor 4 is passed through the gas-liquid separator 20 at a temperature of 50 about 300' to 500' C. and a pressure of about 50 to '00 arms. and then gas is withdrawn from the top of separa- tor 20. while a solid mixture is withdrawn from the bottom thereof. which is then introduced into the first solid-liquid separating device 10. The solid-liquid mix- 55 ture is subjected to a somewhat lower temperature and pressure than the reaction mixture prior to its introduc- tion into gs-liquid separator 20. All stop valves and pressure reducing valves in the solid-liquid separating devices 10 and 10', are maintained in their zlosed posi- tions at first. and then stop valve 16 on inlet pipe 15, which leads to the inlet of separating device 10. and stop vah e 14 on inlet pipe 15. which leads to separating device 10 are opened to allow the introduction of the in the present process includes: i : i a high degree of hydrogenation of ; a: ants :n 'he presence Jt htdroeen anti :atatst J 7 ac::. such as a .ai ilvst of the cohait-mri. DC?^:T tem. :ron ; r iron,uitur s.sieni at hi m^eratur: effluent from reactor 4 into device 10. The effluent is o5 separated :nto a liquid-rich phase this will be referred to simriy as a liquid), and a solid-rich phase The ;oiid- iieuia in:,.cure will be referred ::-) 4b a sot:d 'A hen .(std n t 1 1 1 I 11 t 1 r  I 1 t t f t t Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 (2) a relatively low degree of hydrogenation in the presence of an iron system catalyst or in the ab- sence of a catalyst in the presence of hydrogen; and (3) liquefaction at a high temperature and high pres- sure in a hydrogen donor solvent having aromatic characteristics such as anthracene oil, without or in the presence of a small amount of hydrogen. The term "hydrogenation reaction" is used herein in association with the above-described processes in- cluded in the present invention. FIG. 4 illustrates the second embodiment of the lique- faction process of the present invention. Coal fines, solvent and catalyst are slurried in slurry tank 101 and then the slurry thus prepared is delivered by slurry pump 102 to preheater 103. Prior to passage of the slurry into the preheater a highly reductive gas is mixed with the slurry. The mixture of slurry and high pressure reductive gas, which has been preheated to about 300' to 500' C., is fed under pressure into the first reactor 104 through its base, wherein the mixture is passed from the bottom to the top at a flow rate (preferably 10 to 400 m/hour) such that the solids in the reaction mixture may settle against the upward flow of the mixture for reaction at a temperature of about 300' to 500' C. and a pressure of about 50 to 700 arms. The reaction mixture effluent, which overflows the top of reactor 104 is intro- duced into the second reactor 104' through its base, and then the reaction mixture effluent, which overflows the top of reactor 104', is introduced into the third reactor 104" through its base. At this time, fresh catalyst from the catalyst accumulating tank 105 is slurried in a suit- able solvent and then the slurry is delivered by means of pumps 106. 106' and 106" to reactors 104, 104' and 104", respectively. The solids which settle in the various reactors are discharged through solid outlet portions 107, 107', and 107", positioned at the bases of the reac- tors. The reaction mixture effluent from the final reac- tor 104" is introduced into a gas-liquid separator 108, and then part of the gas effluent from the top of the gas-liquid separator 108 is cooled for liquefaction, while the liquid residuum is further distilled in a distilling column. The liquid effluent from the base of gas-liquid separator 108 (in this case, the liquid may contain some amount of solids) is subjected to flash distillation under a reduced pressure into gas, liquid, and solids, followed by further distillation. The solids obtained from the distillation contain unreacted coal fines, catalyst and the like, and may be used repeatedly. Fresh catalyst can also be combined with the recovered catalyst for reuse. In the reactor of the invention, the reaction mixture tends to separate into a solid-rich lower layer and a solid-lean upper layer. Accordingly, it is preferable that the flow velocity of the reaction mixture be adjusted by an appropriate means such as a tube which may be inserted into the reactor to withdraw the solid-rich laver, and that one or more solid accumulators having the same pressure as that of the reactor can be con- nected to the bottom of the reactor. Thus, gas is bled through the gas outlet pipes which are connected to the solid accumulators by opening the gas pressure and flow rate control valves provided on the gas outlet pipes. at a discharge rate which is commensurate with the rate a solid-rich liquid is introduced into the solid accumulators under pressure. so that an interface be- tween the solid-rich laver and the solid-lean laver may be maintained at a given level. 41n general. the volume ratio of the solid-lean layer to the solid rich laver should preferably be adjusted to 1/ o to 2 i In addition, the 12 solid-rich liquid and the solid-iean iuuid arc ~itndr3. through the open tip of the tube inserted into the reac- tor, so that the interface between the solid-rich laser and the solid-lean laver may be maintained in the vie in- 5 ity close to the open tip of the tube, thereby maintaining an equilibrium level within the reactor. The separation of the solid-rich layer and the solid-lean layer permits the desired dehydrogenation-cvclopolycondensatior. reaction to progress in the solid-lean layer, as has been 10 described earlier. thereby increasing the yield of a heavy oil fraction having aromatic property character - istics A description in greater detail of the reactor!. A i11 ;e presented. IS Referring to FIG. 5. reactor 110 is shown whose base is provided with an inlet port 113, which is adapted to introduce a mixture of a slurry and high pressure reduc- tive gas therein, and whose top portion is provided with an outlet port 114. which is adapted to withdraw the 20 solid-lean layer therethrough. Reactor 110 is connecter: via pipe 111 and valve 115 to a solid accumulator 112. The solid accumulator 112 has its top portion connected to a gas injection pipe 117 which is provided with a gas injection valve 116. and a gas outlet pipe 119. which is 