Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Next 2 Page(s) In Document Denied Iq Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 Translation from Serbo-Croatian. Elektrotechnika, vol.8,No.1,1959,p.85-.93. PRODUCTION OF OXYGEN-FREE COPPER FOR THE ELECTRICAL INDUSTRY IN YUGOSLAVIA. Dragoslav Janicijevic, Chief Metallurgist, Fabrika Kablova Svetozarevo, Svetozarevo, Yugoslavia. SUMMARY During the past two decades, electric furnaces have increasingly replaced conventional reverberatory furnaces for copper melting. Two types of electric furnaces are used, arc furnaces and low frequency induction furnaces. The latter type, in conjunction with a special casting process, under exclusion of air, is used today to produce copper wire bars of superior quality which is known on the world market as oxygen- free copper of high conductivity. A plant for production of this type of copper, the third in the world, started operation in June 1955 at the Fabrika Kablova Svetozarevo. The present paper briefly describes the quality of oxygen-free copper, the history of the special process, and the production methods and equipment used at the Fabrika Kablova. Finally, some idea is given of actual operations and product controls. Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 INTRODUCTION.. Yugoslavia was known as a source of cathode copper of good quality even before the construction of the Fabrika Kablova "Mosa Pijade" at Svetozarevo and of the Copper and Brass Mill at Sevojna. The installation of these two large plants, in addition of the few older copper producers, has meant a transformation in the copper industry of the country. The copper processed in 1957 was 76.5% of the entire Yugo- slavian copper output, 41.6% being passed through the cast- ing shop and rolling' mill of Fabrika Kablova. Despite this strong increase in capacity, which led to a brilliant export trade, the Fabrika Kablova Svetozarevo began by importing cathode copper, for the first time making Yugoslavia an importer of copper. Today, the Fabrika Kablova have established a good repu- tation even beyond the borders of Yugoslavia, but little is known of its production methods. The success of the enterprise may be ascribed to the choice of producing oxygen-free copper. It has been customary in the past to produce wire bars at the electrolytic refinery. When the Fabrika Hablova Svetozarevo were planned, it was decided to depart from conventional practices and to cast the wire bars right at the wire and cable plant. Several melting and casting methods were considered, such as stationary or rotary Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 reverberatory furnaces, horizontal casting wheels, and others. Finally, it was decided to use a process for pro- duction of oxygen-free copper. Today, the Fabrika Kablova Svetozarevo is the only plant in the world whose entire production consists of oxygen-free copper. The plant has now been in operation over two years (in 1959) and it has been found that the choice of process and equipment was entirely justified. This paper is intended to acquaint the engineering public in general with something new in metallurgy, with a process that has been tested in our country for several years. WHAT IS OXYGEN-FREE COPPER? Oxygen-free copper is a type of copper produced by a patented process, and until recently it was manufactured exclusively by the U. S. Metals Refining Company, Carteret, New Jersey, a subsidiary of American Metal Climax, Inc., under the registered trademark "OFHC". Oxygen-free copper is not deoxidized copper, i.e., copper from which the oxygen was removed by means of phosphorus, lithium, or some other metallic of metalloid reducing agent; it is a copper which has not been oxidized during remelting, and therefore requires no oxygen removal. Copper from which oxygen has been removed by some agent is called deoxidized copper. Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Oxygen-free copper is produced In equipment which maintains the molten metal protected from contact with air throughout the entire process. The selected cathode copper is converted directly into the desired cast shape under strictly controlled conditions, thus avoiding con- tamination of the pure electrolytic copper. This type of production assures a very high quality metal with a copper content ranging from 99.95% to 99.99%. Since the impurities are kept very low - of the order of about 0.01% - the metal has the characteristics of pure copper. Some of the important properties of oxygen- free copper are the following: a) High Ductility. This metal has a remarkable capa- city for undergoing successive drawings without inter- mediate annealing. Ductility of oxygen-free copper Is practically unchanged by cold deformation. Therefore, it is particularly suitable for any type of deep drawing. The occurrence of "ears" is unknown in this type of copper. b) High Electrical Conductivity. It is assumed that the conductivity of copper is affected by the presence of unoxidized impurities In solid solution. Oxygen-free copper guarantees high conductivity because of Its high purity and freedom from impurities. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 c) Immunity to Embritttlement. When heating oxygen-con- taining copper to a relatively high temperature in a hydrogen-containing reducing atmosphere, the oxide is de- composed - under formation of water vapor - breaking down the edges at the crystal boundaries and impairing metal quality. Oxygen-free copper is immune to this type of deterioration, and therefore is well suited to gas welding, bright annealing, and other operations where copper comes in contact with hot hydrogen. Thus, this copper type is particularly suited for applications in electronics for high-vacuum components because it does not break or become brittle, as is the case with copper containing oxygen. d) Ability for Form Hard Adhesive Oxide Skins. This is one feature of oxygen-free copper of particular ad- vantage to the electronics industry. When this copper type is heated above 800 C (1470 F), a hard adhesive oxide skin is formed on the metal surface which permits a permanent tight connection with glass and guarantees a ,permanent vacuum in electronic tubes. Copper containing oxygen or phosphorus, even as little as .0005%, does not have this property. e) High Softening Point. Since the impurities are present in solid solutions, oxygen-free copper softens at a higher temperature than ordinary copper after cold deformation. Elements in solid solution, even when pre- sent in very small amounts, raise the softening tempera- Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 ture. Therefore, oxygen-free copper is well suited for apparatus and machinery working under difficult conditions where the metal is subject of special stresses in addition