APPROVE~ FOR RELEASE: 2007/02/08: CIA-R~P82-00850R0002000600'16-6 , ~ ~ i4 MARCH i988 CFOUO 1r88) i OF 2 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USI: ONLY JPRS L/8975 14 March 1980 U SS R Re ort p CONSTR~ICTION AND EQUIPMENT - (FOUO 1 /80) ~ FBIS FOREIGN BROADCAST I~JFORMA~'ION SERVICE FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02108: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY JPRS L/8975 14 March 1980 USSR REPQRT CONSTRUCTION AND E~UIPMENT (FOUO 1/80) CdNTENTS PAGE CONSTRUCTION Problems in the Planning and Stimulation o~ t;apital Construction (T. Khachaturov; VOPROSY EKONOr~KI, No 12, 1979)..,.. 1 METALWORKING EQUIPMENT Optimizing Automated Machine-Tool Sections (M. Kh. Blekherman; STANKI I INSTRUMENT, No 5, 1979) 12 ` - Standardized Subassemblies of Machine Tools (L. S. Bron; STANKI I INSTRUMIsNT, No 5, 1979)........ 20 New Line of Spindle Boxes Elaborated (G. I. Gorelik, et al.; STANKI I INSTRUMENT, No 5, 1979) 27 Power and Rotary Index Tables With Hydraulic Drive (V. B. Genin, Zh. E, Tartakovskiy; STANKI I INSTRUMENT, No 5, 1979) 35 Power Tables With Electromechanical Feeder Drive (R. G. Chaadayev, G. I. Gorelik; STAbTKI I INSTRUMENT, No 5, 1979) 45 Multi-Spindle Boxes of Unified Series UNYe-3100 (V. M. Lobusev, et al.; STANKI I INSiRUMENT, - No 5, 1979) 51 ' a - [IYI - USSR - 36a FOUO) FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 CONTENTS (Continued) Page History of Five-Year Plans for Machine Tool and Tool Building _ (STANKI I INSTRUMENT, Jun 79) 58 ~ Angular Coordina~te Gauge for Digitally-Programmed Machine Tools (G. A. Lebedev, et al.; STANKI I INSTRUMENT, Jun 79) 66 _ s ~xhibit of Specialized Machine Tools From Socialist Countries (0. I. Aver'yanov; STANKI I INSTRUMENT, Jun 79)...... 72 East German Articles on New Machine Tools (STANKI I INSTRUMENT, N~v 79) 79 Digital Program Machine Tools, by P. Sachowitz, W. Pabst Digital Program Control Lathe, by K. Schnaubelr.auch - b - FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007102/08: CIA-RDP82-00850R000200060016-6 ~ I ; , ~ FOR OFFICIAL USE O1V~.Y CONSTRUCTION PROBLEMS IN THE PLANNING AND STIMULATION OF CAPITAL CONSTRUCTION Moscoca VOPROSY EK~NOMIKI in Russian No 12, 1979 pp 3-11 [Article by Academician T. Khachaturov] [Textl The decree of the CPSU Central Committee and IJSSR Council of Ministers ' "On Improvi~ig Planning and Tntensifying the Impact of the Economic Mechanism on Increasing the Effectiveness of Production and Improving the Quality of ~ the Work" contains a system of ineasures for the improvement of planning, capital construction and cost accounting. These measures arQ an outgrowth , of the stage of developed socialism in which the volume of production is � significantly increased, its technological level becomes more complex, and the interdependence of various branches and enterprises is enhanced. All this makes new and higher demands on the management of the national economy, on the improvement of the economic mechanism, on planning, and on cost ' accounting. _ ~ With each passing year, higher demands are made on capital construction, the effectiveness of which determines the growth of production potential arid prospects for the development of the country's economy. The decree assigns a significant place to the improvement of capital construction. Particularly important is the fact that the decree views such improvement as part of the interconnected system of inea~ures encompassing planning, construction and cost accounting and envisaging the implementation of uniform principles: - higher effectiveness and quality, orientation toward five-year periods and longer periods, pr~portionality in economic growth, increased interest and responsibility of managers and performers for the attainment of high end ~ results The decree defines the periodicity and procedure for compiling long-range and one-year Nlans of our country's economic and social development. The ~ USSR Academy of Sciences, the State Committee for Science and Technology and The USSR State Committee for Construction Affairs are instructed to draft a 20-year comprehensive program of scientific and technical progress adjusted _ for five-year periods every five years. This ensures the continuity of planning. The USSR State Planning Committee together with USSR ministries ~ and departments and the councils of ministers of union republics are charged , I FOR OFFICIAL U5E ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY with the responsibility of drafting the Basic Directions of Socioeconomic Development of the USSR for 10 Years by Five-Year Periods based on long-range socioeconomic tasks articulated by the party and the Comprehensive Pro~ram for Scientific and Technical Progress. The decree also makes provision for er,suring the continuity of planning by making amendments in the Basic ~ Directions every five years. Accordingly, the USSR State Planning Committee - will elaborate control figures for the forthcoming five-year plan, broken . down by year, and will convey them to ministries and departments of the USSR, to councils of ministers of union republics and beyond to ass~riations, enterprises and or~~nizations that must draft five-year plans with due re~~3rd ~ to counter-plans and social competition c~mmitments. The USSR State Planning Committee uses these draft plans to draft a balanced state five-year plan. Thus the decree clearly defines the system of national economic planning; for the first time establishes planning horizons for 2Q, 10., 5 years and for ~ one year; formulates particular features of the plans for these periods; and ~ defines the procedure for drafting these plans. Five-year plans compiled on the basis of a system of scientifically substantiated technico-economic norms become the principal form of planning of economic and social develop- ment. The planning of construction and the enhancemen,t of the effectiveness of capital investments occupy an important place in the system of planning of the economic and social development of the USSR. The role of capital con- struction in the development of the socialist economy is exceedingly great. The country's national wealth (not counting land and timber~ is presently evaluated at more than two trillion rubles. The value of USSR fixed capital is in excess of 1.5 trillion rubles. This vast wealth was created by the - labor of the Soviet ~eople. The overall volume of capital investments in the Ninth Five-Year P1an and in four years of the Tenth Five-Year Plan alone amounted to almost one trillion rubles. Considering the fact that the national economy's fixed capital is roughly 30 times greater than in the initial years following the revolution, it is obvious that most of the ~ Sov~.et people's possessions were created and accumulated during the years of Soviet power. Morcover, this is not passive property but is production potential, i. e., is the prerequisite and basis of the further growth of - production and of the entire economy as a whole. But trie results of capital investments could be still greater. Analysis and calculations show that shortcomings in capital construction have impeded its devzlopment and have been the reason for the incomplete return on the vast sums invested in it. These shor~:comings have been repeatedly pointed out at pargy ccngresses and at plenums of the CPSU Central Committee. At the October (1976) Plenum of the C1'SU Central Committee, L. I. Brezhnev, focusing attention on several key problems, stated that "capital construction is one such problem and possibly the central problem... The orientation of the five-year plan is toward Lowering the volume of incomplete construction, towar'd reducing the time and cost of construction and installation work, and toward the more rapid reconstruction of existing capacities." In a speech , 2 s FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL liSE ONLY at th~ November (1978) Plenum of the CPSU Central Committee, L. I. Brezhnev criticized the situation in capital eonstruction. "We have not yet succeeded in halting the process of scattering capital investments over numerous con- struction projects. The volume of incomp.tete construction is on the rise. [1nin.~talled equi~ment costin~; several hilli~ns of rubl.es lies idle in tt~c warehouse. This point has been discussed i~ore than once. }3ut it is not evident that the USSR State Planning Committee, clients, and builders feel a sense of responsibility for freezing capital investments, equipment and materials." The share of incomplete construction has systematically increased in recent years. Vis-a-vis the annual volume of capital investment, it increased from 69 percent in 1965 to 75 percent in 1975 and 85 percent in 1978. The volume ~ of incomplete construction is particularly grsat in the case of productive - projects. Thus, in the power industry in 1978 it ~ras 127 percent of the - annual volume of capital investment; in the coal industry 140 percent; in ferrous metallurgy 131 percent; and in chemistry and petrochemistry 173 percent. ` The excessive volume of incomplete capital construction immobilizes almost two times more resources than are required for the activation of a year's projects. The construction time of various projects is normed according to type and capacity. These norms cannot be callf:d understated: they frequently significantly exceed the actual construction time of analagous projects in the USA and Japan. However, analysis of the data on numerous completed projects shows that only a few of them have been put into operation on ~ schedule, while the majority of them were~ activated with a greater or lesser lag time. The disrsption of the schedule for the ac:tivation of new capacities not only lowers thc effectivenes:~ of the construci:ion process proper, but also has ~3 negative impact on the economy as a whale. After all, the output that is supposed to be forthcoming from newly activated capacities is distributed beforehand in supply plans and capital is allocated for it; the shortfall in output from non-activated capacities complicates the normal operation of - the capital-holding enterprise and frustrates their plans, which is reflected in the economic activity of client enterprises. One of the major reasons for the delay in construction time is the scattering of capital investments among an excessively large number of construction projects. The party and the government have repeatedly indicated the need to halt the scattering of capital and to concentrate capital investments primarily on decisive, priority projects. Measures have been repeatedly taken to review and reduce the number of construction projects. However, the proper results are not obtained when nonreturnable state budget financing is the source of the capital investments and when the proper stability of the plans is not attained. Clients see their goal to lie in proving the need to include the projects they need in the plan. They use various, sometimes improper approaches to this end. For example, the estimated cost of proposed 3 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-44850R000200064416-6 i I FOR OFFICIAL USE ONLY - pr~jects is understated whereas the actual overrun is latFr discovercrd to be 1.5-2 times or even higher. New projects are includerl in th~ tit1~ list under the pretext that the necessary vol~ime of production would be impossible without them. New construction, not li.sted in the plan as such, is sometimes carried out under the guise of reconstruction. In order to halt the scattering of capital investments, the CPSU Central Committee and the USSR Council of Ministers have directed the USSR State Planning Committee, USSR ministries and departments, and councils of ministers of union republics to elaborate measures to accelerate the activation of production capacities at construction projects alr~ady in progress and to bring about a sharp reduction in the number of new construction projects so as to brir.d the volume of incomplete construction down to the established norms ir. the next few years. The decree's pronouncement on increasing the importance of the five-year plan and on ensuring its stability is very important. Considering the duration of production time, this pronouncempnt plays a special part where capital con- struction is concerned. The stability of the five-year plan permits the - confident planning of the work of const~~uction organization with an eye to commissioning the project on or ahead of schedule and the planning of the work of the customers for new products, for whom the time of receipt will be thoroughly realistic. Naturally the stability of the five-year