25 provided with a gas pressure flow rate control valve 118. A solid outlet pipe 121 having a stop valve 120 thereon for withdrawing solids therethrough is con- nected to the base of accumulator 112. In the reactor shown in FIG. 5. pipe 111 branches into two pipes 30 which are connected to two solid accumulators 112 and 112', which are arranged in parallel with each other. In this respect, like parts in the second solid accumulator are designated with like primed reference numerals which are in common use with the corresponding parts 35 of the first solid accumulator. In operation of the reactor shown in FIG. 5. the solid accumulators 112 and 112' are isolated from communi- cation with the reactor by closing the valves 115 and 115', and the gas pressure flow rate control valves 118 40 and 118' as well as stop valves 120 and 120' are close.: for the first time. Then, a high pressure reductive gas is introduced through the gas injection velves 116 and 116' substantially at the same pressure as the pressure in reactor 110, after which injection valves 116 and 116' 45 are maintained in a closed position. A mixture of slurry and a high pressure reductive zas which has been preheated to about 300' to 500' C. is introduced through the inlet port 113 into reactor 110 at a slurry flow rate of I to 3600 m/hour. preferably IC'; to 50 400 m/hour. In this case, the reactor 110 is maintained at a temperature of about 300' to 500' C. and a pressure of about 50 to 700 arms. The mixture thus introduced under pressure is separated into a solid-lean laver A (this will be referred to as laver A) and a solid-rich lave- 55 B containing ash. catalyst. and unreacted coal fines in .i uniformly or thoroughly mixed condition. This wiii be referred to as a laver B.) In laver B. ash and catalyst are condensed and accumulate so that the li iuefaction reac- tion is promoted. On the other hand. in layer A. w nick b0 is heated in the presence of hydrogen at a cos partial pressure or a small amount of hydrogen almost under catalyst-free conditions, a light oil fraction or a react:on product. which possesses naphthenic or paraffinic-etch properties and which results from exce'sr'.e hydr; zcra- e5 tion, is subjected to a dehvdrogenar..on-cycioror?.c.-r.- densation reaction, thereby nemz zonyerte.] i:,i,- heavy oil fraction which has ar;'manic nroreru:..k *i:c- is best suited as a netatlur icaj .aroonac )u' ^:a::r:a. I B-257 Approved For Release 2007/02/20: CIA-RDP83M00914RO01000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018- 13 4,219,403 Layer A is continuously withdrawn through outlet port 114. while a mixture of a slurry and a high pressure reductive gas is fed under pressure through inlet port 113 into reactor 110, so that the interface between layer A and layer B ascends beyond the tip of the tube 111. At this stage, valve 11S is opened to bring the first solid accumulator 112 into communication with reactor 110. Since accumulator 112 and reactor 110 are main- tained substantially at the same pressure level, layer B is not introduced into the accumulator 112. Then, the gas pressure flow rate control valve 118 is opened, so that gas is discharged from the accumulator 112 at a rate proportional to the rate at which layer B is being intro- duced therein. (For instance, when the solids are pres- ent in the slurry in an amount of 25 to 40%, when the high-pressure-reductive-gas-feed rate is 14 to 30 Nm3/hour, when the feed rate of slurry is 50 to 100 kg/hour, when the volume of the reactor is 100 liters, when the reaction temperature is 400' to 450' C., and when the reaction pressure is 70 to 150 atms, the feed rate of layer B is 3 to 20 kg/hour.) As a result, layer B is introduced at a given flow rate into accumulator 112 so that the interface between layer A and layer B reaches an equilibrium at a given level with the result that the volume ratio of layer A to layer B may be maintained at 1/6 to 2, as shown in FIG. 5. The above ratio is well suited for hydrogenation in layer B and dehydrogenation-cyclopolycondensation in layer A. When a sufficient amount of layer B has been intro- duced into the solid accumulator 112, valve 115 is opened, valve 115 is closed, and the first accumulator 112 is shut off from the reactor 110, so that layer B may be introduced into the second accumulator 112. The layer B, which accumulates in the fast accumulator 112, is subjected to flash-distillation by opening valve 118, while residuum solids are discharged through valve 120, which is maintained in its open position. Subse- quently, accumulator 112 is pressurized to the same pressure level as that in reactor 110. This cycle of opera- tion is repeated by alternately using the accumulators 112 and 112'. Referring to FIG. 6, reactor 121 has a tube 122 which is inserted therein through its base and opens into the reactor through its open tip, in addition to an inlet por- tion 123 adapted to introduce a mixture of slurry and a high pressure reductive gas, and an outlet port 124 adapted to withdraw a solid-lean layer therethrough. In the operation of the reactor 121 shown in FIG. 6, a mixture of slurry and a high pressure reductive gas, which has been preheated to about 300' to 500' C. is introduced via inlet port 123 into the reactor 121, which is maintained at a temperature of about 300' to 500' C. and a pressure of about SO to 700 atms. The mixture thus introduced is separated into layer A (a solid-lean layer) and layer B. which includes ash, catalyst, unreacted coal fines and the like in a uniformly or thoroughly mixed condition, i.e., a solid-rich layer. In layer B, ash and catalysts are condensed and accumulate, thereby promoting the hydrogenation reaction. On the other hand. in layer A, as in the case of FIG. 5, the dehy- drogenation-cyclopolvcondensation reaction takes place, so that the product is convened into a heavy oil fraction. Laver A is continuously withdrawn through outlet port 123. while a mixture of slurry and a high pressure reductive gas is continuously fed through inlet port 123 under pressure so that the interface between the laver A and the layer B ascends. 