to a higher temperature. f) Low Vapor Pressure at Very High Vacuum. There are no gas occlusions in oxygen-free copper, a result achieved by the high densities obtained with this casting process (8.89 to 8.93 kg/dm3 In the as-cast condition). Further- more, there are no impurities present that may have a low vapor pressure at various temperatures under high vacuum. This property is of particular importance for production of high-emission tubes. In addition to the above properties, oxygen-free copper has other characteristics different from those of ordi- nary or deoxidized copper, such as high Impact resistance, creep resistance, excellent anode distribution during plating (electrolytic coating), etc. During World War II, oxygen-free copper was in great demand and the metal was rationed. It was used for making electronic tubes for radar equipment and thin-walled tubes for aviation heat exchangers. In our country, oxygen-free copper is used chiefly in the production of several types of cables and conductors and to a smaller extent in the electronics industry; from the beginning, it has shown its superiority, both from the point of view of quality and of processing and workability range of the metal. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 HI STORY. Oxygen-free copper was little more than a metallurgical curiosity until the Scomet Engineering Company started its Summey induction furnace with two melting chambers, the first and largest plant in the world, to begin commercial production. Before that time, only small quantities of dubious value and quality were obtained from laboratory experiments. The first attempts to obtain oxygen-free copper were made as early as 1919 In the foundries of the Scovill Manufacturing Company, Waterbury, Conn. However, this company was not in a position to continue the very promising work that had been started. Almost ten years passed until means were found to continue with these early experiments. In 1928, an agreement was reached with the American Metal Company, Ltd. (now known as American Metal Climax, Inc.), on the basis of which facilities were made avail- able at Carteret, N.J., for the production of oxygen-free copper by its wholly-owned subsidiary, the U.S. Metals Refining Company. The oxygen-free copper manufactured by this company since 1931 has been sold under its sole and exclusive "OFHC" trademark. The complete success of this venture was jeopardized at first by the frequent breakdowns of the refractory lining in the Summey furnace inductors. Even then, high conductivity oxygen-free copper was produced to satisfy Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 the great demand, but a conventional reverberatory furn- ace was used for the preliminary refining by the classi- cal method, supplemented by passing the molten copper through a charcoal-filled deoxidizing unit. During World War II, the demand for oxygen-free copper increased beyond the available productive capacity. For this reason, and becuase of the many other advantages of the process, a new production unit was erected at the U.S. Metals Refining Company and started operations in 1942. This plant uses a Summey induction melting furnace with oscillating movement and a protective atmosphere, eliminating the reducing unit. The refractory material used for the inductors in this furnace is now more care- fully chosen and the inductors are more durable; many other improvements have been made to the process, such as moisture removal from the protective gas used, etc. This furnace is still In operation today, producing 7-8 tons per hour of "OFHC" copper in commercial shapes. At the beginning, the metal was cast into vertical molds and most oxygen-free copper still is produced in this manner; however, continuous casting was furst applied in 1942, initially with Welblund-Benard, or INCO, casting machines and, after 1948, with Junghans-Rossi casting ma- chines. In all instances, casting is conducted under a protective atmosphere. Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 The basic disadvantage of the Summey furnace was the long time required for replacing an inductor (10-15 days), and the relatively short inductor life (t1.-8 months), and this led to the development of the Scomet and Ajax-Scomet furnaces. One such furnace was installed at Pori, Finland, by the Outokumpu Mining Company in 1939, which operated the furnace and produced oxygen-free copper under license by the Scomet process. These casting furnaces have a single chamber serving for both melting and pouring, and casting is done Into vertical water-cooled chill molds on a rotat- ing wheel, using a reducing unit. Towards the middle of 1952, negotiations were started and at the end of that year (December 10, 1952), a contract was signed with the Ajax Engineering Corporation of Tren- ton, N.J. This contract enabled construction of the third plant In the world to produce oxygen-free copper by the Scomet process, at Svetozarevo, Yugoslavia. Construction took about two years. The new plant differs from the two above mentioned operations in that the casting shop at Svetozarevo is more modern and highly automated, its entire production being cast by Junghans-Rossi casting machine. The basic shape cast here is the wire bar. Figure 1 gives a general view of the casting platform. BRIEF DESCRIPTION OF PROCESS. Copper cathodes are produced by electrolytic refining, the most perfect method of purifying the metal; because of their shape, however, the cathodes have to be remelted A` Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 and cast into commercially desirable shapes. Before electric furnaces were used, remelting was carried out in reverberatory furnaces which make it impossible to avoid contamination of the high purity copper cathodes, and therefore a complete fire-refining process is required. Today, according to American statistics, 80% of all pri- mary copper produced is in the form of cathodes; 72% are still remelted in reverberatory furnaces and about 8% in electric furnaces, of which 3.2% are used for pro- duction of oxygen-free copper in low frequency induction furnaces, and about 4.8% are remelted in electric arc furnaces. The contamination of the high-purity cathode copper Inevitably occurring in the reverberatory furnace called attention to the advantages of electric furnaces. It was found that economical remelting of the cathodes would ordinarily have caused contamination unless-the small amounts of sulphur and gases usually entrapped in the charge are eliminated. This idea forms the basis for the patented process of remelting cathode copper under a pro- tective atmosphere, and for the production of oxygen-free copper of high conductivity. Figure 2 shows a schematic diagram explaining the production of oxygen-free copper at the Fabrika Kablova cast- ing