plan of capital construction with targets bxoken down lay year presupposes the elimination or at any rate the maximum reduction of all manner of corrections - ahd revisions that undermine the stability and efficacy of the plans. The stable fi~e-year ~lan must be balanced with resources of materials, tech- nological and power generating equipment, with labor and financial resources, and with the capacities of construction and installation organizations. To date, insufficient proportionality has been one of the reasons for prolonging - construction time and fo.. increasing construction costs. The untimely supply of construction materials and components, the incomplete delivery of equipment "piecemeal," and the occasionally poor quality of - equipment greatly hinder the work of builders, disrupt its planned character, and decelerate the activation of completed construction projects, Interrup- ~ tions in the delivery of materi.als sometimes compel builders to use more expens.ive and higher quality materials metal, cement, slabs where lower quality materials could be used a.nd vice versa. All this leads to the over- expenditure of materials. Incomplete deliveries, the low quality and shortage of materials and equipment cause idle time and extend construction time and the time of installation, debugging and development of capacities. Interrup- tions in the supplying of construction are also reflected in the wages of construction workers and necessitate their tx~ansfer to other construction projects thereby disrupting the fulfillment of the plan still further. The "Sasic Directions of Development of the USSR National Economy Hetween _ 1976 and 1g80" adopted by the Twenty-fifth Congress of the CPSU call for 4 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY raisinp, the role and responsibility of enterprises of machine building rninistries in se;curing complete deliveries, of the install.er, and in bringin~; the equipment manufactured by them up to rated capacity. These tasks also confront organizations in the material-technical supply system. 'Che new decree indicates ~ higher measure o:E~ responsibility on the part of suppliers for the nonfulfillment of delivery plans, which will be taken into account in the evaluation of their economic performance. Sanctions must be invoked for the violation of delivery contracts. In order to facilitate the delivery of complete equipment packages, the decree envisages the use of credit: bank credit is offered to the general supplier of equipment ~ prior to the expiration of the planned date for completing the delivery of the entire equipment package or for its installation. When the planned peri~d expires, the crediting continues but higher interest is charged for the use of the loan. ~ Lag in construction work and interruptions in the delive~~y and installation of equipment packages result in the formation of large equipment inventories in the warehouses. At the same time, millions of square meters of production space are vacant. The implementation of ineasures indicated in the decree will make it possible to eliminate these disproportions. The coordination of the construction volume planned for every construction organization with its capacities is an important condition to striking a balance. To this end, it is necessary first and foremost to determine the capacities of each construction org~nization. The decree envisages the compilation of 'passports' for each production association or enterprise in 1979 and 1980 and their subsequent updating. The passports must contain data on the availability and use of production capacities, on the organiz- ational and technical level and other technico-economic indicators required for drafting five-year and one-year plans. Such passports on construction organizations will provide the complete picture of the capacity of each of them. Accordingly, it is essential to plan the work volume for a five-year and one, year period based on the decree's pronouncement that plans must be compiled on the basis of economic and engineering calculations. At the same time, we must not permit the establish.ment of plan targets for subordinate con- struction organizations solely on the basis of the existing dynamics of the corresponding indicators, i. e., on the basis of the "status quo." The decree's pronouncement that existing production and new cotistruction must be planned as a single whole holda great significance for securing the proportionality of capital construction plans. In this regard, the five-year plans will allocate capital investments for the development of branc,'~es of material production to perform the planned volume of production and services. This ensures the creation of new capacities in branch.es of material production in a volume necessary for the solution of problems posed in the five year plans and envisages an increase in th.e volume of production in particular in accordance with the requirements of construction proper. 5 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY The decree obligates USSR ministries and agencies and councils of ministers of union republics to draw up balances and make calculations of the use of production capacities and fixed capital ,ss part of the drafts of five-year ; plans 3nd also to draw up summary plans of r.econstruction ~~nd technic~~.l rr.l-oolin~* ~C exi:;~iny~, ~~nterprises inter ,ili,3 ,3t the ~~x~~enr,~~ ~f I:h~~ ~~rucJiu�I.ic~n ~1eve.l.oPment Eund. The compilation of sur.h balances will m~lkr~ LC 1~UJJ1.~~~ to elicit reserves of production capacities and to provide a technico-economic _ substantiation of the reconstruction of existing enterprises for which there 4 ; is a real need. , The use of the production development fund for the reconstruction of entci~- prises was rrequently impeded by this fund's lack of the appropriate material resources and the lack of the necessary capacities. Now, according to the decree, the plans must give top priority to the allocation of material resources and equipment to associa~ions and enterprises for reconstructiun and technical retooling and must also assign limits to capital investments, to construction-installation and contractcr-performed work. This ensures the use of the development fund for the needs of capital construction in the interest of reconstruction and technical retooli,ng and will thereby bring one of the economic incentives for increasing the effectiveness of � production into play. The existence of balances of production capacities and plans for the rr:~constrtiction oF existi.n~; enterprises F~rovides a re~31 opPortunity for ~ placing new construction in a fz~amework corresponding to the real. needs of ~ the national economy. The decrea envisages the allocation of funds for the construction of new enterprises anci for the expansion of existing enter- prises only if the requirement for given output cannot be provided through - the reconstruction and technical retooling of existing enterprises. This will make it possible to limit new construction that is extensive, to concentrate capital investments on a lesser number of projects, to place major emphasis on the usE of new equipment, on increasing the effectiveness of production, and on its intensification. The decree charges the USSR State Committee for Construction Affairs with , responsibility for pursuing a unified technical policy in construction, for ' improving planning estimates, for improving the quality of project-planning, for preparing measures to reduce construction costs, for improving city planning norms, and for improving the architectural appearaiice of population centers. The USSR State Planning Committee will ratify five-year plans for project- � planning and surveying operations and the performers of these operations. In order to attain greater maneuverability, the plans and estimates will be only for the first st a ge of an enterprise when constriiction takes longer than two years. But the project will be based on the master plan of development of the enterprise. Subsequent stages will be designed con- currently with the construction of the first stage. 6 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY The new system of indicators for evaluating the work of constxuction workexs is of p,~reat importance. Up until now, their work has been evaluated on the basis of the fulfillment of the capital investment plan, i. e., essentially on the basis of the expenditure of capital. This has determined the size of thc wa~e fund and the m3terial incentive fund. Capital investmenl- ~~lans wcre ~ulf'illed, resourc:es were "assimilated," but th~ ~zctivati.on [oC r.~~ipac- ities] lagged significantly behind the plan (by 20-30 or more percent for certain branches). The orientation toward gross indicators has led to an increase in the interest of construction organizations in the use of costlier materials and com;~onents and in their red~stribution, to the division of projects into "profitable" and "unprofitable" projects, and fin~lly to a.tl. manner of exaggeration of report data. The decree specifies a list of indicators that are ratified in the five-year and one-year plans assigned to construction ministries and construction- installation organizations. The principal indicator among them is the a~tiv- ation of production capacities and projects, i. e., the final product of construction. The list of indicators also inclu3es: the volume of comme~cial construction output with a breakdown of general volume by client; the growth of labor productivity; the maximum number of workers and employees; profit (for individual organizations reduction of the prime cost of construction and installation work); targets for the in~troduction of new technology; and the volume of delivery of materials, machinery, mechanisms, and other resources required for the fulfillment of the plan. The evaluation of the economic activity of construction and installation organizations and their economic stimulation will be based on the results of _ the fulfillment of targets, on the activation of production capacities and projects, on the volume of commercial output of the construction industry, and on the growth of the productivity of labor arid profit. This creates new sti~nuli in the work of construction and installation organizations and leads to the abandonment of the orientation toward the "assimilation of capital" and the notorious "gross." The most important indicator is the commissioning of completed projects. At the same time, the fewer material resources and the less manpower expended, the ~reater wil.l the profit of an organization be. ~ Thus, the higher the evaluation of ifis performance, the higher will the , ecor~omic incentive funds be. ! _ The introduction of the new system of evaluati~n calls for the.transition ; to the practice of settl~ng accounts between clients and contractors for ~ entirely completed enterp~~ises, fer individual complexes, for capacities ~ ready to produce goods and render services on the basis of the estimated cost - of commercial c~nstruction output already in the yEar 1969. Such a procedure ~ is analagous to the payment procedure used in industry and in other branches ' of material production (where money is paid after the product is produced i_ and received) and stimulates the speediest conclusion of construation ~ projects. Advance payments by clients to contractors for the purpose of ~ defraying the expenses of the latter are forbidden until the project is ~ completed. These expenses are defrayec~ by bank credits pending the deadline for commissioning a given construction projec~ from the clients' disposable ~ ~ 7 ( i FOR OFFICIAL USE ONLY j- ~ ~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY funds. Subsequent credit is granted if necessary, but at a higher interest rate. This will encourage the r_ommissionin~ of projects on schediile or ahead oF sche~iile. It is ~roPosc~ci that accounts betw~en clients and project-pl~~n- ning ancl survey.in~; organizations be settled in .similar f~~shior~. Paymcnl- is made for projects that are entirely completed and accepted by the cl.ient: ~ the expenses of project-planning organization prior to the commissionin~; of completed projects are defrayed by their working capital and by bank credit also on the basis of the clients' disposable funds in connection with thn settlement of accounts withost intermediate payments. Al1 this will have a stimulafiing influence on project-planning organizations and will compel them t~ completP project plans of higher quality oii schedule. - Credit will a~~o play a greater part in connection witn the fact that the decree envisages the