14 On the other hand, the open tip of tube 12 position of 6/7 to 3 of the height of reactor the interface reaches the open tip of the to t is set at a 121. When 122, layer rough the of a mix- the slurry f the high when the when the e reaction e reaction f laver B, .s a result, inity close ie ratio of nge of 1/6 B (as well as the layer A) is withdrawn t open tip at a rate proportional to a feed rat ture. (For instance, when the solid content o is 25 to 40% by weight, when the feed rate pressure reductive gas is 14 to 30 Nm3/hour feed rate of the slurry is 50 to 100 kg/hour volume of the reactor is 100 liters, when t temperature is 400' to 450' C. and when t pressure is 70 to 150 aims, then the rate which is withdrawn, is 3 to 20 kg/hour.). the interface reaches an equilibrium in the vi to the open tip of tube 122, so that the volu layer A to layer B may be maintained in the r to 2. (See FIG. 6) tube 122 is flash-distilled into solid and liqui acted coal fines, catalysts, and the like. As is apparent from the above description, reactors is reduced, while the flow velocity tion mixture within the reactor is lowered, vides the same advantages as those of a pisto reactor. Attention will now be turned to the thi and S. A hydrogenation reactor 210 is equip other end of the tube. adapted to introduce a mixture of a slurry pressure hydrogen-rich gas, and an outle reactor 210 is connected via a pipe 212 and v equipped with a gas injection valve 216. an charge pipe 219 equipped with a gas pressur control valve 218 are connected to the top accumulator 212, while a solid withdrawin bottom portion of the ash accumulator 212. two lines which are connected to two ash ac 212 and 212', which are arranged in parallel bottom of fractions. rain unre- he diame- number of f the reac- td the set- actor pro- flow type i embodi- o FIGS. 7 d with an d therein. 212 at the port 213 nd a high port 214 top. The lye 215 to pipe 217 a gas dis- flow rate of the ash pipe 221 ed to the n the em- ched into umulators with each other, respectively. As in the previous embodiment, like parts in the second ash accumulator are designated by like primed reference numerals, which are us d in com- mon with those of the first ash accumulator 212. As shown in FIG. 8, a pipe 213 leading from pre- heater 203 is connected to reactor 210 andithe outlet port of reactor 210 is connected to a separator 205 via the ash accumulators 212 and 212', while 201. accumulators 212 and 212' are isolated from pressure hydrogen-rich gas is introduced t as supply d 217' for olid-with- lurry tank tus of the 8. the ash eactor 210 s pressure top valves yen. a high rough gas t t t 1 R I Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t t 1 I t t I 1 I -1.219,403 15 16 iniection .gives 216 and 216 into ash accumulators 212 Lion reaction, while the dehydrogenation- and 212' in order to bung the pressures therein to the cyclopolycondensation reaction is promoted in the soi- level of the pressure in reactor 210. after which the id-lean laver so that the yield of the heavy oil fraction. injection valves 216 and 216' are maintained closed. suitable for use as a metallurgical carbonaceous mate- A mixture of slurry and a high pressure hydrogen- 5 rial, is increased. In addition, solids may be separated in rich gas. which have been preheated to about 300' to the reactor so that the ash content of the mixture mas be 500' C. is introduced at a slurry flow rate of I to 3600 reduced and the catalyst may be reused, which provides m/sec. preferably 10 to 400 m /sec. into reactor 210 a considerable economic advantage as well as avoiding which is maintained at a temperature of about 300? to the public nuisance problem of the disposal of the cata- 500' C. and a pressure of about 50 to 700 atms The 10 lyst wastes. The conditions of the operation are the mixture thus introduced under pressure is separated into same as those of the preceding embodiment. i.e . the a solid-lean layer A and a solid-rich laver B containing withdrawal rate of laver B should preferably he in the ash, catalyst, and unreacted coal fines in a uniformly ranee of 3 to 20 kg under the same conditions as those mixed condition. A hydrogenation reaction is promoted of the preceding embodiment. in layer B because ash and catalyst are condensed and 1! The fourth embodiment of the liquefaction process of accumulate therein. In layer A. the mixture is heated in the present invention will be described with reference the presence of hydrogen at a low partial pressure or a to FIGS. 9 and 10. small amount of hydrogen almost under catalyst-free FIG. 9 shows a reactor 310 of the present invention conditions, so that a light oil or part of a product which The reactor 310 is provided with tube 311 which is possesses naphthenic or paraffinic-nch properties, be- -0 inserted through the base of the reactor with its open tic cause of the addition of an excessive amount of hydro- positioned therein. The reactor 310 further is provided gen is converted into a heavy oil fraction which has with an inlet portion 312 in its base which is adapted to aromatic properties and is therefore suitable as a metal- introduce a mixture of a slurry and a high pressure lugrical carbonaceous material, as prepared from the dehydrogenation-cyclopolycondensation reaction. 25 hydrogen-rich gas, as well as an outlet port 313 at the Layer A is withdrawn through outlet port 214 into top which is used to withdraw a solid-lean laver there- separator 205, while a mixture of the slurry and a high from. As shown in FIG. 10, a pipe leading from pre- pressure hydrogen-rich gas is continuously fed through heater 303 is connected to inlet port 312 of reactor 310. inlet port 213 into the reactor, so that the interface while outlet port 313 is connected to separator 305. The between layer A and layer B ascends beyond the open 30 lower end of tube 311 is connected to solid-liquid sepa- tip of tube 211. In this stage. valve 215 is opened in rator 314. order to bring the first ash accumulator 212 into com- In the operation of the liquefaction apparatus of the munication with reactor 210. Accumulator 212 and present invention, a mixture of a slurry and a high pres- reactor 210 are maintained almost at the same pressure sure hydrogen-rich gas, which has been preheated to a level so that layer B is not fed into accumulator 212. 35 temperature of about 300' to 500' C. is introduced at a Then, the gas pressure flow-rate control valve 218 is slurry flow rate of I to 3600 m/hour, preferably 10 to opened so that gas may be discharged from accumulator 400 m/hour through inlet port 312 into reactor 310. 