shop: Electrolytically refined first-quality copper cathodes (1), containing at least 99.96% Cu, and having a fine-grain structure, hard and dense, without large amounts of nodules, well washed, with sulfate removed Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 as much as possible, with no carbon, pigments, or other impurities of any kind, are charged continuously into the melting furnace (3). The metal flows continuously from this furnace through an electrically heated launder (4) into the pouring furnace (5). From the pouring furnace, the molten copper flows at a precisely determined tempera- ture into the bottomless chill mold (7) in which the metal solidifies Into the shape of the wire bar. Beneath the chill mold, In a special chamber, ring-shaped sprayers (8) are located which cool the wire bar to room tempera- ture. From this chamber the water runs into the sewer and the wire bar passes through a rubber wiping box to trans- port rolls (9) which draw It 'down. at a constant speed to- wards the saw. Cutting the wire bar into determined lengths Is done automatically by a mechanism moving down- wards with the wire bar, which consists basically of clamps (10) holding It firmly, a rotary saw (11) which moves horizonally, and a basket (12) for transfer to the gravitation conveyor (13). In both furnaces the molten metal Is covered with a layer of charcoal (2). The protective gas is produced In a special group of apparatus, starting with a "Galusha" gas producer (14) from where it passes through a scrubber (15), a sulphur remover (16), a gas converter (17) for complete com- bustion of the producer gas, and a refrigerator (18) for moisture removal; thence to another generator (19) of Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 "drycolene", where the converdter gas is reduced in a re- tort by red-hot charcoal. The reduced gas is filtered at (20) and passes to the hood (6) above the chill mold and Into the melting furnace, the heated launder, and the pouring furnace, eliminating all possibility of contact between molten metal and atmosphere. MELTING AND CASTING EQUIPMENT AT THE FABRIKA KABLOVA SVETOZAREVO A. The Melting Furnace consists of a hexagonal welded- steel drum with openings at both ends, for cleaning the furnace and charging charcoal, respectively. The cathode charging door is located at the center of the drum's upper end, slightly above the horizontal plane passing through the horizontal axis of the drum. A pair of open- ings is provided on each side of the lower half of the drum for installation of the inductors. Figure 3 shows the construction of this furnace. At the front end of the furnace,.at the side where the charging door is located, a launder is arranged in such a manner that the discharge opening is located at the center of rotation of the furnace, i.e. slightly below the center of the furnace drum. The furnace is mounted on a frame and rolls and may be inclined to 300 by means of a hydraulic mechanism. Attached to each side of the drum are two twin-coil inductors, each rated 300 kw at 575 Volts, 50 cycles. Thus, the furnace has a total power rating of 1200 kw and a maximum melting rate of 4.3 tons per hour. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 Each of these inductors has its separate control unit rated 300 kw, 575 V, 50 cycles, single-phase, with built-in circuit breakers, autotransformer, high and low voltage power contactors, etc. All four power control units in turn are connected to a single operating panel from which the entire melting furnace is controlled automatically. The furnace drum is lined with special refractory insulating blocks. The approximate analysis of this ma- terial is: 15% Al 2-03 and 52% SiO2. Expansion at 1175 C (2150 F) Is about 0.5%. The material has a high crush resistance and its apparent porosity is less than 20%. The "deep connection" principle is used in construction of the lining, using a minimum of cement, and grinding the surfaces of contact between individual blocks. Meti- culous care is necessary in preparing, drying, heating, and emptying the furnace so as to insure long lining life and economical operation of the furnace. Lining life is further influenced by the oxygen-free copper being melted, a metal which does not "wet" the refractory. The lining is installed by skilled workmen who carefully follow specifications and directions. Every block must be set tightly and precisely into the lining to give long con- tinuous service. Of particular importance is the accurate positioning of the various "guide points" in the lining, such as the opening for the launder, the inductors, and the top bricks finishing the lining. The block forming Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  l9Pe~a nn.e__ Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 the opening to receive the launder must be perfectly bonded with the launder itself. At the inductor openings, the lining must have a completely smooth surface on which the Inductor will attach well. When drying the refractory lining, it must be consi- dered that water cannot evaporate through the outer sur- face since this is a steel shell. Therefore, it must leave the lining through the inner surfaces. Drying takes about one month. Before starting operation of the melting furnace, the. lining is heated from the inside to at least 900 C (1650 F). When it throws sparks, the lining temperature is held and raised no more than 100 C (210 F) in 24 hours. The furnace is maintained at 900 C for one or two days before molten copper is charged. The melting furnace inductors are also of welded-steel construction and contain the necessary nonmagnetic sec- tions, cores, primary coils, blowers for cooling the pri- mary coils, and refractory material for lining the induc- tors. Figure 4 shows a cross section of such an inductor. -14- In preparing the refractory lining of the inductors, special care and techniques are required to insure long operating life. Lining begins with the laying of asbestos and mica sheets, continues with light linsulating bricks, and ends with a rammed refractory for filling the joints. The ramming mixture used is a sillimanite with the appro- ximate analysis 41% S1O2, 562 A1203, and small amounts of 1~ . ,VVnF1? Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 CaO, MgO, and Fe2O3; loss upon heating, 0.4%. Grain size is of importance as well as moisture content, which is about 1~% in the mixture when ready for application. The techniques of preparing the lining and applying the ramming material to the inductor, as well as the qua- lity of the material, may insure a long operating life. Normal inductor life under continuous operation appears to be about l- years. At the Fabrika Kablova Svetozarevo, the melting furnace inductors now have been in continuous operation for 221 years, have remelted 35,000 tons of copper cathodes, and are still in first class condition. Before being put in operation, the inductors must be air-dried for about two weeks, then dried by electric heat for at least 3 months, keeping the lining at a temperature between 60 and 80 C (140-180 F). During this time, the lining is transformed into a monolithic block. The longer it is dried, the better. After the inductor is attached to the furnace drum, and before charging the first molten metal, the inductor channels are heated to at least 950 C (1740 F). The furnace is started in operation by a charge of molten metal, but only when the secondary coil of the inductor has been put under voltage. Molten metal for starting is prepared in a small portable furnace of I,-ton capacity. The charge is poured and, if necessary, deoxi- dized to minimize oxygen content. The furnace is then Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 rotated to 300 and the first two inductors charged and power applied at 35 kw each; the furnace is then placed in a horizontal position and the other two inductors are charged with molten copper in the same manner as the first two. The molten metal surface is now covered with a char- coal layer to prevent oxidation of the metal. This layer is about 10-15 cm (1r-6 in.) thick and the charcoal used has a grain size of 2.55 cm (1-2 In.). The furnace is then slowly charged to its normal capacity with copper cathodes. Total capacity is of the order of 13.5 tons. The minimum metal content under operating conditions is 6.1 tons, with the furnace inclined to 18? In a clock- wise direction. When charging, the cathodes open the furnace charging door by their own weight, and after they have entered the furnace door closes by its own weight so that the furnace practically remains closed at all times and it is possible to maintain a protective atmosphere in it; at the same time, charcoal consumption to cover the molten metal is reduced:to:minimum. Discharging speed is usually governed by the melting furnace and by the voltage available from the power supply lines. With full voltage available, the maximum capacity of 4.3 ton/hour is obtained. Normal melting rates range from 3.17 to 11.0 tons/hour. During normal operation, furnace temperature is held to 1170-30 C (2140-2160 F), and fluctuates within + 20 C (70 F). Temperature variations of this order are a problem in continuous casting and therefore a pouring furnace was provided. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 B. Electrically Heated Launder. The molten metal flows from the melting furnace to the pouring furnace through a closed., electrically heated launder using elec- tric rod heating elements. The construction is shown in Figure 5. Electrically, the launder is divided into three sec- tions, each of which has its control unit and autotrans- former to regulate voltage and, thereby, temperature. Each section is rated 7 kva, 575 V, 50 cycles, single phase. The launder is connected with the melting furnace exactly at the center of rotation of the furnace so as to take advantage of the smooth bricks to make an outlet for the protective gas introduced at this point. At the pour- inf furnace end of the launder, there is a 900 elbow which forms an extension of the launder, of heat-resist- ant steel and refractory lined; this elbow connects with the pouring furnace and metal is charged through it into that furnace. A thermocouple is attached to each launder section to control temperature which is normally held at 1030-1050 C (1835-1920 F). Since molten metal flows through the laun- der in a continuous stream, protected by a reducing gas, the electric heating elements have a very long life. More than six months pass before their efficiency decreases to such a degree that they have to be replaced. -1 7- Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 18- ~+VU," j? ft 4~'9 C. Pouring Furnace. This unit, too, Is of welded .a~yL steel construction, designed to hold and oast molten cop- per into a Junghams-Rossi continuous casting machine. The furnace has four main parts: the furnace body, the spout, the lid, and the inductor. The portion of the furnace where the inductor is attached, as well as the in- ductor itself, Is lined with a sillimanite rammed refrac- tory applied by a special process, and the remaining por- tions of the furnace are lined with special insulating refractory bricks having ground surfaces. The quality of the refractories used here is the same as for the melting furnace. The pouring furnace spout is purposely construct- ed of fire-resistant material and has a zirconia insert for pouring, a silicon carbide muffle with heating elements inserted, silicon carbide slabs, etc. Figure 6 shows a cross section through the pouring furnace spout construc- tion. The drying, preheating, and initial operation has been described in detail above and must be strictly adhered to. The furnace is designed to be tilted forwards and back- wards and at the same time shifted horizontally, all by a hydraulic mechanism. In addition to the charcoal layer on the melt, a pro- tective atmosphere is introduced into the furnace which penetrates into the launder and acts as protection at this point where no other protective cover exists. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 CIA-RDP80T00246A011300260001-7 The pouring furnace inductor is rated 100 kw, 575 V, 50 cycles, single phase. It has its own control unit and electrical apparatus for completely automatic operation. Installation and insulation of the inductor are the same as for the melting furnace inductors. However, in this case lining life normally will be about three years under continuous operation. Figure 7 shows the pouring furnace inductor which is of different design than the melting furnace. Inductors. -19- The holding capacity of the pouring furnace is about 2.5 tons. Before tilting the furnace for pouring, metal temperature Is increased to 1200 C (2190 F), but the normal pouring temperature of 1150-1160 C (2105-2150 F) is reached within the first 10-15 minutes. Temperature fluctuations in the pouring furnace are of the order of + 2 C, a factor of great Importance to the successful continuous casting of this metal. Both the pouring and melting furnaces are automatically controlled by thermocouples and electric pyrometers re- gistering the temperature. Otherwise, it would be impossible to regulate furnace temperature as the furnaces are comple- tely enclosed. D. Junghans-Rossi Continuous Casting Machine. The only casting method used at our plant is continuous casting with a Junghans-Rossi machine. This machine operates at casting speeds from 0 to 1524 mm/min. (for cross sections of l" x 14.", about 8 ton/hour). Maximum width attainable is 153 mm (6" x 6" square) and minimum width is ~1 mm (2" x 2" square). Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Casting length is adjustable up to 1524 mm, our present standard length being 1140 mm. The main components of the casting machine are: the casting table with chill mold and water sprays (upper unit), the main drive and transport rolls (middle unit), and the saw with its hydraulic mechanism for cutting the wire bar (lower unit). The chill mold is arranged in the center of the cast- ing table, at the vertical axis of the saw clamps, with the transport rolls holding the wire bar in position. The casting platform moves up and down within from I" to 1i"-, adjustable in steps of 1/8". When casting our 4" x 4" wire bars, the casting table movement is of the order of 5/8". Before starting operation, and after any adjustments, the casting machine is synchronized. This means that the downward motion of the chill mold must be the same as the peripheral movement of the transport rolls so that there can be no relative movement between the mold and the bar being cast. The upward movement of the mold is about three times the speed of the downward movement. The wire bar is first cooled by water in the chill mold and emerges at a temperature of 850-900 C (1560-1650 F), and is sub- sequently cooled to room temperature by water sprays: The cooled wire bar then passes a rubber wiper and the water is, conducted from the cooling chamber into the sewers Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 by tubes. Figure 8 shows this middle unit with the main drive, transport rolls, and casting table mechanism. In addition to withdrawing the wire bar from the mold at a constant speed, which is governed by the casting speed, the transport rolls at the same time cause the wire bar to push down the basket receiving the cut wire bar, thus actuating the entire flying saw operation when the bar has reached the determined length. The saw is completely automatic and operates with three different- systems, hydraulic, pneumatic, and electric. As the wire bar - withdrawn by the transport rolls at a specified speed - strikes the bottom of the receiving basket, it pushes the basket downwards until it reaches its determined length. At this point, the pneumatic system actuates the hydraulic system and starts the sawing cycle by means of a series of valves which open and close one after the other, and change the direction of the oil in the lines. The saw clamps grasp the wire bar tightly and the s*aw operating platform then moves downwards with the wire bar through a series of steps. The motor operating the saw blade works continuously. After the clamps have grasped the wire bar, the saw is pushed to the wire bar horizont- ally at a set speed by hydraulic means; the sawing speed is adjustable, depending on casting speed and on the sharp- nessof the saw. After the wire bar is cut, the saw is withdrawn to its original position and the motor operating the platform is started to bring it back to its upper starting position. In the meantime, the basket is lowered pneumatically and the wire bar transferred to the gravity conveyor, whereupon the basket returns to its upper post- Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 -21-  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 tion. The cycle is repeated for each successive cut. Figure 9 shows the saw during the cutting operation. The chill mold used for casting this type of copper. differs from those used for casting copper alloys or aluminum. It consists of a monolithic copper block with ducts drilled in for suitable water cooling. The profile to be cast is cut out from the center of this block and the inner surfaces are machined, polished, and chrome- coated (.05 mm) so as to obtain the greatest possible smoothness and to reduce friction between cast bar and mold surface. Accordingly, at any interruption of the casting process and before restarting, the mold is cleaned and polished with a special polishing material, using a special flexible-shaft tool. Completely smooth surfaces ire obtained in this manner and no milling of the surfaces is required. -22- A hood is placed over the top of the chill mold and a.protective atmosphere introduced so that the molten metal will not come into contact with the air. In addition, butane gas is introduced through a ring for lubrication; with the high metal temperatures and in absence of air, this decomposes into H2 and C. The carbon is precipitated in the form of soot on the metal surface and is constantly drawn against the mold walls where it acts as a lubricant. The proportions of protective gas and butane in the chill mold are of great importance for successful operation and for the quality of the casting. Just:sufficient gas should Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 be applied to force the air slowly out through the hood, and if this is attained, the amount of butane used usually is of 200-300 ml. With these proportions, it is obvious that carbon settles on the metal surface, and also the bright surface of the metal. If butane is used excessively, spots and occlusions are formed which will appear as im- purities on the wire bar surface. Correct cooling in the mold is extremely important for the continuous casting of copper. The soundness of the casting depends on uniform cooling in the mold and by .the sprays, and the slightest irregularity in this respect leads to rejects. Roughly speaking, one third of the en- tire amount of heat is removed in the mold. The remainder is removed by the sprays. The approximate water consump- tion of the mold for a 1L" x L1" section is 70-90 liter/min. and 130-200 liter/min. are used in the sprays. Deoxidized copper and copper alloys present no problem in continuous casting, but electrolytic tough pitch copper from reverbe- ratory furnaces has not yet been cast successfully by a continuous process, although experiments have been made in that direction for a long time and are still being con- ducted. Before casting begins, the first wire bar is inserted about two thirds into the chill mold and the space between mold and casting is filled with asbestos strips. The mold table Is set at its highest position and the speed is set for starting. Normally, casting temperature is held be- tween 1150 and 1165 C (2100-2180 F), but for starting it Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 is increased to 1200 C (2190 F) so as to prevent freezing of the downspout; within the first 10-15 minutes, the tem- perature is then decreased to normal. It seems obvious that a carefully standardized procedure is required In starting and casting. Up to the present, the maximum production for any one day has been 95 tons. During 1959 it reached 103 tons/day. mal daily production runs around 80 tons. E. Production of Protective Atmosphere. Since the production of oxygen-free copper consists only of the con- version