expedience for individual branches to finance construc- ~ tion projects from credit granted by the USSR All-Union Bank for Financing Capital Investments [Stroybank SSSR] to construction and installation contrac- tors in the full sum of construction costs in accordance with the estimate accepted by the contractor and the agreement to turn the project over to the client in completely ready-to-use form. At the present time it is essential t~ enhance the role of long-term credits in the financin~ of capital construction at least, to double its share in the next few years. The use of credit increases the responsibility of both contractors and clients. Unlike budget financing, credit must be repaid. When credit is used, it is necessary to substantiate the expedience of expenditures and to secure their effectiveness. In order to ensure the lack of interruption in capital construction plans and to increase th e responsibility of clients and contractors for the ~ activation of capacities and projects on schedule, the decree envisages the elaboration and ratification of lists of enterprises undergoing reconstruction or slated for reconstiruction in five-year plans and the compilation of title lists of construction projects. They must become a stable planning document that is binding for clients and contractors; for pla~ning, finance, bank and supply agencies; for suppliers of equipment and components not only for a year but for the entir.e period of construction. The one-year capital construction plans will include only construction projects for which project-planning and estimate documentation and blue- prints for a year of work are available by the first ~f July of th e preceding year. Ministries producing technological and power equipment must receive orders for the delivery of equipment for the entire period of construction, and must receive orders for at least two years for the delivery of inetal structural components. - A number of ineasures are envisaged for the expansion of work on the technical retooling and reconstruction of existing enterprises. They include the right of managers of production associations and enterprises to ratify title lists for the technical retooling of enterprises irrespective of the overall estimated cost of the work in accordance with their estabiished limits on capital 8 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040240060016-6 ~ FOR OFFICIAL USE ONLY investments and construction-installation work and material stocks. Managers ~ire also entitled to establish bonuses for personnel meeting targets for _ _ the technical retooling of existing enterprises and to raise wages in construction-installation organizations in whose plan the volume of work on t~~chn ic~~l retool ing ~~nd r~~construction of existin~; enrerPrir;es .i;; ~i0 ~~~~r~.cnl or more. The Al~-Union State Bank for Financing Capital Investments (Stroybank) and _ the USSR State Bank (Gosbank) are instructed to finance state capital invest- ments in productive construc~ion projects continuously on the basis of title - lists for the entire period of construction within the sums ratified in the estimate. It is permitted to grar,t clients credit to pay for major technological and power equipment of domestic manufacture for productive facilities before the equipment is installed and to continue to grant credit ~ ~ upon the expiration of the equipment installation de~dline but for a higher - interest rate. This procedure creates the stability of financing of - construction projects. The same procedure is also extended to the settlement of accounts for the delivery of equipment packages. In such a case, the client pays the e~neral supplier in full for the delivered and in~talled equipment package. The general supplier receives bank credit pending the - delivery and installation of the entire equipment package. Credit continues after the deadline but the intere~t rate is higher. ` The decree calls for higher bonuses for the timely activation oF production capacities and Facilities in the average amount of up to ttiree percent of the Estimated cost of constructioa and installation work performed. - According to regulations on awarding bonuses for putting completecl projects into operatian (regulations ratified by the USSR State Committee for Labor - and Social Problems, the USSR State Committee for Construction Affairs, - and the All-Union Central Council of Trade Unions), bonuses are paid with regard to the quality of the work for the activation of projecl-s on schedule: bonuses are increased by 10 percent for a rating of "excellent"; there is no increase in bonuses for a rating of "good"; and bonuses are reduced by 20 percent for a rating of "satisfactory." When the activation tirne is reduced by at least 30 percent, the tatal bcnus is raised by 50 percent; when the activation time is reduced by 20 percent, the bonus is ~~aised by 25 percent; and when the activation time is reduced by 10 percent, the bonu~ is raised by 10 percent. When a project is put into operation ahead of schedule, the ge;ieral contractor receives fror,~ the client 50 percent of the projected profit for the reduced period of construction but not more than 0.5 percent of the estimated cost of construction-installation work for each month of reduction in construction time. These .funds are channeled into the economic incentive fund of organizations involved in the construction. Provision is made for the distribution of the profit realized by the general contractor betwePn subcontractors, proje~t-planning and other organizations responsible for the reduction of construction time and for the devel~pment of production. This profit is used for sociocultural measures and housing construction and for the payment of bor,ases to managerial, engineering- technical personnel, and employees and to woi�kers and brigade leaders who have distinguished themselves in the amount of up to 1, 1.5, 2, and 3 times their salaries or basic wage sc91e::. FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02108: CIA-RDP82-00850R000200060016-6 ~ FOR OFFICIAL USE ONLY The F:].eventh Five-Year Plan calls for making the txansition to the planning of labor productivity in construction-installation organizations on t-he basis _ of normative net output or another indicator that reflects changes in "l~bor inputs n~ore precisely. The wage fund will be planned on the basis of ruble~~' _ worth o~' commodity output on the basis of the indicator that is used for the - pl~inriin~; of labor productivity. The USSR State Committee for Construction - Affairs in conjunction with the construction mini.stries mtist prepare the norms and estim~~~es base to this end. The transition to the settlement of accounts on the basis of net output i~: also envisaged in industry. Construction ministries of the USSR and councils of ministries of union republics are instructed to implPment measures to improve the managemen-t of capital construction and to adopt a two-three element system of management - between 1979 ~nd 1981. These measures hold great importance f~r constr~iction: the present system of construction management is complex and un~aieldy. It includes four and even five elements and the simplificaticn of the system of management will increase the effectiveness of construction. Cost accounting principles will undergo further development in construction- installation organizations a~ well as in production associati.ons and at _ enterprises. Cost accounting is based on five-year plan targets and on long-term economic norms that guarantee an increase in resources that are left - at the disposal of cost-accounting organizations depending on improvements in the final resul.ts of their activity coupled with a simultaneous increase in deductions paid into the state budget. Provision is made for the evalu- ~ ation of t~ie results of economic activity to fiulfill product delivery plans (includin~; c~nstruction output) in accordance with contracts, to increase labor productivity, to improve product quality, and to increase profits. E~onomic incentive funds will be formed on the basis of sfiable norms: the hipher the profits, the larger the incentive funds. Ministries and agencies establish a unified fund for th~ development of science and technology for ,.he compensation of expenditures associated with the elaboration and development of new types of products and technological processes, with the improvement of product quality, and with higher expend- itures during the first years of production of new products. This innovation holds great significance for industry and will also be a stimulus to the introduction of new technology in construction as well. The pronouncement regarding the el.aboration and implementation of ineasures _ for the broad development of the brigade form of organization of labor, cons- idering the fact that is must become basic in the Eleventh Five-Year Plan, is especially important for the organization of labor and wages. Collectives ~ (councils) of brigades are authorized to determine the size of bonuses and wages on the basis of the actual contribution of each brigade member to the general results and other types of material encourageme.nt, All this _ emphasizes `he significance of the development of the brigade contract method = and of other progr�essive forms of labor in co;_struction. The successful use of this method and these forms depends in larger measure on the rhythmic operation of the entire construction-installation organization and, in particular, on the lack of interruption in supply. ZO FOR OFFICIAL LTSE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007102/08: CIA-RDP82-00850R000200060016-6 i FOR ~JFFICIAL USE ONLY The decree should be the basis for the elaboration of normative acts on the implementation of ineasures indicated in the decree, including measures in capital construction (some of th.em have already been ratified and published). The decree of the CPSU Central Committee and the USSR Council of Ministers opens up broad opportunities before all workers in the construction industry complex to raise thz level of all work, to eliminate existing shortcomings, to increase the effectiveness of construction production and labor productiv- _ ity, arid to accelerate scientific and techni.cal progress in construction and in the entire national economy. - COPYRIGHT; Izdatel'stvo "Pravda", "Voprosy Ekonomiki", 1979 5013 . CSO: 1821 . ! ; i� _ ; . ~ 11 - _ FOR OFFICIAL USE ONLY ~ Y~ a:~;3 fi:~4~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007102/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY METALWORKING EQUIPMENT iJDC 658.512.6:658.52.011.56:621.9.06-529 OPTIMIZING AUTOMAT ED MACHINE-TOOL SECTIONS ' Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 3-5 [Article by M. Kh. Blekherman: "Optimization of Equipment Load of Au~omated Sections Consisting of Machine Tools with Individual Control Panels"] - [Text] The creation of comprehensively automated sections of machine _ tools with individual control panels (ChPU) controlled by computer is a ~ promising trend for increasing labor productivity and efficiency of utilization of equipment in small-serial and unitary production. In this article are described the principles of equipment load optimization in the system of on-line industrial planning (SOPP) for automated sections of machine tools with ChPU for treatment of parts such as solids of rotation (type ASV sections). The SOPP was elaborated at ENIMS (Experimental _ Scientific Research Institute of Metal-Cutting Machine Tools) and was realized on the M-6000 electronic computer (with 32 kbyte working storage - and one floppy disk file) . The first pP~ase of the system (SOPP-1) has been in industrial operation since 1.977 at ti~e ASV-20 section (Stanko- , konstruktsiya plant of ENIMS); the secc~nd phase of the system (SOPP-2) is _ being put into operation et the ASV-21 section (Sasovsk Plant of Automated - Lines). Machine tools with ChPU (as compared to all-purpose machine tools of the _ same technological designation) have high productivity and cost, and therefore the maximum intensification of their load is so important. Several theoretically new possibilities in this direction have been revealed by comprehensive automation of produ~:tion in type ASV sections because of the presence in the section of a control computer, unified transport and storage system (TNS), automated systems of technological preparation of production (TPP) and the SOPP. Within the SOPP, in- tensification of loads of machine tools with ChPU is achieved by reducing down time for technical organization and preparation and finishing time. Aspects Of The Planning Object And Interaction With The Planned Production Control Division (PDO) Or Automated Production Control System (ASUP) Type ASV sections are designed to acc~mplish lathe, milling and drilling operations in the manufacture of parts of the solids of rotation type and 12 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 I FOR OFFICIAL USE ONLY consist of several technical machine tool groups (TGS). Each TGS combines ' machine tools of the same model and modification, designed to perform identical technological operations. Within a TGS, all machine tools are completely interchangeable. For example, the ASV-Z1 section consists of three TGS: lathe (six model 1725MF3's), drill-milling machines (three models MA2235MF4's) and a centering-milling machine (model MR021F4). The SOPP is adjusted to a specific equipment make-up according to tables. Up to 30 machine tools of different TGS can be simulatneously connected to the SOPP. Let us examine the ASV-20 to illustrate several characteristics of the ASV type section load. The average size of a start-up run (in 1978 figures) is 19 items: 52 percent of the run contains no more than five parts per item. The average treatment time per run in a single control program (UP) for lathe operations is T~P = 8.5 minutes. The annual inventory of rotary parts comprises more than 1200 items. An average of 50-60 items are simultaneously being produced. Therefore, the ASV type section is a multi-item small-serial production ~ line with short treatment cycle. Typical features of such production (because of the diversity and complexity of industrial connections) are: 1) raising the requirement for efficiency and coordination of activities of all section and plant services; 2) the large number of unpredictable deviations from production schedule, leading to equipment down time for organizational and technical reasons. 