212 at a rate proportional to the feed rate of laver B. which is maintained at a temperature of about 300' to Layer B is fed into accumulator 212 at a given feed rate 500' C. and a pressure of about 50 to 700 arms. The so that the interface between layer A and layer B 40 mixture thus introduced under pressure into reactor 310 reaches a given equilibrium level above the open tip of is separated into a solid-lean layer A and a solid-nch tube 211, with the result that the volume ratio of layer layer B including ash, catalyst, and unreacted coal fines A to layer B may be maintained over a range of 1/6 to in a uniformly or thoroughly mixed condition. In layer 2. (FIG. 7) The above ratios are well suited for the B. since ash and the catalyst settle and accumulate, the hydrogenation reaction in layer B, and the dehy- 45 hydrogenation reaction may be promoted in the reac- drogenation-cyclopolycondensation reaction in laver tor. Laver A is heated in the presence of hydrogen at a A. low partial pressure or a small amount of hydrogen. Valve 215' is opened when layer B is introduced into almost in a catalyst-free condition, and a light oil or a ash accumulator 212 in a sufficient amount. Thereafter, portion of the reaction product which has achieved a valve 215 is closed so that the first accumulator 212 is 50 naphthenic or paraffinic-rich property by the addition isolated from reactor 210, thereby introducing layer B of an excessive amount of hydrogen is subjected to a into the second accumulator 212'. in the same manner as dehydrogenation-cyc!opolycondensation reaction so that of the first accumulator. The pressure reducing that the reaction product is converted into a heavy oil valve 218 is opened and the mixture is flash-distilled of an aromatic-rich property. and is therefore well from the First accumulator 212. After the pressure in the 55 suited as a metallurgical carbonaceous material. thereby accumulator 212 has been returned to atmospheric pres- improving the yield of the heavy oil product. sure. stop valve 220 is opened so that solids are with- Layer A is withdrawn through outlet line 313 into drawn through the solid withdrawing or outlet pipe 221 separator 305. while a mixture of a slurry and a high and fed to slurry tank 201 for reuse. Subsequently, accu- pressure hydrogen-nch gas is continuously introduced mulator 212 is pressurized to the same pressure level as 0 through inlet port 312 so that the interface between that in reactor 210. The above cycle of operation is laver A and laver B ascends. repeated for the alternate use of accumulators 212 and On the other hand, the open tip of the tube 311 is set 212'. to a height of b/' to J of the height of reactor 310 As is apparent from the above-described liquefaction When the interface between the two layers reaches the process )f :he present invention. a mixture is separated e' open tip of the tube in reactor 310. layer B is withdraw ti tnt; a ,o!id-lean !aver and a solid-rich layer for different through the open tip at a rare which is zommensurate rtes ,f reactions, so :hat ash anu . awty,t contents may with :he fend rate )f the mixture Al a re,wt. the rte' 7e to settle :n order to promote the h%ar,oeena- "ate i, maintained :n ?he ?.:c:nit' ; t,,,e t,, the 'reel ':r" B-259 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' 17 4,219,403 18 tube 311 at all times, so that the volume ratio of layer A the introduction of the solid-liquid mixture from the to layer B may be maintained from 1/6 to 2. (FiG. 9) first solid-liquid separating device 410 to the second The layer B thus withdrawn is separated into solid solid-liquid separating device 410'. for the separation of and liquid fractions in solid-liquid separator 314, while solid and liquid and the accumulation of solids. the solids are delivered for reuse to slurry tank 1, and the S other hand, after the switching operation, the pressure liquid fraction is fed to separator 305 for further pro- reducing valve 414 is opened while the stop vale 417 cessing by conventional prior are procedures. and 415 are closed so as to isolate the aforesaid sol d-liq- The advantages and conditions of withdrawal of uid separating device from the other system in order layer B are the same as those in the preceding embodi- that the pressure in the device may be reduced to tmo- ment. 10 spheric pressure instantaneously for flash-distil aeon, The fifth embodiment of the liquefaction apparatus of thereby separating the same into gas-liquid and lids. the invention will be described with reference to FIGS. The gas and liquid are withdrawn through the g s-liq- 11 and 12. uid outlet pipe 413 and line 421. The solids whit con- As shown in FIG. 11, a solid-liquid separating device dense are withdrawn through the solid outlet po 418 410 is positioned downstream of reactor 404, thereby 15 in the base of the solid accumulating tank by o ning efficiently separating solids from the reaction mixture stop valve 419. When the first solid-liquid sepa acing which is introduced from reactor 404. The solid-liquid device 410 becomes empty and the second solid liquid separating device 410 consists essentially of a liquid separating device 410' is filled with solids, the int oduc- cyclone 411 which is one type of a solid-liquid separa- tion of the solid-liquid mixture is switched from the tor, and a solid accumulator 412, which is connected to 20 second solid-liquid separating device 410' to th first the bottom portion of cyclone 411. A gas-liquid with- solid-liquid separating device 410. Likewise, flash istil- drawing or outlet pipe 413 is connected to the top por- lation is conducted therein for separation of the mixture tion of liquid cyclone 411, and a pressure reducing into gas, liquid and solids. In this manner, two solid-liq- valve 414 is provided on a branch line of pipe 413, while uid separating devices are used alternately fora effi- a stop valve 415 is provided in another branch line of 25 cient operation by a so-called batch system operation. pipe 413. A reaction mixture inlet pipe 416 is connected The gas and liquid effluents withdrawn through lines to the top portion of liquid cyclone 411 at a position 421 and 421' pass through a condensor, as requited, so lower than the point of juncture of the gas-liquid with- that a portion of the gas may be cooled and liq efied. drawing pipe 413 with cyclone 411. A stop valve 417 is The liquid is further distilled in a distilling colts in. On provided on pipe 416. In addition, a stop valve 419 is 30 the other hand, the liquid effluent withdrawn t rough provided at the solid outlet port 418 at the base of solid- lines 422 and 422' is further distilled in a distil W g col- accumulating tank 411 umn so that the solvent which is recovered is ret sed as Two or more solid-liquid separating devices 410 and a slurry solvent. The gas product withdrawn from the 410' are provided as shown in FIG. 12, directly or via a top portion of the gas-liquid separator 420 is cool and gas-liquid separator 420 downstream of the reactor 404. 