of high-quality copper cathodes into suitable shapes (in this case wire bars) for further processing - while at the same time maintaining the quality of the cathode metal - the remelting process is carried out under a specially prepared protective atmosphere which Is of primary importance to the entire production process. , This protective atmosphere Is produced in a group of apparatus designed to yield as an end product the desired gas composition. Figure 10 shows a schematic view of this apparatus. -24- The equipment to produce the protective atmosphere for the oxygen-free copper casting shop at the Fabrika Kablova r.cohsists of the following: An apparatus to produce gas from charcoal, a gas scrubber for washing and cleaning, an appara- tus for removal of water vapor, and an apparatus for convert- ing carbon dioxide into carbon monoxide, with filters. Charcoal is burned in a.smgll "Galusha" gas producer lined with insulating and refractory brick, and equipped Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 -25- with an air blower; normal producer gas is made with an approximate composition of 16% H29 27% CO, 5% C02, 1% CH11, remainder N2, and an approximate heat value of 1330 kcal/ Nm3. This generator can burn up to 20 kg of charcoal per hour. The cold washed gas gives about 87% of the total heat in vigorous firing, up to 1,660,000 kcal/hour. If needed, less charcoal may be burned to produce smaller amounts of gas per hour. Our normal production requires about 140 kg of charcoal per day, or 5.8 kg/hour. Grain sizes range from 50 x 50 mm to 25 x 25 mm. The gas so produced is first cleaned in a scrubber to remove dust and tar and, if needed, SO2. The scrubber is filled with hard washed coke, of a grain size of 3/8" to 3/4" in the lower half, and 3/4" to 1/2" in the upper half. Gas is discharged from the bottom; there is a water out- let at the bottom and a water spray at the top of the scrubber. Charcoal was chosen as fuel because of its low sulphur content. Since sulphur is highly detrimental in copper, particularly in the form of H2S; nevertheless, a sulphur remover is used which contains sawdust impregnated with iron oxide (Fe2O 9, and the following reaction occurs as the gas passes through this: Fe2O3 + H2S ? Fe2S3 + H2O. The cleaned producer gas is sent to the converter by a gas pump with a constant pressure of 0.211 atm. The gas-air Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 proportion to the converter is carefully controlled by measuring instruments and they are mixed, compressed and burned. The burner is located in a reaction chamber filled with catalytic bricks of a special kind which help to complete the combustion process. The gas from this chamber is composed of CO2 and N 2. Some of the moisture is removed in the converter cooler which brings the gas to a temperature of 17-18 C. The gas is then conducted to a refrigerator and chilled to +2 C, thereby loosing the major amount of water. This gas - now containing only 002 and N2 - goes to a "drycolene" generator. This is actually a retort of heat resistant steel, filled with charcoal of carefully con- trolled grain size, which has its outside walls heated so as to maintain the retort temperature and charcoal temperature at 1050 C (1920 F). The gas enters the retort at its lower end, passes through a layer of glowing char- coal, and exits through a dust filter from where it goes to the casting machine where it serves as a protection. -26- As the CO2 passes through the glowing charcoal at 1050 C, it is reduced to CO, and yields a gas with the following analysis: 20-25% CO, .5-1% CO2, .5-1% CH40 .5-1% H2, re- mainder N2. This is the protective atmosphere which pre- vents the molten copper from coming into contact with air. The entire gas generating apparatus is provided with instruments, regulating valves, safety devices, etc., to Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 -27- WIVUsdaJutu ILL operate continuously and very quietly. Though the appa- ratus is ideal for automatic analyzing, the gas in prin- ciple is controlled by an Orsat apparatus. Figure 11 shows this equipment. PROCESS AND PRODUCT CONTROL. A method of statistical process and product control was adopted for the casting operation. The completely continuous melting and pouring process, together with the full mechanization and automation, allows a high degree of control and accuracy. According to the manual of instructions, process con- trol is carried out at the five key points where a cer- tain amount of information is recorded at precisely de- termined times to indicate the condition of that particu- lar portion of the equipment. In addition to the standard recording of instrument readings, every change is record- ed together with the exact time when it occurred. This is often accompanied by remarks and comments by the foreman in charge of the section. By recording the process in this way, for one thing, the foreman in charge of a section is compelled to record readings from various instruments at specified Intervals and note at the same time any changes that may have occurred, and if so, take the necessary steps; also, the total information gained in this manner from all key points at the same time intervals give a clear picture of the process and of its accomplishment. Based on this Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 information, the process may be speeded up or slowed down, improved upon and supervised. _2g_ These data, collected for each shift, also serve as a basis for daily reports on plant operations, listing all essential data such as amount of metal melted, hourly melting rate, average melting rate in tons per hour, amount of metal poured, analysis of casting machine operation, yield, amount of rejects and scrap, with analysis thereof, electric power consumption per ton of production, con- sumption of charcoal and other materials required in the operation and maintenance of the plant, etc. These data are an adequate basis for a complete economic analysis of the plant. Evidence of this kind made it possible in the course of this year, by supplementing the capacity and taking other measures at the plant, to reduce electric power consumption per tcn of finished product from 470 to 350 kwh, consumption of charcoal from 6.1 to 4.3 kg/ton, and increase the yield from 93.5% to 99.2%. Control of wire bars is obtained by: a) Visual Inspection on the conveyor: b) Measurement of specific gravity of approximately every thirty-fifth wire bar; c) Testing of physical and chemical characteristics In the plant laboratories. The physical laboratory is equipped with a small stand of rolls and a tensile strength machine. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7 For a complete analysis of a wire bar, it is standard procedure to take one sample for every four hours of cast- ing, or twice per shift. With the continuous casting pro- cess there is no danger of sudden changes in production. Whenever smaller amounts of copper from several sources are melted, a greater number of samples is taken. The following tests are made for a complete analysis: electrical conductivity, bending, torsion and rupture tests, elongation, macro- and microstructure, and a sepa- rately conducted embrittlement test. This last test con- sists of the following:samples are prepared for bending by heating for one half hour in a hydrogen atmosphere at 850 C (1560 F). In accordance with ASTM Standards B-170, the samples must withstand at least 8-10 bends. Ordinary electrolytic tough pitch copper with normal oxygen content will withstand not even one bend of this test. The following table gives comparative values for oxygen-free copper produced at our casting shop and for tough pitch copper from a reverberatory furnace, which were tested at the same laboratory. The table shows clearly the superiority of oxygen-free copper over tough pitch copper. In analyzing these re- sults, it should be kept in mind that the tough pitch copper used for these tests was of the best kind known with re- gard to purity and quality of the tough pitch copper cathode. As further Illustration, Figure 12 shows the macrostructure of oxygen-free copper and of tough pitch copper with about .0459o'02. Figure 13 shows the macrostructure of oxygen-free Approved For Release 2009/07/22 : CIA-RDP80T00246A011300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 -30- continuously cast wire bar of oxygen-free copper. Type Specif. Tensile Elonga- Specif. No. No. No. of of Gravity Strength tion Conduc- of of Bends / Wire tivity Bends Turns Embritti. Bar kg/dm3 1 kg/dm3 met/mm2 1 2 4 3 5 6 7 8 __w FKS .... ~. _ r _. T ._. ~_ 3.90 to _-.. . _b... .._. (oxyge 8.94 42-43.5 2 58.9 to 15-18 130 8-12 free) 59.3 -140 Toughy Pitch 8.50 to 8.75 40-14.2 2 58.2 to 10-12 100 0.0-+ 58.6 -130 Notes: 1) Tests in Columns 3 and 4 were made with hard-drawn wire, 1 mm in diameter. 2) Tests in Columns 5,6,7,3 were made with soft annealed wire, 2 mm in diameter. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 -Figure 1. General View of the Casting Platform at Fabrika Kablova Svetozarevo. Figure 2. Schematic diagram showing production of oxygen-free copper at Fabrika Kablova Svetozarevo. V Air HO-Water G Dryco ene gas B Butane gas 1 Cathode 2 Charcoal 3 Ajax-Scomet melting furnace Electrically heated launder 5 Bahney pouring furnace 6 Chill mold hood 7 Chill mold 8 Direct cooling chamber 9 Transport rolls 10 Clamps 11 Saw 12 Basket to receive cut wire bar 13 Wire bar to rolling mill 14 Galusha gas producer 15 Scrubber 16 Sulphur remover 17 Gas converter 18 Refrigerating machinery 19 Drycolene generator 20 Gastex gas filter Figure 3. Ajax-Scomet Melting Furnace. Cross Section. Figure 4. Cross Section of Ajax-Scomet Melting Furnace inductor. Figure 5. Electrically Heated Launder. Cross Section. Figure 6. Pouring Furnace. Cross Section. 1 Silicon carbide slabs 2 "Carbofrax" plug 3 Silicon carbide muffle 4 Zirconia throat and insert 5 Pouring spout Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Illustrations:  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Figure 7. Pouring Furnace Inductor. Cross Section Figure 8. "Middle Unit" of Junghans-Rossi continuous casting machine. Figure 9. Flying saw for cutting wire bars during con- tinuous casting on the Junghans-Rossi machine. Figure 10. Schematic view of gas producing apparatus. Figure 11. View of operating platform of the gas producer providing the protective atmosphere. Figure 12$ Microstructure of oxygen-free copper. Figurel2b. Microstructure of tough pitch copper. Figure 13. Macrostructure of oxygen-free copper wire bar produced by continuous casting. Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 44 f17 a Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 I l Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 ?  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 A ri ? O&P A". ? I' ? 0 l` 4 9 .0 ? 0 ? ? t Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 HFt'd.;?,~~ A',,, 7, T fie. C? a t)E>T Yt !e C.7 TT4 Y+J E0 Krap r- rrtt M"-sgngwGrk Sevolrro/JuVoskkwien F. Pl1PENCOF,DT, .uVj i..IDursn Jugu;lawiezt., alas weite und beliebta Reiseland von groBer, ursprungltdaer Scionheit, hat durdi seinen vielfaltigen Reidit.sm an Eudensc:latzer, und reine ci nstigen Wasser- ver tar.tnisse aufSeruidentlia?e Voraus,etzungen fur eine >dtnelle industrielle ErschlPeBung. Den zwangsiaurigeu Ent- wicklungen der Zeit folgend, nutzt das Lard seine Mogli.-h- keiten und befindet aide in einer U1nwdlzung suiner wirt- sdiaftlidien Struktur. Aus der Vielfalt der groBen Irdustri- alisL rurigsprojekte soil Tier ernes herausgenomrnen und erlau?err werden: Das Kupfer- und Mossingwerk Sevojno. Die anerkannt hodiwertige Kupferbasi. on Bor und Um- gebung, in Verbindung mit Ieidien Zinkvorkomznen, deren Verhuttungsanlagen ebenfalls groBzugig und modern aue- gebaut worden sand, war die naturlikhe Voraussetzung iiir deft Wunsch, ein eigenes grcBes Halbzeugwerk zu erricinten. Die Bead?iung der Steigerung des einheimischen Bedarfs und die Al idit, an.aatt der Bor-Kathoden weitgehend ver- edeltes lialbzeug zu exportieren, hab."n zu dem Entsdilu13 gefi hrt, ein Werk zu bauen, dessen Grdt3enordnung den Ein- satz moderner, leistungsstarker Maschinen und Einrich- tungen rechtfertigt und lohnt. Mit der Gesamtplanung wurde die Gutehoffnungchutte Sterkrade A.G. be auftragt. Die Walzwerke und Pressen wurden von der Schloemann A.G., Dusseldorf, geliefert und, soweit Maschinen vorhan- den w. wren, vervnllstandigt. Die Montage, Inbetriebsetzung and Vorfuhrung erfolgte unter Fuhruim der beiden genenn- ten Firmen. Als Standcrt wurde d:e Kreisstadt Titovo-Uzice bestimmt. Uzire hat etwa 20 000 Einwohner unnl:-liegt in der Mitte er Eisenbahnstredce Jieograd-Sarajevo Die Landwirtschaft bietet in der bergigen Gegend our geringe Moglichkeiten. Die W11dwirtschaft hat in den vergangenen Jahren stark gelitten. Die in groBem Umfang durch5efiihrten Wicderauf- forStungen brauchen Jahrzehite, bis sie wirtschaftlich ge- nutzt werden konnen. Der Gedanke, die Wirtsdiaft diesel Gegend zu starken und durdt das Werk neue .rwerbsmog- lidikeite.?i zu sdeafi:: a, durfte bei der Entsdieidung fur den Standort ausrdilaggebend gewesen sein. Da Uzice selhst in einem engen Gebirgskessel liege, wurde 6 km entfernt in dem bis dahin unbedeutenden Dorf Sevojno ein groB- fl3diiger Bauplatz zur Verfiigung gestellt, der jede Erwei- terungsmoglidikeit bietet und in unmittelbarer Nahe der Bahn 'iegt. Vorlaufig ist das Werk auf einen Lastwagen- park und auf die Sdimalspurbr.hn Beograd-Sarajevo ange- wiesen. In wenigen Jahren wird jedodi Sav-otnc) Station der Vollspurbahn sein, die Beograd mit dem im Ausbau