5ome of these deviations (retraining of groduction because of design changes of treated articles or tretment technology; untimely delivery of billets, fittings and cutter; delay in performance of subcontracted work) are typical for most small-serial productions; some deviations (errors in iJP, need to retrain UP for significant deviations in billet dimensions) are specific to equipment with ChPU. The k~reakdown of equipment also leads to unpredictable deviations from the section's work schedule. Elimination of causes of unpredictable deviations requires the performance of a set of measures aimed at improving short-term planning, improvement of pre- paration of production and enhancement of equipment reliability. In addition to coordinating section service work, section stability in the fact of unpredictable deviations from the production schedule is of primary importance (i.e., distribution of resources and planning con- ditic+ns so that equipment down time for organizational and technical reasons due to random deviations is at a minimum). Work planning of automated sections oi: the ASV type is done at two levels: the level of long-term (monthly, biweekly) volume planning of section work as a whole, done by the PDO or ASUP within the entire plant; and the level of short-term (shift, half-shift) planning of work of specific units of - equipment and section services, done by the SOPP. This organizatian of planning is governed by the fact that within the ASUP it is almost impossible to consider on-going changes in the manufacturing situation typical of small-serial production in a thorough and efficient manner. 13 FOR O~FICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 ~ rux urrl~;t[~. U5~ UNLY Intervention of PDO or ASUP in the work of SOPP is only permitted when the monthly production program is corrected or the initial orders are changed. Shortening Equipment Down Time for Organizational and Technical Causes The basic means of shortening equipment down ti~ne for organizational and technical causes within the section SOPP have been determined from operating experience of automated sections. 1. Comprehensive solution of production control problems. In ordinary producti.on lines, the load of machine tools is planned on the basis of technological routing. Work planning of automated sections is done in SOPP on the basi~ of a comprehensive examination of the entire manufacturing cycle of the order path through the section [1]. The manufacturing cycle of order path consists of two stages (see table): preparation of production (opening the order and listing parts, UP, fittings and cutter) and the execution of the order per se (from start-up of the listed order to sealing of the order and shipping the ready product to the customer). The first stage in the manufacturing cycle is standard for all orders, while the second stage is automatically shaped on the basis of the technological route. The technological route, UP and standard and adjustment data for each UP (so-called UP tags) are elaborated in the TPP system and are transmitted to the section via punched tape. The manufacturing cycle contains the following operation groups: 1) metal working operations carried out in the section (with breakdown according to installation of parts); 2) subcontract operations after which the parts - must be returned for further treatment in the shop; 3) TPP operations; 4) receipt of fittings and cutters stored outside the section; 4) technical - monitoring operations; 6) dispatcher operations. TPP operation is plannPd once in the SOPP (with first start-up of a given item). With repeated start-ups, the SOPP automatically considers this _ operation to be executed (except for cases of change in billet size or treatment technology). Operations of billet delivery and subcontract work are included in the manufacturing cycle of order path in the section to organize a closed accounting system that identifies possible disturbances in section work rhythm caused by disruption in billet delivery time and - subcontract performance. In the SOPP, the performance of these operations is not planned, only monitored. Thus, the entire manufact~�cing cycle of order routing is reduced to the performance of a preset sequence of operations. A shift from the technological path to the manufacturing cycle of order routing enables us to plan the work not only of machine tools within SOPP, but also TPP services, technical monitoring, c.tters and dispatcher work. In addition, 14 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 \ FOR OFFICIAL USE ONLY Manufacturing Cycle of Order Transit in Section of the ASV t e(Formalized Exam le) Cycle stages Groups of operations preparation of opening of order in the section production receipt of billets technolo ical re aration of roduction execution of loading in TNS order preliminary lathing, first unit* prelminary lathing, second unit* technical monitoring forwarded f~r subcontracting subcontracted heat treatment* - loading in TNS final lathing, first unit* final lathing, second unit* drilling-milling work, first unit* technical monitoring _ sealing order and shipping ready product to customer *Operations appearing on the technological path of an item elaborated in the TPP system based on data contained in UP labels, the SOPP plans the operations of the cutter service for cutter alignment and fitting out. The SOPP interaction chart is illustrated in the figure. Metal working operations are automatically standardized in SOPP based on the values of TuP and T~ (manual auxiliary time) contained in the UP labels. An important role in reducing equipment down time for organizational and technical causes is played by on-line reporting to section and plant services on the current status of production. In this connection, SOPP (in addition to output of reports) on request of the appropriate services displays reference data (disruption of deliveries of billets, current work load, etc). 2. Increasing Efficiency of Control Reactions. If there is a significant number of deivations from the production schedule, it is necessary to achieve maximum speec] of feedback, i.e., to reduce the time interval between the moment of change in the manufacturing situation and the change in the appropriate planned assignme~t. This requirment is most fully satisfied by the conditions of continuous (dynamic) planning in which the :~ext line item of the planned assignment is determined and is reported to the working area only after receipt of data on the performance or non-performance of the preceeding assignment line item. 15 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 . 1'VL\ ~/CL'1V1HL UJ~ UNLY Q ~ Z ~ 1~ S DI 1f 4 1 10 5 - _ ~ 9 6 IP a ~ Y ~ Interaction of SOPP with Plant and Section Subdivisions and Services: I--SOPP; II--PDO or ASUP; III--TPP service; IV--technical montiroing; V-- section chief; VII-cutter service; VII--dispatcher service; 1--section manufacturing program, additions and corrections to program, change in initial data on orders (run size, time, etc.); 2--reports, d.ata on current - status of production (current status or orders, volume of insurance reserves, shortage in order parts list); 3--assignments for technological preparation of rpoduction and Ui~ error corrections, data on current status of technological data bank; 4--technological routing and labeling of UP prepared according to assignments; 5--assignments for conduct of technical monitoring operations; 6--data on results of operations of technica_ monitora.ng; 7--assignments for machine tools of section, data on current status of production, reports; 8--data on results of execution of assignments for machine tools, removal of residue at end of half shift and status of work areas; 9--assignments for receipt of cutter and fittings, assignments for alignment of cutter and fittings; 10--data on receipt of cutter and fittings; 11--assignments for dispatcher operations (loading in TNS, sending out ~or subcontract work and sealing orders); 12--data on results of dispatcher operations, data on receipt of billets and half- finished products (from subcontractors). The choice of the current line item of the assignment is done on the basis of the entire set of data stored in the system at the time of inquiry. But realization of these conditions is complicated by several organizational - and technical problems. In this context, when SOPP programming in- structions are developed, it is provided that the system can operate under both continuous and session planning conditions. The most natural interval of planning is the half shift (planning sessions are done between shifts and during the lunch break). Planned assignments for the next half shift are elaborated on the basis of information on the status of production at the end of the preeceeding half shift. Data during 16 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 ~ FOR OFFICIAL USE ONLY the half shift are stored on pap~_r, usually the planned assignment blanks. Information is put into the SOPP at the start of the planing session. Only data on changes in the current status of orders and equipment are put in; the bulk of the data is stored on the floppy disk. The SOPP is serviced by one operator per shif`. The need for highly efficient data processing in continuous and half shift planning required the creation of a special system of information processinq [2]. Input and monitoring of data for the preceeding half - shift, correction of data banks, calculations and print out of planned assignments for the next half shift take no more than 30 minutes in all. As operating experience with the ASV-20 shows, conditions of half shift planning provide, in most cases, the necessary efficiency of readjustment and adaptation of production in conformity with current manufacturing conditions. According to the nature of production, SOPP can be aligned to conditions of shift and daily planing. 3. Localization of deviations from the production schedule. In addition to introducing on-line feedback, SOPP stability is also increased by using additional constraints which localize the consequences of random de- viations. The essence of these constraints consists in a distribution of resources so that the performance of the planned assignment at one work , site in a given planning interval (half shift) is independent of the performance or lack thereof at other work sites. Thus, the planned assi~nment for a machine tool only contains orders (or parts of orders) which are completely ready for execution of operations of the appropriate TGS at the time of planning. During the interval of planning, parts can not be moved from machine tool to machine tool, even if the machine tools are completely interchangeable. This guarantees local I indepedendence oi machine tool loads, i.e., the operation of one machine L tool does not affect (during the planning interval) the operation of other machine tools. If the order is placed in several containers, these constraints are related only to each part in its individual container, not to the entire ~rder. Localization of discrepancies can be used only with small planning _ intervals and ensures more s~able and efficient machine loads. 