35 liquefied in a condensor as required. (Two solid-liquid separating devices 410 and 410' are As is apparent from the foregoing discussion, a lique- provided in FIG. 12.) Like parts in the second solid-liq- feed reaction product may be separated into solids and uid separating device in FIG. 12 are designated with liquid under considerably low viscosity conditions like primed reference numerals for common use with thereby dispensing with the prior art necessity of add- the corresponding parts of the first solid-liquid separat- 40 ing a light oil to the liquid to lower the vi osity ins device 410. The operation of the apparatus of the thereof, thus allowing for the separation and rem val of present invention for separating and removing solids solids in an efficient manner with the accomp ying from a liquified reaction product will be described with improvement in quality. In addition, the size of a appa- reference to FIG. 12. A mixture from the top of reactor ratus may be reduced to a considerable extent i com- 404, which is maintained at a temperature of about 300' 45 parison to the size of the prior art apparatus thus hiev- to 500' C. and a pressure of about 50 to 700 arms, is ing the desired saving in equipment investmen . Fur- passed through the gas-liquid separator 420 so that gas thermore, upon flash distillation. by reduction o pres- may be withdrawn from the top of the separator 420, sure in the system, solids do not pass through the pres- while a solid-liquid mixture is introduced into the first sure reducing valves, thus preventing valve corrosion solid-liquid separating device 410 through its base. The 50 problems. This further permits the reduction f the solid-liquid mixture introduced into the solid-liquid pressure to atmospheric pressure instantan ously, separating device is somewhat low in temperature and thereby avoiding the need to provide many sepa ators. pressure in comparison to the temperature and pressure Still furthermore. in the de-ashing operation of the pnor of the reaction mixture prior to introduction into a gas- art, heat is needed to lower the viscosity or the mixture' liquid separator. When a solid-liquid mixture is intro- 55 while the apparatus according to the present inv~enuon duced into the solid-liquid separating device 410, the requires no such heating, thus saving energy. stop valve 417 on the inlet pipe 416 is opened. while the Having now fully described the invention. it will be stop valve 417' on the inlet pipe 416' to the second apparent to one of ordinary skill in the art that; many solid-liquid separator 416' is closed. changes and modifications can be made thereto ~~yy~ ithout The solid-liquid mixture thus introduced is separated 60 departing from the spirit or scope of the invent;odi as set into a solid-lean phase and a solid-nch phase in the forth herein. liquid cyclone 411. The liquid overflows through the What is claimed as new and intended to be secured by gas-liquid withdrawing pipe 413, while stop valve 415, Letters Patent is: pressure reducing valve 414 and stop wive 419 are 1. A coal liquefaction process which camp s: closed. The solids accumulate in the solid accumulating 65 admixing coal fines with a hydrocarbon solvent hav- tank 412. When the solids have accumulated in the solid ing a boiling point greater than 150' C. to orm a accumulating tank 412, the stop valve 417 is dosed, coal slurry: while the stop valve 417' is opened in order to itch admixing with said coal slt:rr% a hvdr!,ern-n. 'n _as. 1 i 1 t Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-01  i s t t 11 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 4,219,403 19 hydrogenating said coal slurry by heating said hydro- gen-containing admixture at a temperature of from 300' to 500' C. and a pressure of from 50 to 700 atms whereby said coal fines are liquified and a solid-liquid admixture is formed; separating said liquid-solid admixture into liquid and solid fractions; and dehydrogenating and cyclopolycondensing said liq- uid fraction at a temperature of from 400' to 500' C. and a total pressure of 70-150 atms in the pres- ence of hydrogen at a low partial pressure wherein 20 introducing said coal slurry-gas mixture into the lower portion of a reactor at an upward flow rate such that a solid rich layer is formed in the lower portion of said reactor and a solid lean layer is formed in the upper portion of said reactor; maintaining said reactor at a temperature of from 300' to 500' C. and at a pressure of from 50 to 700 atms whereby said coal slurry is hydrogenated in said solid rich-layer and the resulting liquid reac- tion product is dehydrogenated and cyclopolycon- densed in said solid lean layer; and withdrawing a portion of said solid lean layer to thereby recover a heavy oil product. 7. The process of claim 6, wherein the volume ra::c o; said solid lean layer to said solid rich layer is from 1.6 to 2:1. 8. The process of claim 6, wherein said coal slurry contains a hydrogenation catalyst. 9. The method of claim S. wherein said solid lean layer is essentially free of said hydrogenanon catalyst. 10. The process of claim 6, wherein a portion of said solid rich layer is withdrawn; the solid and liquid com- ponents of said layer separated; and the solid compo- nents admixed with said coal slurry. 11. The process of claim 6, wherein said upward flow rate is from 1 to 3,600 m/hour. 12. The process of claim 11, wherein said upward flow rate is from 10 to 400m/hour. . . * S said low partial pressure of hydrogen is in the range of 7 to 70% of said total pressure, to produce an aromatic-rich heavy oil product. 15 2. The process of claim 1, wherein said coal slurry is hydrogenated in the presence of a hydrogenation cata- lyst. 3. The process of claim 2, wherein said hydrogena- tion catalyst comprises cobalt and molybdenum. 