be- griffenen Adria-Hafen Bar vert;inden wird. Fur den Betrieb des Metallwerk2~ niuBte zundchst im we- sentlidren mit dem Einsatz ungelernte:, hauerlidter Arbeits- krafte geredinet werden. Nur eine geringe Anzahl Spe- zialisten konnte Gelegenheii zu einer kurzfristigen Aus- bildung an ~.hnlichon jugoslawischen oder deutsdten Ar- beitsstatten erhalten. Da die wirtsdiaftlidi erreidibareKohla elneii ziemlich hohen Schwefelgehalt :ind andere unangenehme Eicfensdiaften hat, wurde in Hiablirc auf die giinstige Entwidcluna der Stromversorgung eine vollkomme-i au% elektrisdier Energie aufbauende Ausstattung des Werkes vorgenommen. _.edio- lich fiir die Versorgung mit Hci3uwasser zum Anwarmen der Beizbader, zum Spiilen und vo, allem fur die Heizung der Werkshallen und Nebengebxude wurde ein I.esselhaus auf der Basis von L.ignit errid-`et. Die Heizung ist so ausgelegt, da13 trotz der GroBe der Hallen selbst bei Wintertempera- turen von m%nus 30? C eine Hallentemperatu1? von 12 his 15? C tatsichlidt gehalten wurde. Das Produktionsproeramm besdlrankt side aa; die handels- iiblichen Halbzeuge wie illeccte, Bander, Rohre, Stangen und Drahte aus Kupfer und Messing ncdr DIN. iahkn/ggerp/oi ( yr 'Tr Move -U~, n^r^t?mrr^n?rnrnrmET 10 Die handelsiiblichen Kupfersorten, Messinge und Sonder- messinge werden hergestellt. In Sevojno wird ebenfalls leitfahiges Kupfer vom Typ SE-Cu nach DIN 1708 ge- gossen, das audi den USA-Normen fiir die Sorte OFHC entspricht. Die Vorteile des kontinuierlichen GieBens haben sich bei den hier vorliegenden Verhaltnissen voll ausgewirkt. Die Ausbi'.dung konnte side auf einige Spezialisten konzentrie- ren. Nur dadurdi war es moglidi, nach einem halben Jahr Betriebszeit schon die Giel3kapazitat von 2000 t monatlich zu tiberschreiten. Die verhdltnismdBig saubere und be- queme Betriebsweise der Stranggiellanlagen bietet eine erheblidie Erleiditerung fiir das Betriebspersonal. Die fii Sevojno iiblichen Sommertemperaturen erschwereu die Arbeit in den Warmbetrieben ohnehin erheblich. Die medianisdie GuBbearbeitung ist mit den iiblichen Ma- sdiinen neuester Konstruktion wie Schnellsagen, Platten- frasmaschinen, Block-Bohr- und -Drehbanken verschiedener Grof3e usw. ausgerii.stet. Zur Zeit wird die Sdimelzerei urn zwei Niederfrequenzofen erweitert. Platz fiir weitere Sdimelzofen und fiir die Aufstellung von zwei zusatzlichen GieBanlagen ist vorgesehen. Fiir die Herstellung von Son- derlegierungen in kleinen Mengen sind Kiihlkokillen vor- handen. Die Gief3erei ist damit alien Anforderungen ge- wadisen; sie arbeitet :nit giinstigen Einsatzzahlen, einer kleinen Belegschaft und hoher Wirtschaftlidikeit. Warmwalzwerk In den vergangenen Jahren hat sick die Fertigungsweise von Bledien in der NE-Metallindustrie stark gewandelt. Die Forderungen der Verarbeiter und die Leistungen der Walzwerksbauer zwingen den Halbzeughersteller, den alten Weg der Blediherstellung in Einzeltafeln zu verlassen und zur Breitbandwalzung iiberzugehen. Den technischen und wirtschaftlichen Vorteilen dieser Methode, die sick bei der Herstellung von Karosserie- und Weifbledien voll aus- wirken konnen, stehen bei Kupfer und Messing meist zu kleine Auftragseinheiten gegeniiber. Neue Bauarten von Maschinen und Zubehor ermoglichen aber heute auch mitt- leren Werken und soldien mit stark wediselndem Arbeits- programm die Modernisierung ihrer Walzwerksanlagen. Bei den fiir Sevojno vorgesahenen GrdBenordnungen war die Planung dadurch vorgezeidinet, daB 90 % der Erzeu- gung an Blech und Band bei Dicken von 3 mm ab warts liegen sollte und damit zur Herstellung als Breitband geeignet war. Mir die Fertigung der restlichen 10 % wurden zwei vorhandene Duo-Blechgerilste alterer Bauart vorgesehen. Im Betrieb hat sick spater erwiesen, daB selbst Bledie bis 5 mm Dicke vorteilhaft als Breitband gewalzt werden konnen. Das Walzplattenformat von 600/170/1250 mm hat im bearbeiteten Zustand ein Gewicht von etwa 1000 kg. Fine wesentlidie Erhohung des Gewichtes ist vorgesehen. Von aussdi1. ggebender Bedeutung fiir die Qualitat des fer- tigen Breitbandes ist ein Warmband mit guten Toleranzen und guter Oberflachenbeschaffenheit. Das aufgestellte Gleichstrom-Duo-Reversierwalzwerk mit den Walzenabmes- sungen 800 0 X 1600 mrl,geeignet fiir einenWalzdruck von maximal 1000 t, erfiillt these Bedingungen. Zum Antrieb die- nen 2 Gleichstrom-NebensdiluB-Umkehr-Walzwerksmotoren von je 1135 kW, die stoBweise 100 % iiberlastbar sind. Dies isi bei den eisten Stichen von.Bedeutiing. Die Kraftiiber- tragung erfolgt fiber Pin mit der_ Motoren direlct gekuppel- tes Hochleistungs-Stirnradgetriebe fiir ein maximales Ab- triebsmoment von 110 mt und zur Ubertragung von normal 2 X 1135 kW und maximal 2 >: 2270 kW bei einer Touren- reduzierung von 0 his 200/300 auf 0 bis 40/60 U/min. Die maximale Walzgeschwindigkeit betragt 2 m/s. Die Walzen sind in geschlossenen Einbausti cken mit preB- fettgeschmierten Kunstharzschalen gelagert, die ein schnel- les Auswechseln der Walzen gestatten. Die A.nstellge- schwindigkeit betragt 7 mm/s. Um sicherzustellen, dell das Walzgut immer gerade auslauft, kann jede Druckschraube fiir sick unter vollem Druck mit 0,25 mm/s nachreguliert werden. Vor und hinter dem Gerdst sind die Arbeitsrcll- gange mit den Blockdreh- und -Zentriervorrichtungen an- geordnet. Die Verlangerungen der Arbeitsrohgange, die mit angeflanschten, in Walzlagern laufenden Rollenaggre- gaten ausgeriistet sind, erlauben das Auswalzen von Ban- dern bis etwa 30 m Lange. Das NormalmaB der Warm- walzbander fiir Breitband von 1000 mm ist 1060/5/22 000 nim. Die warrngewalzten Bander werden auf einer Einroll- maschine mit maximal 1100 mnm Bandbreite gewickelt und rollen durch Eigengewicht zu einem 3-stufigen Kiihlbett ab. Vor der Einrollmaschine ist eine langere Kiihlstrecke ange- ordnet, wo Kupferbander mit kraftigen Wasserstrahlen ee- plbtzt und vor dem Einrollen abge'ciihlt werden. Zum Ab- legen starkerer Walzplatten fiir dicke Bleche wurde die in Abb. 5 vorn sichtbare Stapelvorriditung angeordnet, die so ausgebildet ist, daB das Bassin mit zirkulierendem Was- ser gefiillt werden kann, um Kupferwalzplatten ebenfalls in einem Arbeitsgang zu plotzen. Das Anwarmen der Walzplatien erfolgt in drei elektrisch beheizten StoBofen mit einem AnschluBwert von je 550 kW. Die Ofen haben 6 Regelzonen und Sind fiir eine Hochst- temperatur von 1050c C gebaut. Ihre Leistung liegt bei 3,5 t Walzgut je Ofen und Stunde. Die angewarmte, ausge- stoBene Walzplatte kommt auf den in Abb. 6 siditbaren Rollgang, der an der Ofenseite angehoben wird. Durch ihr Eigengewicht rollt die Platte auf den Transportwagen, der sie von dem jeweils in Betrieb befindlidien StoBofen zum Walzwerk fahrt. Zwischen dem Plattentransportwagen und 896 Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7  Approved For Release 2009/07/22 : CIA-RDP80T00246AO11300260001-7 #di'v' '