4. Increase in the Number of Degrees of Freedom in Solving Optimization Problems. One of the basic constraints in solving optimization problems of equipment loading is the planned periods of order output. If the planned periods are uniformly distributed throughout the month, under conditions of multi-item production the criterion of minimization of disruption of these periods is very rigid and almost unambiguously determines the sequence of order processing on the machine tools [3]. By establishing the sequence of treatment in this way, it may involve~the inefficient use of equipment and significant down time for organizational and technical reasons. 17 FOR OFFICIAL USE ONLY - ~ ' APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 I r~n Vrrl~lrw u~~ UNLY Analysis of multi-item small-scale production shows that in most cases, the required accuracy of observance of planned periods of order delivery _ does not exceed two or three days. Thus in the SOPP, all orders are grouped according to three priorities of fulfillment ("normal", "urgent", "emer- gency") ; this permitted a shift from a more than 20-level system (according to the number of working days/month) of priorities to a three-level system. Within the level, all orders are considered equally urgent. The priority level is designated upon opening of the order and be changed on-line by technical and engineering workers of the section and plant during completion of the order (not only the entire order, but also each part - placed in a separate container) . Fulfillment of ari order of lower prioriLy is permitted only after fulfillment of all orders of high priorities. To eaualize random deivations from the production schedule and optimize macine tool load in the ASV-type section, insurance work reserves are envisaged for each TGS (for 2-3 shifts). Data on current volume of insurance work reserves are automatically prepared in the SOPP. In addition, insurance work reserves are introduced into each half-shift assignment per machine tool. Reduction of Prepara'cion and Finisliing Time (Tp_Z) One basic obstacle to efficient use of machine tools with ChPU in small-scale and unitary production is the relative large portion of T_Z in overall resources of machine tool time. The relative significance o~ Tp_Z is reduced in SOPP by minimizing re-adjustments of machine tools. Under conditions of small-scale production, machine tool load is usually planned by operations (without dividing into installations). At the same time, re-installations within an operation in sc~me instances are related to significant re-adjustment of the machine tool. The presence of unified TGS of the section, ,~:~ich ensures efficient feed of items to any work position, permits a shift from planning of operation fulfillment to planning of installation fulfillment. The planning unit of the SOPP is fulfillment of one UP (i.e., one installation) for a part of an order situated in a single container. Therefore, SOPP permits fulfillment of two installations in one operation with a discontinuity in time at various machine ;:ool positions. The sequence of planning units for each machine tool (planned assignment per machine tool) is established using the type optimization method [4], which represents a modification of the method of group treatment in short-term planning and is designed for the high intensity of unpre- dictable deviations from production schedule. The type optimization method is high speed: calculation of the half-shift - assignment for TGS of four machine tools (with order portfolio of 100 planning units) takes about 2.5 minutes. - 18 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY Introduction of SOPP in the ASV-20 section reduced to almost 1/2 the down time of equipment for organizational and technical causes and to almost 1/2 the machine tool adjustment time. References 1. l3lekhermar~, M. Kh., Kardanskiy, L.L�. and Margolin, M.D., "Urqaniza- tion of technical reference libraries in OPP systems for automated sections of machine tools with ChPU", in: Tsentralizovannoye uprav- leniye oborudovaniyem ot EVM i podgotovka upravlyayushchikh programm (Sb. trudov)[Centralized computer control of equipment and pre- paration of control software (Proceedings)], Moscow, ENIMS, 1976. 2. Blekherman, M. Kh., Mikhaylovskiy, M.A. and Yakunin, M.A., "Software systems for section control of machine tools with ChPU", STANKI I INSTRUMENT, 1978 No 9. 3. Conway, R.W., Maxwell, W.L., Miller, L.W, Teoriya raspisaniy [Theory of Schedules), Moscow, Nauka, 1975. 4. Blekherman, M. Kh., Grachev, L.N., Margolin, M. D. and Chistyakov, V.M., "Minimization of re-adjustment time in systems of on-line production planning for automated sections of machine tools with ChPU", Oborudovaniye s chislovym programmnym upravleniye [Equipment w.ith numerical software control), Scientific-Technical Abstracts, (NIimash), 1978, issue 4. COPYRIGHT: Izdatel'stvo Mashinostroyeniye~ STANKI I INSTRUMENT, 1979 8617 CS0:1821 19 FOR OFFICIAL USE ONLY - APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 rux urrll:lt~1. US~; UNLY METALWORKING EQUIPMENT UDC 621.9.06-112+[658.527:621.9.06-52] STANDARDIZED SUBASSEMBLIFS OF MACHINE TOOLS - Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 14-17 [Article by L. S. Bron: "Unified Range of Standardized Subassemblies of Modular Machine Tools and Automated Lines"] [Text] Automated lines (AL) and modular machine tools (AS) are the most productive equipment for multiple arbor mechanical treatment of chassis parts under conditions of large-scale and mass production. A distinctive feature of AL and AS is that they are composed of separate standardized , (normalized) subassemblies and parts, which reduces periods of planning and manufacture, reduces cost and raises the quality of this equipment. In th~ Minstankoprom system, modular machine tools (using normalized - subassemblies in their manufacture) have been manufactured since the early 1950s by the Moscow Machine Tool Construction Pant imeni Sergo Ordzhoni- kidze (according to designs of Moscow Special Design Bureau of Automated Lines and Modular Machine Tools, the Minsk Plant of Automated Lines (according to designs of Minsk Special Design Bureau of Automated Lines) and the Kharkov Plant of Mod ular Machine Taols (according to designs of the Kharkov Speicl Desigi. Bureau of Modular Machine Tools). Individual normalized subassemblies were manufactured by the Glukhovskiy Plant of Modular Subassemblies (accordinq to designs of Kharkov Special Design Bureau of Modular Machine Tools), Gomel'skiy Plant of Machine Tool Subassemblies (according to designs of Minsk Special Design Brueau of Automated Lines), the Moscow Stankoagregat Plant, and the Moscow Plant of Special Machine Tools Spetsstanok (according to designs of the Moscow Special Design Bureau of Automated Lines and Modular Machine Tools). Subassemblies manufactured according to the designs of the three en- umerated special design bureaus were normalized only for the corresponding manufacturer; consequently it was not possible to arrange their cen- tralized production for use in machine tool designs and automated lines manufactured by other plants. , With the growth of machinery of large-scale and mass production (auto- ~ mobiles, tractors, agricultural machinery, etc.), the need increased for ' metal cutting equipment to manufacture the most complex chassis parts of 20 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 ~ FOR OFFICIAL USE ONLY ~ o, U ~ o�~ v v 3 v sve u ~ t O 1 ?i ~ ~ v O ~ ~ ~ w ~ 7 N G1 ~ ~ ~ ~ ~ .u n�, ~ " ro v~"i a' ~ rt1 �n A ~ ~ UJ .7 ~-~I ~�U~l N W U O ~ 'i C J.~ v I G) W C~ N�rl �.~1 .FI ~ N W ~ n, w .n a b ~ ~ c o n E ~ 1~ ~ dP y~ N VJ 1.~ O dP N U�.[~I rtJ U~ � ~ ro b ~ N u~ w a, u~ u, N 4 tn N N .0 C U L+ O~ tn ( R1 0 C 0 C Gl o~ u.~ Q N U .a ~ ~ O +~i ~ R7 C ~ ~ ~ N rl �.1 'C7 V N .C N W 'O GJ �r1 ~.1 ~ 7 O~ C i0 1~ 3.~ 1.r td �.-i W H.n U?~ 0,~ ~ rtl �~-1 N �.~1 ~-1 . U Gl C dP u UI ~ N'O N m o u� oo~w~~N.~~,a c~nw.`�u�~'`-' ~a,~na, ~ C ~~-rol N N~ ua RS C O - ri W Q 'Jt N W~ L~'i C1 Cl N�~ 'J .,-1 UJ ~ 1-~ ,7 ~ > V~ 1~ N 0'O Cl i0 (n CJ ul W�v1 ~ N �d v ~ V.,a ~ - 'o~~�~+~a'a?aroi~�~ ~o~cro~orow ~Hc~i�~ a o.~ .a+ c i� ~n v~ Q ~ o~; N x N�.~ a~ ro~ a, u~ u ~tJ C O ~ croiacaroiaNi"~rs,wGi~m "~A'w ~.S~y~'�N~ ;~~a~i.n 'C7 O?-~ U'O tn O v R+ N dP u1 p ~~-1 u-~ .c ro i "w u�1i~ v�~ O~,'~~�n,~ y ?ro+ ro.�`-� croY a~~ m~o ro o GJ U u rt1 'C7 U GUi cI1 a~i 0 ~ v b b v.C 3+~ o b u~i N O'~ 7 U.~7C ro�~ ~ CT O~ 1~ Q 4�.1 UI 4 1~ i.~ N 1J O N 1~ N dl O~0 U.. ~ (0 ��.1 C~ T l sa r- 1 C'D C N 3~' ~ w r-roi N ~ U ~ v�.~ v U~�.~ y�~ s~ w�.~ ~ o U ro'~ .i w~ v c v m ca,v4roo~a, ro.c~ �J~~bvc.c~~~crn .a~ N+-~ a ~n o~ cn v~ ro~o o+ c v~ c~~ rn a~�i v~ ~ c�1n aroi v~ ~ w ~o a+ a, s�?+ a ro�.~ ,o a rts ~ b u~o ~n ~o ~v i ao a N rn ~n ~ cn ro a ~ a, o a~ ~ b n,ro ror�~�~ c'~iri'-�1i~v~ o N A+~i u~~w~, a~ v~ ro p s~ ~boo?~~aaa UUa~ av N v M ~ M c1' ~-I C N j j~ v :c �J ~ + + i ~�~o A V ~ I H ~ ~ ~ ~ C) N V f~ t~ ~ N ~'~1 N I N N ,aj ~p pp M~ ~ N f.i ~ vv rn~rn i~c ~ ul ~1 r-I N�~-~i r-~1 N A Y b~ N C.[ U~1 t~ C.C W r-I �~-1 .~-I N sa N �~-i 1~ W v �.~I .L~ (n r~o o c~a ro~ A~ 3 ~ A~i 3 ro O b~; ~~~~a H ~ ro ro � u .a.+ a w a ro ~ .c ~ :c ~n . . . ~ , m ~ s~ ~ b i a~i w a~i ~b a .C ~ Y .~e .x ~ .Y .G - ~ O ~ O ~ b ' 3 s.~ 'O 3 ~ N U O~ ~ ~ ~ O ~ ~ C~ 7 H 0~r O~ 0 W C .C .C ,C \.C C I 0 a~n aa~ ~nw.ca~nw~~o ~~oau3u�.~ ~ x v aNi ~ I M M ~ N F~'- ~ U] ~ ~ ~ M lf1 lf1 ~O t0 ln ~ M U1 ~ ~ ~ ~ ~ ro R3 'O O~ r-1 Cr G) I N s.i G1 ~ ~ a1 ..,..i ~ r-i ~�~-~i C�~ 'O tA N�~ A .Y x c`~ .-�'i a~ 3.c v~ ~ ro~ R, ~ v a r~o u b a ro y'~ .s N�~' a~, - U U U�~+ u 3 U.Q 3 U .n U v N O b R+ " ro � ~p ~ ~ s~ N ' a' ~ A' ~ ro ~ ~ rt ~ ro o ~ v~ . . . o+ ~ rtl ro s~ rt rts N ~ +~i ~ .Y .Y x +~i .Y ro .~e vl ~ I G1 0 Gl i.~ Q 7 4 Ul ~ sa N O U~0 r-I U U U U~ U 'U ~ N ~ 3~ 3 r+ [ R7 3 C'C 3.u W U rn H oa ro ~ ~ ro o ro ~ ~ ~ .~c .c .c ~ .c ~ x ~ a`~i c o ~~m~~a~.~ ~,bwcro ~~ua~a~�.~:c�~.~ 21 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY i a~ v 7~ ~p N E w ~ c ~ ~ O ro ~ C w m O w N O 21 C-~ O N v O N (A U! rl N N N ~ �rl a1 1~ UI J~ VI > E ro ~ a~ ro �.a a~ ro s.i 'D S] .0 'O ~ U U C E w N c O'n N W G 0.~ U~ N O O rt ~n ~ ~a ro Rf ~r ~ 1~ fA C C v N .Q C ~ ~tl O 9 'O ~ �~+vroo ov N ~-a J~ O CT N .f~ a~ rn ~ c a W 11 s..i �.I �.a U ~ ~ o ro v x a ~ b J~ C G N 4 ~ r-1 tA ��i 'C7 'O Q, ? C N N.C C 0 ~ 'D 41 N U ~-I 1~ N v c~nrob ro .-i r0 rt1 N E w�.~ ~ u G1 N O O ~0 ~ O U C O-~ ~ C ~ V C C ~ u _ ,O v) .,a pi ,,a p c c�~ ..--i ~ w c w .C ~0 U m G~ v1 ~ O a~i cn a~, v .`~u c a~ ~ - J~ ~ f1~ �.1 N UI (A O N ~0 1~ �~-I N 'O �~-1 (0 ~ 'D ~U U rt1 a~ ~p .u N O ~�ri N M v 1~ N G 1a ~ UI ~ N 1 sa W G tA 41 U N rt1 ~ N R+ O~ r0 ~ C~+ N~ G1 O N N sa sa . rI >r E s-+ s~+ U'~ U da ~ m U dv C C C o�.a t0 W 0 M U vH ro�~M++ v o ~ ~ ~ o .,c, ~n ~ ~ N ro v " v c~ u r~ Ql N N rl ~ .-I C 1 N 610 I N 41 ~ ~-~1 U ~ O~ A ~ p ~7 E+ da 'O aJ v~ N A u1 N ~ ~ ~ (1~ N M O ~ I ~ st' U b ~ ~ �.I r-1 'O O �.i �rl S-I ~ ~ b ~ ~ x ~ ~ ro b .c ~ v ro v w i~ o v u ~ ~o .a a C?.~ W 41 sa ~ r1 ~ U t/~ ~ tn' 0~0 3 O ~ E~ t~0 ~ O r+ C cn r7 ~ O O s+ cn s~ 3 C~C N ~ m u~e w a, ro�~+ o rn ro v~ s~ ~ N u�~+ ~s c a, ~ u ro v a .n x~v v ~n ~n ~ s~ ~ v x N ~ rtsa,~.~voa,ao ~ ro~x ro H ~r T1 .C ~ A~ E I GO v~ C .O N C ~ CL N N N ~�.1 N M UI V' A ~O 1~ N ~ A '-I U1 1 ~0 1.~ ~ 7 W rl ~ r-1 ~ �.~I 1-~ x b o ro~ x i r+ ro x i r+ ro v~+ b a, ~ ro�~ a u ro a cn a 'a 'C1 ~ U Ql 'O N U U ~CS ~ U CL ~ C?i tT U1 u~ G~-1 �rl U/ C~-I v] Gl .c n, ~ a a, a w a, a w E N~n w ro cn ro~ o ro N?~ ' 7 3 C~ N~r U.Y U) ,r U.~ ~ W 41 s-i ~ O Q~ ~-l O/ s.e dl N ~ s.~ N 4+ ~6 e ~ rt~ ~ rts E a ~ ro~ ro a~ a~ v .p ~ m N A a..~ 0�~ O~ s.~ u1 ~ b o�~ o a,w ro o?