20 4. The process of claim 2, wherein said hydrogena- tion catalyst comprises iron. S. The process of claim 4, wherein said hydrogena- tion catalyst comprises iron and sulfur. 6. A coal liquefaction process which comprises: 25 admixing coal fines with a hydrocarbon solvent hav- ing a boiling point greater than 150' C. to form a coal slurry; admixing with said coal slurry a hydrogen-rich gas; 30  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' JAPANESE COAL LIQUEFACTION TECHNOLOGY 31. Mitsui Engineering and Shipbuilding Direct Coal Liquefaction Process Process Description This process, which is being developed by the Mitsui Engineering and Shipbuilding, Co., a Mitsui Group Company, is based on the direct hydr gen a- tion process flow diagram for their newly constructed 2.4 ton/day proc ss development unit. The key operation steps that are different from other processes include the following: (1) preheated coal slurry/H2 gas str am containing disposable FeS catalyst is introduced into the tubular liquefaction reactor where additional quantities of H2 gas are injected at different stages in the reactor system at about 750? to 930?F and 2840 to 4270 psia, (2 the slurry phase in the high-pressure separator is separated into solids (unreacted coal, catalyst, ash, etc.) and oil by means of a centrifuge or a hydroclone system, (3) oil thus separated is fractionated into naphtha light oil, heavy oil, and bottoms via the atmospheric and vacuum towers, and 4) single stage operation. Although this development is somewhat different than the original IG Farben process it closely parallels research in West Germany to modify the original IG Farben process. The direct hydrogenation process for coal liquefaction is the third of the three major processes under the Japanese Sunshine project. The design of the process emphasizes improving the rates of coal liquefaction reaction to achieve high liquid hourly space velocities (LHSV) (i.e., of at least bout 10). The design feature to increase both the mass transfer and chemic 1 reaction rates consist of (a) the use of the tubular reactor to obtain turbulent flow, (b) promotion of the "bubble flow" mode, (c) maintenan a of high hydrogen concentration in the process stream by use of multistage injection of fresh and recycle hydrogen streams into the reactor syste#n, and (d) application of high reaction temperature (400-500?C or 750-930?F) and pressure (19.6-29.4 MPa or 2840-4270 psia). Another feature of the process is use of the disposable FeS catalyst. y 1 1 t  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t 1 1 1 t t Relationship to Prior Technology The Mitsui process is based on the IG Farben Process and has been further refined by the government industry development laboratory, Hokkaido, in Sapporo City. The laboratory became the first Japanese institution to have completed a "continuous" test facility back in March 1979. It is still being run to seek the optimal reaction conditions for the direct liquefaction opera- tion at the temperature range of 400 to 450?C and pressure ranging from 200 to 700 atm. The bench-scale one- and five-liter reactors are utilized in a six-- week cycle: one week for test preparation, two weeks for continuous run, one week for waste disposal, and the last two weeks for analysis of coal liquids. The Sapporo, Hokkaido, laboratory is confident that the direct liquefac- tion route will eventually prove the most reasonable and practical technology largely because of its simplicity. This confidence stems partly from the technical know-how accumulated over the past 16 years. The lab's basic work, aimed at utilizing the northern-most island's coal resources, started in 1965. While still providing technology to the Mitsui engineering group, the laboratory is about to launch its study to pursue the so-called coal chemistry - an avenue of research intended to make best use of coal liquids for production of chemicals. The 0.1 tonne/day bench-scale unit is continuing its operation to conduct the support R&D for the process development unit. Main subject areas of studies include (a) evaluation of PDU operating conditions, (b) investigation of liquefaction characteristics of different coal types, and (c) determination of properties and material balance of the recycle solvent. Basic studies conducted by Hokkaido and Yamagata Universities, Asahi Chemical Industry Company, Hitachi Ltd., Japan Steel Works, and the National Chemical Laboratory for Industry are (a) catalyst development, (b) recovery systems for slurry feed and power, (c) reactor materials, and (d) coal pretreatment methods. Operating Facilities A 2.4 metric ton/day facility has been completed at the Nippon Kokan Kawasaki shipyard. This direct coal liquefaction PDU was completed at a cost of $19 million. I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' Major Funding Agency This process is one of four coal liquefaction efforts which is being funded by the Japanese New Energy Development Organization (NEDO). This pro- cess will compete for funding with the Sumitomo and Mitsubishi efforts or funding which will probably be used to construct one 500 metric ton/day demonstration facility in the 1985-86 timeframe. The Mitsui headed gro developing this direct coal liquefaction process consists of the Mitsui Engineering and Shipbuilding Co., Nippon Kokan, Asahi Chemical Industry Co., Hitachi Ltd., and the government controlled Electric Power Development o. Capital Costs Capital costs for a commercial size facility have not been publish d. However, this process should be similar in cost to those being develope in West Germany which are based on the IG Farben process. Technical Problems No major technical problems have been reported. 11 1-1 1 J 1 i I N S T I T U T E O F G A S T E C H N O L G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-  1 1 I I t. Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 Lc% t 6 ;O > p O 0 7 W O O ~ C Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 JAPANESE COAL CONVERSION PROCESS 32. Sumitomo Solvent Extraction Coal Liquefaction Process Process Description Because of the limited amount of published information and the lack of pilot plant data, little is known of the Sumitomo coal liquefaction process. A rough process flow diagram is presented in Figure 1. As shown, coal is dehydrated and pulverized before being mixed with a hydrogen-donating solvent (tetralin) in the ratio of 2 to 5 times the coal volume to solvent.24 The slurry is then mixed and heated before entering the high-pressure, high-tem- perature liquefaction reactor. The liquefaction reactions occur at 400 to 450?C and 100 to 150 atmospheres. The lighter products are cooled and subse- quently separated into gaseous and liquid streams. The bottoms from the high pressure and high temperature liquefaction reaction are sent to a solid/liquid separator where solid solvent treated coal is produced. The liquids produced in this separator tower are cooled and sent to a distillation tower. During cooling, the heavier liquid products are collected; lighter liquids and spent solvent are separated in the distillation tower. The liquids product yield is reported to be 3.3 bbls/ton of coal.26 The spent solvent is further cooled before being sent to storage. The lighter oils are also cooled and separated before being sent to storage. The spent solvent (naphthalene) is then converted back to the hydrogen donating solvent tetralin. This is accomplished by heating and mixing hydro- gen gas with the naphthalene prior to entering a series of reactor towers where the actual transformation occurs. The resulting donor solvent tetralin is then sent to storage for reuse. The key to the process is the availability of hydrogen for the solvent reclaiming step. Although some hydrogen is reclaimed from the process, most hydrogen requirements must come from an external source. For this purpose SMI has developed a molten iron bath coal gasification process to generate the necessary hydrogen. In the combined coal liquefaction/coal gasification mode, the hard-to- liquefy portion of the incoming coal is separated and fed to the molten iron coal gasification reactor for the production of hydrogen. The primary design feedstock choice for the liquefaction process is subbituminous coal. With r 1 1 r  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 R t 1 1 A I r Y C 0 lion - PC - N7c- O N a 0 u N I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20 - C;IA-RnPR:IM00g14Rnn1nnnnEnn1R-n  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 this combined process and feedstock the overall process efficiency is claimed as less than 60%.21 A technology fact sheet for the this process is presented in Table 1. In 1970 the Sumitomo Coal Mining Co., Ltd, (SCM) a member of the Sumitomo Group, started research in the area of coal liquefaction in anticipation of an era of increased coal utilization. In 1976 SCM constructed a continuous operation 3 metric ton/day solvent refined coal liquefaction pilot plant at a coal mine near Akahera in central Hokkaido. This pilot plant produced a low ash, sulfur, and melting point solid product. In the process, a mixture of pulverized coal and hydrogen doner coal-derived solvent were heated to 400?C under high pressure. The pilot plant achieved more than 100 hrs of continuous operation in 1978.2,3 In 1975 another Sumitomo Group member, Sumitomo Metal Industries, Ltd. (SMI) of Osaka, initiated research on ways of converting steam coal to binder pitch for metallurgical coke production. This investigation was prompted by a shortage of metallurgical coal in Japan at that time. Because of SCM's experience in coal conversion technology, SCM joined SMI in studying binder .pitch production. This effort was soon curtailed by a decline in steel production which lessened the need for metallurgical coke. In 1978 this change in direction was illustrated by the support given by the Ministry of International Trade and Industry (MITI) to SMI and SCM for the development of the coal liquefaction technology. As part of the Sunshine Program this project has received full funding by MITI. As an aside to coal liquefaction research, SMI has developed a ferrous bath coal gasification process. This gasification process was developed to help the steel industry toward an "oilless steel plant" capability.5 In addi- tion, the ferrous bath gasification can also be used to produce hydrogen for the coal liquefaction process. Relationship to Prior Technology The Sumitomo liquefaction process is an extension of research conducted in the mid 70's for the production of binder pitch. This process is similar to the Exxon Donor Solvent process developed in the U.S. 1 t 1 I r  1 I 1 t t 1 t Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 D+ U s~ NU Approved For Release 2007/02/20: CIA-RDP8  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 t t r B-270 G A S 1  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 1 1 1 I 1 Operating Facilities With experience gained from SCI's binder pitch research and SCM's solvent refined coal solid production investigation,3 SCM and SMI constructed a 1 metric ton/day pilot plant at the Hasaki Research Center in Ibaraki Prefecture. This pilot plant, which produces a heavy, medium and lightweight liquefied coal, started preliminary operation in February of 1980. Full operation of the pilot plant began in March of 1981.4 Major Funding Agencies Funding for this process comes from the Japanese Ministry of Interna- tional Trade and Industry (MITI). A discussion on the continuation of this process will be made by MITI and the New Energy Development Organization (NEDO) in mid 1982. Technical Problems The Sumitomo coal liquefaction process is currently in the pilot plant stage of development. Due to the lack of available data and operating experi- ence critical problems for this process have yet to surface. But because this process is similar to other coal liquefaction processes - in particular the SRC and EDS process - parallel problems might be expected to occur. In the SRC process corrosion/erosion problems occur in four main process areas that are similar to those found in the Sumitomo liquefaction process. These areas include coal receiving and preparation, preheating and dissolving, filtration and mineral residue drying, and solvent recovery. In the area of coal receiving and preparation typical problems associated with similar facilities occurred in coal slurry centrifugal pumping equipment and high-pressure, plunger-type slurry preheater charge pumps. These problems centered on packings and seal leakage, as well as check valves and plunger erosion. In the preheating and dissolving sections a few material problems developed. These minor problems involve nozzle sleeve lining corrosion and scale formation. But severe stress corrosion cracking of Type 304 stainless- steel lining occured in the high- and intermediate-pressure separator equipment. This stress corrosion cracking was attributed to polythionic acid and chloride stress corrosion cracking at weld sites. Corrosion was not experienced in any of the other materials in the separators, including carbon steel.  