~~ m o~+x ~ ro H J-~ 4 rl 'E Ll ~ 11 LI 1~ 1~ LI 11 ~ R1 .Q 22 FOR OFFICIAL USE ONLY ~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040240060016-6 FOR OFFICIAL USE ONLY _ these muchines. In the machine-tool manufacturing industry, several new plants were drawn into production of modular machine tools and automated lines; this made it necessary to elaborate a unified range (for all designers and manfuacturers} of standadized subassemblies for modular - machine tools and auto~~~ated lines and to arrange centralized production. tn the creation of a unified range of standardized suba:,semblies, the - following goals were set: 1) further development of modular methods of machine tools and automated lineG to expand technical resources and increase the number of possible combinations using the minimum list of subassemblies; 2) refinement of parameters of several subassemblies to conform to recommendations of CMEA and ISO; 3) increase precision and performance of subassemblies; improve designs based on operating experience of functional subassemblies (including increased rigidity and precision, rate of rapid movement, etc.); 4) expansion of possible fields of application of modular machine tools and autom.~ted lines by including subassemblies of small modular machine tools in the unified range. T-' I o~ - al � . - - - , I ~ ~ ~6 , I f` ~ s � ,y;. I 4 ~ o ~ a . �I ' a o ~ h ~ 800 i - , ~ 0 f ' 1 1 ~ ~ 117U ' ' ~ I - ' i i ~ I ~ -----~r-F~~i - I ~ I j ' d} ~ ~---o,15U.. a , ~ ~ 0 i` ~ , ~ ~ ~ j.. _~_160u__ 7 _ , Figure 1. Vertical multi-arbor multi-~osition AS: 1--rotating table; 2--work; 3--arbor housing; 4--stop - brackets; S--moving platform of power table; 6--pedestal; 7-- base support. 23 ~ FOR OFFICIAL USE ONLY - APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 r~ux ur~r~tc;l[~ U5E ONLY _ i ' . I ; ' . t~1_.._~ - . t~. ' - I~~:_~-.~-- �o ~ - 1.1:~Y~._ _.1,= ~m ~ ` ~ ~ . ~ . ~ _ . ~ ~ ' i ,r t;"`~C ~ :~~i O ~ n ;acr J ~ re~a , - 3190 ~ � ~ Figure 2. Hori~ontal bilateral drill AS: 1) drill chuck; 2) power table; 3) side base. Table 2 parameters affecting improved parameters relative possible in- AS producti-~ity of subassemblies of signifi- crease in unified range (ave- cance of machine-tool rage based on ap- increased productivity, _ plicability of sub- producti- ~ assemblies), ~ ~ity, ~ ;yj increased rate of rapid 40 15 6 travel of power pack5 increased dimensions of 70 32 10 arbor housings (and ac- cordingly, average number of arbors) set on bracket, whose size corresponds to - size of power table inccreased conditions of 70 33 11 - cutting because of in- - creased rigidity of arbor housings, chucks, power ~ and index rotation tables ~ and frame parts increased output of elec- 45 20 9 tric rotary drive of arbor housings and chucks 24 - FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 . ~FOR OFFICIAL USE ONLY When the unified ranye uf standardized 5ub~~:;seinblie:~ i: ncoc~urated, the overall number~of moduluar machine tools (including 25 type sizes of new subas~emblies for small machine tools) is reduced by about 40 percent (including arbor housings, about 60 percent). The following are used as power packs in the unified range: small manual hydraulic tail-spindle heads (size 01-04) with hydraulic drive 0.12-1.1 kW; automated radial cam tail spindle heads (sizes 03 and 05), output 0.6- 3 kW; tables, power (sizes 1-7) of normal, increased and high precision (with hydraulic and electromechanical feed); chucks, reaming, drilling and milling (without tail spindles), output 1.5-30 kW; chucks, recess-reaming and milling (with tail spindle), output 15-30 kW. Work rotating subassemblies for the unified range include: mounted rotary index tables (~f200-320 mm) of high precision with hydraulic drive; rotary index tables (~d400-800 mm) of normal and increased precision with electromechanical drive; mounted rotary index tables (~800-1600 mm) of normal and increased precision with hydraulic drive. The unified range envisaged the use of support frames (for modular mz.chine tools planned by all special design bureaus) including: frame for small modular machine tool; frame parts (including base and pedestal} for ~ modular machine tool with radial cam heads; frame parts (cast and welded) for AS and A1 composed of power tables. For the possible use of computer technology in composing orders for unified range subassemblies, a classifier was elaborated in conformity with which tihe code of each subassembly consists of 6 characters. The first character (letter U) is the index of the unified system of standardized subassemblies. The second ck~aracter is a letter belongi.ng to - the developer of the technical speci~ications: A--ENIMS; D--Odessa Special Design Bureau ARS; E--Minsk Special Design Bureau of Automated Lines; N-- Moscow Special Design Bureau of AL and AS; Kh--Kharkov Special Design Bureau of AS. The third character is a figure belonging to the subassembly .group: 1--frame, base parts; 2--drives and mechanisms of installation; 3- -arbor subassemblies; 4--main drive subassemblies, feed and adjustment ' units, etc. The fourth character is a figure belong to the subassembly group; the fifth symbol is a figure belong to the subassembly type size. ENIMS developed state standards (over 20) governing basic dimensions and norms of precision of standardized subassemblies of the unified range, which ensures high quality ot manufacture of these subassemblies by all ' plants according to standardized technical conditions. 25 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 i�va~ vl~ri~.itw uJC~ U1VLY The use of unified range standardized subassemblies of AS and A1 instead of the previously used normalized subassemblies yields the following ad- - vantages: 1) the overall number of type sizes of subassemblies is greatly reduced and the technical l.evel of subassemblies and their AS and AL is increased (Table 1); 2) productivity of AS can be raised by 36 percent (Table 2); 3) subassemblies of unified range are fitted with improved electrical and hydraulic control, as wel.l as systems of lubrication, ' removal of cuttings, etc. ~ Figures 1 and 2 illustrate t~~pical arrangements of AS (design of Moscow Special Design Bureau of AL and AS) of different purposes, built on the basis of standardized subassemblies of the unified range. ~ COPYRIGHT: Izdatel'stvo Mashinostroyeniye, STANKI I INSTRUNiENT, 1979 ~ 8617 CS0;1821 - 26 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY METALWORICIPIG EQUIPMENT UDC 62-229.331 NEW LINE OF SPINDLE BOXES ELABORATED ~ Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 17-19 [Article by G. I. Gorelik, V. B. Genin and Zh. E. Tartakovskiy: "Spindle Boxes - (Text] The Moscow Special Design Bureau of AL and AS and the Minsk Special Deisgn Bureau of Automated Lines elaborated a range of single-spindle boxes of varied technological designation in which they use uniform design solutions and a large number of identical elements. The composition of the range includes boring chucks in seven sizes, recess-boring chucks in five sizes, drill chucks in three sizes and milling chucks in five sizes. - Boring chucks of the UYe411 type are designed for reaming holes without the use of jig bushings and may be of normal and increased precision. L Chucks of normal precision are used in nonferrous reaming of holes of all ~ classes of precision, in semifinished reaming of holes of the third class of precision and in finished ream~^~ ^F ti~?`~ of the fourth or lower ~ classes of precision. Additional requirements are not imposed on the form of holes in these classes, as a rule, and hole axis deviation of 0.1 millimeter is permitted within 300 millimeters of length. Chucks of increased precision are used in semifinished reaming of holes of the first and second classes of precision and in finished reaming of holes of the second and third classes of precision with a tolerable error of shape of reamed holes no more than half the diameter tolerance ar.d tolerable error of hole axis position not to exceed 0.05 mm over a length of 300 millimeters. The reaming chuck type UYe411 is shown in Figure 1. In the housing (5), the arbor (3) is mounted on bearings. Axial forces are absorbed by the thrust bearing (6). Provisional clearance of the bearings is controlled by ' nuts(2) and (4) and expansion rings (1) and (7). The basic technical data of reaming chucks of type UYe41? are shown below. If it is necessary to face end surfaces and scroll grooves in apertures, the recessing-reaming chucks composed of standardized reaming chucks (cf. Figure 1) are used containing type UN428 faceplate and type UN474 cross feeder. Basic technical data of recessing-reaming chucks are shown below. 27 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY UYe411 Reaming chucks Size 1 2 3 4 5 6 7 Diameter of arbor in front support, mm 40 60 80 100 130 160 'lUU i~ront end of arbor (GOST 12595-72) 3 4 5 6 8 11 15 Permissible axial force, - kgs 160 250 400 630 1000 1600 2500 Largest dia- meter of rear~ed aperture, mm 100 125 160 ~00 250 320 400 Recessing-Reaming Chucks . Size 3 4 5 6 7 Diameter of arbor ~ in front support, tldn 80 100 130 160 200 Diameter of faceplate, mm 250 320 400 500 630 Longest travel of carriage, mm 50 60 80 100 125 Highest rate of arbor rotation, rpm 650 550 550 500 400 Cross feed, mm/min 17-450 11-450 11-450 7-400 7-400 Rate of rapid extraction of carriage, m/min 5 4.5 4.5 4.5 4.5 Greatest force - of feed in car- riage, kgs 125 200 320 500 800 Permissible bending moment ~ of cutting forces with respect to carriage force, kgs.m 10 20 40 80 160 Rated pressure in hydraulic system, kgs/cm2 20 20 30 30 50 28 FOR ~JFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY ~ t J ~ s s ~ / . ' . ~ r ~ ~ ~ / 4!.~ , r~_;. . . K . ~ ~ , / :,'1 _ ' Figure 1. Type UYe411 Reaming Chuck The arbor (9) of chuck (Figure 2) is rotated by an electric motor through the main drive (7). A faceplate (10) along whose guides the carriage (12~ travels in a radial direction is attached to the arbor flange. Carriage movement.is accomplished through a rack transmission by a pull rod (8) which is actuated by a hydraulic cylinder (2) of the cross feeding mechanism. The rack cut into the front end of the pull rod is engaged with the two wheels (11) which in turn are engaged with the two racks (23) and (24), attached to the carriage. This coupled rack transmission is necessary for selection of clearance in Ehe feed mechanism by tnoving the rack (23) with - screws (22) along rack (24). To guarantee precision the forward position of the carriage (with diameter tolerance of less than 0.5 millimeter) has a control~screw (14) which, in forward carriage position, touches the detent (13). The cross feed mechanism contains a bearing block 915) intended for _ connecting the pull rod (8), which rotates with the arbor, to the stationary rod (3) of the hydraulic cylinder (2). The initial position of the rod and carriage are set by detent (17) on which rests the nut (1) attached to the rod. With a diameter tolerance of more than 0.5 millimeter, the working stroke of the rod and carriage are controlled by ~ the detent (16) on which the nut (1) rests. To monitor the end positions of the carriage, contactless end breakers (4) and (21) are used. When the hydraulic cylinder rod moves, pin(5) rotates a roller (18) past lever (6), together with which the detents (19) and (20) rotate, interacting with the end breakers. If necesary, the recessing- reaming chucks.can be used to sequentially ream holes and face ends. _ Reamers are attached to the faceplate along with the carri~ge. In all cases, the power table on .which the recessing-reaming chuck is mounted must approach the fixed detent at a slow speed. If it is also necessary to ream a hole in addition to recessing faces, the power table must approach the fixed detent in working feed. In this case, the table is controlled by the hydraulic feed panel. If only an end is to be reamed, the ~ 29 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 r~ux urr~l(:tAL U5E ONLY table is controlled by the guide hydraulic distributor, and to reduce the rate of approach to the fixed detent, a travelling throttle may be used. Figure 3 shows a standard hydraulic control circuit for a recess- ing-reaming chuck. After stopping the power table (on the fixed detent), electromagnet E1 of the three-position guide distributor (5) is switched on. Oil from the high pressure pump passes through the filt~r (8), reducing valve (7) and flow regulator (9) into the right cavity of the hydraulic cylinder (2) of the cross feeder. The cylinder piston moves left performing the working feed of the carriage. From the left cavity of the cylinder (2) the oil pours into the tank throug the pressure valves (3) and - (6) . '1'he reduction valve is designed to reduce pressure in tF?e cylinder (2). ~ ? J 4 ~ S 6 7 d\ 9 10 . ~ ' ~ n ~ _ ~ , ~ r ~ -~::t:~= ~ . . . - _ - - - - 13 . ~ , - ; . ~ ~ , . . . ~ f! 16 ~ A--~ 15 ~ ~ A-A 6=6 ' 99 ?0 � P1 . ~ 14 16 ~ 7J . ~ - . ~ j; \ ~ ; / - - , ; / - ~ ~ , v ~ d \ 11 Figure 2. Recessing-Reaming Chuck. 30 FOR OFFICIAL USE ONLY _ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY 2 f . ~ 3 ~1 8~. �4 3f 32. L _ _3 S - 6 ~ 8 .-~7 I Figure 3. Standard Hydraulic Control Circuit of Recessing and Reaming Chuck. When recessing the front end of a part, the carriage returns to its initial position after the power table arrives at its initial position: this ensures minimum cycle time because carriage return in this case can be combined with release of the work. In recessing the rear end of work, the carriage returns to initial position before the extraction of the power table. To return the carriage to initial position, electromagnet E1 is dis- connected and electromagnet E2 is switched on. Oil enters the left cavity of the cylinder (2) through the reverse valve (4); from the right cavity of the cylinder, oil pours into the tank through the reverse valve of the flow regulatoc (9) and pressure valve (6). Oil is also fed into the cavity of the lubrication plunger pump (1). If necessary to drill single openings of large diameter, type UYe412 drill chucks are used which are similar to reaming chucks shown in Figure 1. The difference is that the leading end of the arbor has a hole for installation of the mandrel tail spindle with a bar cutter (similar to the arbors of multi-arbor boxes), and in the front support of the of the arbor instead of the two-row roller bearing are placed two radial thrust ball bearings. On the sides of the front part of the housing of the drill chuck there are bars for attachment of the conductor plate. The basic technical data of type UYe412 drill chucks are shown below. 31 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 ~�vL~ vi L t~.irw U.~~ U1VLY Size 2 3 4 Arbor diameter in front support, mm 60 70 85 Hole diameter in arbor (GOST 13876-76), mm 28;36 36;48 48;60 Permissible axial force, kgs 1000 1500 2000 Largest hole ~D, mm (steel): 25 32 40 (cast iron): 32 40 50 6 A � _ ~ s s f--- + o a� i ~ B + i - -~-^---~E~ I ~ ~ ~ s z s_a ~ A J~ ' /~�'/,~i ~ . : . � " a a ~i, ://'!j,,i/ . ' 1 ~~~/.~~i/i' ~.~~i.i.'i//.'.'ii~~/ . ~ o a . p p O' O / ' , . ~ ; ~ /i . Z ~ 1 6-6 A_A - k 7 B 9 JO { - ~ . ~z . /i Figure 4. Milling Chuck type UYe413 with Tail Spindle Break-Away. Milling chucks type UYe413 are mainly designed for facing work made of ferrous and nonferrous metals. The milling chucks can be set horizontally, on an incline and vertically on moving or stationary elements or machine tools; feed motion can be imparted to the work or to the milling chuck itself. The milling cutter is set to treatment size by an adjusting motion of the tail spindle. Standardized milling chucks of type UYe413 are manufactured in two kinds: with and without tail spindle break-away. The former ones are used whzn the cutter does not have to be withdrawn from the work surface during the machine cycle. The basic technical data of UYe413 milling chucks are cited helow. 32 - FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY ~ c a~ a) Figure 5. Spindle box rotary drives: a) type UYe465 drive; b) type UYe464 drive. Size 3 4 5 6 7 - Arbor diameter - in front support,~ mm 60 80 100 130~ 160 O.D. flange of arbor (GOST 836-72), mm 88;882 101.600; 128.570; 152.440; 221.440; 128.570 152.400 221.440 335.0 Largest - milling diameter, mm 200 250 400 500 630 Adjustment movement of tail spindle, mm 50 50 100 100 100 Figure 4 shows the milling chuck with tail spindle break-away. The housing (1) has a base plane for attachment of the chuck to the machine tool and a shaft plane for installation of the arbor rotary drive. In the housing opening (1) is set the cylindrical tail spindle (2) with the arbor (3) mounted on bearings. Clearances in the tiearings are controlled the same way as in reaming chucks (see Figure 1). A connecting link (4) is attached to the tail spindle which is connected to the adjustment mechanism. This mechanism is made in.the form of an adjustment screw (7) which interacts with a slide block (9). 33 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 1'va~ vPi iVtrw U~L' V1YL1 Extraction (break-away) of the tail spindle is accomplished by a hydraulic cylinder (10) connected via a slide block (9), screw (7) and connecting link (4) to the tail spindle (2). When the slide block moves to the right, the tail spindle is extracted 10 millimeters. When it moves in the opposite clirection, the tail spindle is brought up to the detent of the variable caliber slide block (8) designed to replace the milling ccutter without adjustment. The clamping and release of the tail spindle are accomplished when the slide block (12) is moved by the hydraulic cylinder (11). The forward position of the tail spindle is monitored by the contactless end breaker (5); the rear position--by the end breaker (6). In milling chucks without tail spindle break-away, the hydraulic cylinders (10) and (11) are replaced by screws with manual rotary drive. The bearings, tail spindle and trail ^pindle movement mechanism are lubricated when the chuck is assembled with plastic lubricant TsIATIM 203. When installed on cross tables which both feed the work and perform cross extraction of the chuck from the work, milling cutters without tail spindles can be used. These chucks differ from reaming chucks (see Figure 1) only in the design of the front end of the arbor, made in conformity with GOST 836-72. The basic technical data of milling chucks correspond to the data of reamers. In the event that the direction of feed is parallel to the support plane of the _milling chuck, the latter is set at the angle of the milling cutter and is l~cked in this position by conical pins. If the direction of feed is perpendicular to the support plane of the milling chuck, the necessary angle of inclination is assured by scraping the work coupled with the chuck or the housing the chuck itself. To rotate the arbors of chucks of normal and increased precision, standardized drives of two types are used: type UYe465 with cylindrical geared transmissions (Figure 5a) and type UYe464 with gear-and-belt transmissions (Figure 5b). Drives with gear-and-belt transmissions are used primarily when a high rate of rotation is necessary, e.g., in work made of aluminum alloys. Below are cited the basic technical data of rotary drives of reaming, recessing-reaming, drilling and milling chucks (numerator for UYe465, denominator for UYe464 drives). Size 1 2 3 4 5 6 7 Maximum motor power, kW -/0.55 1.5/1.5 4/4 5.5/7.5 11/11 18.5/18.5 30/- Maximum torque, kgs.m -/0.5 25/1.5 50/4 90/9 180/16 360/31 710/- Output shaft - rpm - '1-1180 45-900 25-900 20-850 16-710 12-450 770-4100 630-4130 550-3110 410-2550 330-1900 290-78C - COPYRIGHT: Izdatel'stvo Mashinost~oyeniye, STANKI I INSTRUMENT~ 1979 8617 34 cso: is21 FOR OFFICIAL iJSE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY METALWORKING EQUIPMENT UDC 621.9.06.112-229.31-182.5 POWGR AND ROTARY INDEX TABLES WITH HYDRAULIC DRIVE Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 19-22 [Article by V. B. Genin and Zh. E. Tartakovskiy] ~ (Text) Power tables are among the basic subassemblies which determine the make-up of modular machine tools, both discrete ones and those appearing as part of automated lines (AL). Multiple spindle boxes, milling, reaming, revolving and other chucks are mounted on power tables. High productivity multiple position machine tools with rotary index tables hold a sig- nificant place among modular machine tools. On each of these maachine tools a number of sequential operations is performed, making it equivalent to a section of automated line. ~ The Moscow Special Design Bureau of Automated .Lines and Machine Tools elaborated power tables of type UN451 and rotating index tables of type UN205 with hydraulic drive, whose production has been assimilated by the Moscow Plant of Special Machine Tools Spetstanko. These tables are used by all plants which product modular machine tu~als of inedium and large dimensions. The basic technical specifications of power tables of type UN451 are cited below. The basic dimensions of power table correpond to GOST 21038-75 and - recommendations of ISO and CMEA, and precision norms correspond to GOST 16461-77. Size 1 : 3 4 5 E~ 7 Platform widtn, mm 200 250 320 400 500 630 800 Greatest feed force (hydraulic ~ pressure 50 kgs/cm2), kgs 630 1000 1600 2500 4000 6300 10,000 Smallest feed, mm/min 50 32 20 12.5 8 5 4 Recommended rate of rapid travel, m/min 11 . 9 8 7.5 6.5 5.5 4.5 Longest stroke, mm: ' horizontal 400 630 630 1000 1000 1250 1250 vertical 400 630 630 3J 630 630 1000 1000 _ FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 rux Ur~r~1~lAL U5~ ONLY l 1 3 4 5 ~ D ~ ~ 10 ~ - =~~0 ~'i~~ -Q~ d A-A ~ tt rz u - w r~ ~ ~ ~ o Figure 1. Type UN451 Power Table. Note: When the special hydraulic drive is used, the rate of rapid - extraction may be 50-80 percent hiqher. The UN451 power table with hydraulic feed drive is shown in Figure 1. The platform (5) of the table travels along the plate (6) with rectangular (9) and prismatic (10) guides. The use of the prismatic guide, although it led to some increase in labor intensiveness of manufacture ~f the plate + (compared to a plate having two rectangvlar guides), did make it possible to completely eliminate gaps in the guides and avoid the use of a control wedge. The non-rectilinearity of table motion is no more than 16-25 microns (according to the stroke length) for table of normal precision and no more than 10-16 microns for tables of increased precision.* The hydraulic feed drive of the power ~able contains a hydraulic cylinder (14) set in the plate (6), a pump with electric motor and hydraulic panel mounted on the free-standing hydraulic tank. Electromagnets which move the slide valves of the hydraulic panels switch on and off during the table travel on command from contactless end breakers (4), (7) and (8). The latter are arrange~ on the plate and cycle in reaction to detents (1) set on the platform (5). The number of end breakers and detents is determined by the operating cycle of the power table. In the front part of the plate (6) is set a screw (rigid detent)(11) which enables one to control the forward position of the platform. The hydraulic cylinder (14) is attached to the plate (6) and the plunger (14) to the platform: This method of attachment ensures possible disassembly of the hydraulic cylinder without taking down the power table. Furthermore, - - thermal deformations of the hydraulic cylinder are not transmitted to the power table. Valves (12) and (15) are designed to release air from the hydraulic cylinder. *This relates also to power tables with electromechanical feed drive (see article of R. G. Chaadayev and G. I. Gorelik "Power tables with elec- tromechanical feed drive", published in this issue of the journal. 36 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040240060016-6 FOR OFFICIAL USE ONLY _ ' s ~ t ~s~ - s . I 14 'j ~ ~o s ~ ~ o ' 13 i - - ~ - - " ' 7 ~ m - u, ~ lo ~ ~ ) � ~ - . ~r ~o s e - Figure 2. Hydraulic feed panel: 1) hydraulic distributor guide unit; 2) - plate; 3) type 3M22-S320 distributor; 4) type 60Mt-1-100 NVS manometer; 5) type PG7"1-1 throttle; 6) flow regulatoi- type 2PG55-1 (for hydraulic panels of first modification); 7 and 8) safety valves type APG52-24 of feed pumps and rapid travel pumps, respectively; 9) reverse valve type PG51-14; 10) pressure vale type PG52-24; 11, 12, 13) control distributors type 55BPG73- 11; 14) feed selection valve; 15) hydraulic seal. The power table guides are lubricated automatically from a central system. Oil is fed from the lubric.ation stati.on through a flexible hose to the collector (3) attached to the table platform. The collector is connected by meters (2) to the lubrication poini:s (amounts ranging from 0.2 to 0.6 cubic centimeters according to table :~ize). Oil flow control entering the hydraulic cylinder cavity of the power table is accomplished with the aid of a type [rN74 hydraulic feed panel. Hydraulic panels of models UN7416 and UN7414 are designed to control power tables oeprating in a cycle with one working feed. Hydraulic panels UN7426 and UN7427 are designed to control power table operating in a cycle with two working feeds. The total consumption of oil for the first and third models is up to 50, and for the second and fourth models is up to 80 liters per minute: ~ Each hydraulic panel has two modifications, differing in typf~ of flow regulator. In hydraulic panels of the first modification, a ty~.e 2PG55-1 flow regulator is used which during operating feed changes the pressure in the system according to the load on the power table. The hydraulic panels of the second modification have a type PG55-2 flow regulator which during operating feed maintains a constant pressure in the system regardless of the load on the power table. All hydraulic panels are similar in design and their parts are highly standardized. 