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C' Corrosion/erosion material problems also occurred in the filtration and mineral residue drying areas. Most problems occurred in the heat excharger material where severe erosion of metal tubes was encountered as well as tube bulging due to carburization in the 3/8 inch thick 304 SS drying shell. Severe corrosion/erosion problems have also occurred in the reboil rs, air coolers, fractionation equipment, piping, and tower walls of the so vent recovery section of the SRC process. These problems have caused severs major shutdowns. The most severe corrosion occurred in moving parts and materials that came in direct contact with liquid solvent. Most of the problems required a change in material specifications to alleviate the situation. However, acceptable corrosion rates have yet to be achieved in areas such as the stainless-steel trays used in the separator towers. For the most part, the problems discussed above are applicable to most coal liquefaction processes and not just the SRC processes or the Sumitomo liquefaction processes. For this reason these generic problems will probably not hinder any one process toward commercial development. Capital Costs The investment cost of the Sumitomo coal liquefaction process developed by Sumitomo Coal Mining Co. Ltd. and Sumitomo Metals INd., Ltd. has no been published. However, based on a process flow sheet comparison with oth r coal liquefaction processes, the Sumitomo process does not differ significantly from the EDS (Exxon Donor Solvent) process which is being developed by the Exxon Research and Engineering Co. in the U.S. (see Figures 2 and 3.29 Based on this comparison, the two processes should have similar capital cost requirements. The total plant investment costs for the EDS process (i 1975 dollars) are shown in Table 2.30 These costs include engineering, lad, plant, and G&A costs. Coal gasification facilities for hydrogen prod ction have been substituted for the naptha reformers of the 1975 EDS design. Also included is a 20% contigency factor based on the state of the technol gy readiness. All costs are based on a facility that uses 25,000 tons/d y of coal and produces 60,000 barrels/day of liquid products. r I N s AT p~o\tTed oT Release 20 7702/20: C~A-IRDSP83M00914R001000060018-0 G Y  f r 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 T SLUMP, RCTCL( SOLVENT FIL'.AYE a(CVCL( SCLV(N! r- FULL GAS MR N-0.YNT USE U K? CTI.L Figure 2. EDS CONCEPTUAL BLOCK FLOW DIAGRAM t r 1 L= wMTw WTILLAT.71 L~LM( 015 /LL.T( KIiM C157LL.f( Figure 3. SUMITOMO LIQUEFACTION PROCESS CONCEPTUAL BLOCK FLOW DIAGRAM  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C Table 2. TOTAL PLANT INVESTMENT FOR 25,000 TON/DAY LIQUEFACTION FACILITY Offsites (including coal preparation, handling, product tankage, loading, utilities) Liquefaction Facilities Solvent Hydrogenation Hydrogen Recovery and Gasification Gas and Water Treating Total (including 20% contingency) Analysis Cost Basis: $2.7 billion (1980) 1975 Dollars 1980 Dollars (millions) (millions) 300 660 300 660 100 220 450 1000 60 130 Coal Feed: 25,000 tons/day @ 12,500 Btu/lb (including 2500 tons/day for make-up hydrogen required in addition to 7500 tons/day coal residue) 1 1 r 1 Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0 I A I 1 JAPANESE COAL GASIFICATION PROCESS 33. Sumitomo Molten Iron Coal Gasification Process Process Description The Sumitomo process consists of four main systems: coal preparation, coal injection, molten iron gasification, and gas cleanup. Coal is initially sized 20 to 50 mm for storage. From storage the coal is sent to a hot-gas- swept pulverizer where the coal is sized 70% to 80% through 200 mesh and sim- ultaneously dried to 5% to 15% moisture. The dried, pulverized coal is then sent to storage before injection into the gasifier. One of the most important elements of this process is the coal injection system. This system consists of a specially designed lance that injects coal, steam, and oxygen simultaneously into the molten iron bath. Unlike other sub- merged lance designs, this non submerged top-blowing lance utilizes a ultra high speed blowing technique to form a cavity in the molten slag as shown in Figure 1. As the feed is injected into the gasifier a 2000?C flame is generated, and the coal injected at the molten iron surface is cracked in a matter of seconds by the extremely high temperatures. The molten bath assures complete conversion of the reactants while absorbing unwanted elements such as ash and sulfur. The molten ash that forms on the surface of the molten iron bath is skimmed off and withdrawn in the molten state. Part of the slag is composed of CaS, which is formed when the sulfur in the coal reacts with CaO that is added to the molten bath to promote desulfurization. From the literature it is unclear whether the CaO is injected with the pulverized coal or added in a separate manner. The molten iron bath also acts as a buffer when excess coal is dissolved in the bath as carbon. This helps to maintain a steady gas com- position. The possibility also exists to inject scrap metal or iron ore into the bath instead of steam. The steam, which acts as a heat moderator, can there- fore be replaced to allow hot metal production as well as synthesis gas pro- duction. A typical synthesis gas composition for steam or scrap injection is presented in Table 1. The pilot plant gasifier has a fire brick lining which contains the 1500? to 1600?C molten iron bath. This pilot plant gasifier has a maximum inner B-275 I N S T I T U T E O F G A S T E C H N O L O G Y Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-0  Approved For Release 2007/02/20: CIA-RDP83M00914R001000060018-C Injection of Steam Use of Scrap Generated Gas 2150-2220 Nm3/T - Coal 20002050 Nm3/T - Co CO 60 - 64% 64 - 68% C02