37 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040240060016-6 r~n ~rrt~te~, U~r. UNLY Peed hydraulic panels (Figure 2) consist of a set of general hydraulic apparatus and special devices with clamps making possible rapid re- placement of any pari:. Special ele:~~ents of the hydraulic panels are the plate (2), hydraulic distributor y~ide unit (1), hydraulic seal (15) and Eeed selection valve (14). Elements ot the hydraulic panel are set on the plate (2), through which pass the connecting channels. On the rear of the plate are apertures to which are con~~ected the pipes designed for connection of the hydraulic panel to the hydraulic cylinder, pump and tank. The hydraulic panel is attached on the vertical guard of the hydraulic deivice station with four screws. A primary dif2:erence in the hydraulic circuit of the type UN74 hydraulic panels ana the earlier models 5U42 is the incorporation of a hydraulic seal (variable check valve) between the hydraulic distributors of the panel and the forward cavity of the feed cylinder. The hydraulic seal isolates the ' ~7ydraulic distributor and thereby eliminates the effect of interna]. leaks on the intensity of working feed. Because of the presence of a hydraulic seal, and the sealing of the _ cylinder piston wi.th V-shaped rubber sealing rings (instead of the earlier r,ast iron piston rings), fluctuations in wor.king feed do not exceed 5 percent for maximally possible changes in load and temperature. Re~narch done by the Moscow Special Design Bureau of Automated Lines and Machine Tools showed that the spread from the selection point of the power table from rapid approach to working feed at rapid stroke (see technical description) does not exceed 2 millimeters. Instability of power table . platform position when stopped on the ~rigid detent (with constant alignment of the safety valve) does not exceed 0.02 millimeters. To assure repeated intermediate extractions of the power travel during wc.~king feed (when drilling deep holes), an additional control device is installed which conLains two end breakers and a moving working feed detent. _ This mechanism is placed on the right side of the power table; on the left - - side ~F the stable are placed another two end breakers, one of which is switched on when the table platform is in initial position, and anoth~r at a point to which the table travels during intermediate extraction. The end bre~kers of the additional control device determine the selection point of the table from rapid approach to working feed and the extreme forward position of the table (end of treatment). The basic technical specifications of rotating index tables type UN205 are cited below. Their basic dimensions correspond to GOST 22439-77 and precision norms correspond to GOST 16460-77. 38 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY z a , 5 6 ~ ~ ~ ~ i f . ~ I ~ ~ , e s ~ . _~~r_.'~ F'i ~ ' ,i , ~~~f ~ A � . ~1 ; ; ~~f~ _ ` to A-A ' 19 \ ~ 1! 1I; N.' z' ' % I I S 1`�4 i ~ i'~ ~s / :e � t /i//; ~6 2~ , ~ i Ii IJ 21 1S 14 Z~ ~ � ' 10 19 1B . 1~T Figure 3. Rotary index table type UN205 Table model UN2056 UN2057 iJN2058 Faceplate diameter,mm 800;900 1000;1120 1250;1400 Number of positions 2-6;8-10 2-6;8-10 2-6;8-10 _ Itotation time to one position (seconds, not - more than) for tables with number of positions: 2-5: 5.5 6 7.5 6-12: 3.5 3.7 4 Precision of positioning (angle second~) for tables: normal precision 14 1,2 g _ increased precision 8 8 5 Tolerable torque on faceplate from cutting forces, - kgs.meter: clockwise 600 800 1100 counterclockwise 800 1000 1300 Tolerable radial force applied 200 mm above faceplate end, kgs 4000 6300 10,000 Greatest weight of jigs and work set on table, _ ky 2000 3000 4000 On the housing (1)(Figure 3) of the rotai:ing index table is set a faceplate " (2) and within it are arranged the rotary drive, locking mechanisms and 39 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 - N'UK Ur'r IC IAL USE ONLY ~ i s' i i ~ . ~ - - ii_~ u v C _ _ _ _ _ L,i, _J ~~e ro . i . , - n ~ r~ ~ ~ ~ . ~ ` = _..T-- - r, - 4 S ' u - - , r T M � ~ Figure 4. Theoretical hydraulic circuit of ' rotating index table faceplate clamp. The faceplate (2) rotates around an axle (Sj on a precision double roller bearing (6) with conical opening. The axle (5) has a central opening for pipes feeding oil to the device set on the faceplate. The table's hydraulic drive includes a hydraulic motor (26) which rotates the faceplate, hydraulic cylinders (10) for clamping the faceplate, a traveling throttle (20), and a pump with electric motor and control hydraulics placed on a separate hydraulic station. The rotating table operates in the fol~owing cycle: release of the faceplate and hydra~~lic relief, rotation of faceplate with braking at end of stroke, reversal of faceplate and securing to lock, clamping of faceplate. The faceplate is released when the hydraulic cylinder pistons are re- tracted (10). The clamps (7), in reaction to the force of gravity, rotate - around their axes and release the faceplate. Simultaneously, oil is fed under pressure from the central lubricatior~ station into grooves on the annular housing guide to ensure separation of the faceplate from the guide and create an oil layer between them to reduce torque required to rotate the faceplate and to prevent guide wear. The instruction to rotate the faceplate is given by the pressure relay mounted in the guide r~lief ~ystem. The faceplate is rotated by a hydraulic motor (26) via a flexible coupling (24), worm gear (30), worm wheel (29), geared wheel (3) and (4). When approaching the next position, - 40 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY the detent )11_ fixed to the faceplate drops a l.ocking pin (13). The rod (12), whose cleat faces the l.ever (23) set inside the locking pin, clamps the slide block of the traveling throttle (20). At first, the inclined grooves of the slide block located on its bottom smoothly reduce oil feed from the hydraulic motor. When they are completely closed, the upper groves are opened. Then the lower grooves are completely overlapped and the oil emerging from the hydraulic motor only passes through the upper grooves. The slide block is automatically dropped to the extreme bottom position. The flow rate of oil through the upper grooves of the slide block (2.5-3.5 liters/minute) assures the necessary retardation of rotation (smooth retardation) of the faceplate prior to reversal. When the locking pin (13) is dropped, the screw (18) switches on the end breaker (17) which then prepares the instruction for reversal of the - hydraulic motor (26). When the detent (11), as the faceplate continues to rotate, releases the locking pin (13), the latter is lifted in reaction to a spring (14). The end breaker (17) shuts off and relays the signal for the hydraulic motor (26) to reverse. Oil begins to enter through aperture (19), and the slide block of the traveling throttle (20) is lifted, _ releasing the passage of oil to the hydraulic motor through aperture (21). At the end of the reversal cycle, the detent (11) rotates a cleat (12) � overcoming the force of the spring (not shown in Figure 3). The screw (15) acts on the end breaker (16). The latter switches on a time relay whose delay is adequate to stabilize the clamping force of the working surfaces of the detent (11) and lock (13). When the time relay cycles, hydraulic relief of the faceplate is shut off and it is clamped. The clamping of the - faceplate and the indexing cycle end with the cycling of the clamping pressure relay which enables the rapid approach of the power packs. In a rotary ta51e, it is possible for manual rotation of the faceplate during adjustment. The manual rotation drive consists of a spring-loaded shaft-wheel (27) with hexagonal aperture for the key and a wheel (25) set - _ on the sha.ft of the hydraulic motor (26). When the spring is compressed (28), the shaft-wheel (27) is engaged with the wheel (25), which permits the faceplate to be rotated. The cavity (9) is designed for collecting shavings and lubricating fluid which, using scraper (8) attached to the faceplate, are removed along an inclined pan into a separate chip drum. Figure 4 shows the theoretical hydraulic circuit of the rotatina index table. In the hy9raulic tank (1) is set a dual pump (2) of type 5G12-23A with feed of 5/25 liter/minute. The pump is controlled by the distributing hydraulic panel (3) of type MPG53-14. The hydraulic motor (6) is controlled by the guide hydraulic distributor (4) of type 5U4321 with Em2 - electromagnet. 41 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 rux Urr1l;1NL u5~ UNLY When the Em2 electromagnet is switched on, oil enters through the check valve of the stabilizer (5) into the left cavity of the hydraulic motor (6) and the faceplate is rotated. The rate of rotation is adjusted by the _ throttle (8) set at the outlet of the hydraulic motor. At the end of rotation, before reversing, the faceplate is braked by the traveling throttle (7). When the electromaqnet Em2 is shut off, oil is directed to the right cavity of the hydraulic motor (6); this reverses the faceplate. The rate of reversal is determined by the stabilizer (5) placed at the outlet of the hydraulic motor. The stabilizer contains a several successive diaphragms, _ whose number may be changed according to the diameter of the faceplet and moment of inertia of jigs and work set on the faceplate. In the locked position, the faceplate is clamped by hydraulic cylinders (9) controlled by the guide hydraulic distributor (11) with electromagnet Eml. The end of faceplate clamping cycle is monitored by the pressure relay (10) . Hydrostatic relief of the faceplate is accomplished from the lubrication station which also services the cent-ralized lubrication system of the guide opwer tables and working surfaces of jibgs of the modular machine tool, which contains a rotating indexing table. For hydrostatic relief of the faceplate it is necessary to have much less pressure than for operation - of the lubrication system; thus the lubrication system has a reducing vavle which lowers pressure to 3-6 kgs/cm2, which is monitored by the pressure relay. ~ The oil flowing out of the guide ring into the inner cavity of the table housing is used to lubricate the geared and worm transmissions. Oil returns to the lubricating station by gravity flow thorugh a mesh filter with magnetic separator. The dual roller bearing of the central axle is lubricated by a plastic lubricant when the rotating table is assembled. A basic advantage of rotating index tables of this design, as compared with earlier type 5U28, is the increased precision of indexing assured by design measures and by stabilization of the force of clamping of the detents to the lock because of the constant rate of reversal. Rotating index tables make it possible to put together modular machine tools with vertical power - tables on which the spindle box is mounted. In some cases it is - advantageous to put together modular machine tools with several power packs arranged radially. Each pack treats work arranged at one work position. In this case, especially when treating large work pieces, it becomes necessary to use rotating index tables with a faceplate of more than 1400 millimeters in diameter. The Moscow Special Design Bureau of Automated Lines and Machine Tools elaborated a design for rotating type of table UN206 with a faceplate of , 1600 millimeter (model (iN2064) and 2000 millimeter (model UN2065) diameter faceplate, whose production is being assimilated by the Moscow Plant of Special Machine Tools Spetstanok. 42 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 _ FOR OFFICTAL USE ONLY ~ 6 ~ S 4 J 1 1 I \ ~ - ~ \ I j/, ~ - Figure 5. Type UN206 Rotating Index Table Type UN206 tables have the same kinematic circuit as type UN205 tables. Almost all parts of the rotary drive, locking mechanisms and faceplate clamp are identical in both tables. The difference is that tables of type UN206 have a second annular guide (2) {Figure 5) and large conical slip bearing (3) diameter (in UN205 tables, a standard roller bearing is used). The clearance between the bearing (3) and the faceplate (1) is selected by polishing expansion pieces (4). During hydrostatic relief, the faceplate is raised above the guides and a qap is created between the faceplate and the bearing (3); this reduces the force necessary to rotate the faceplate. The large bearing permits the central column (6) to be set on the housing (5). It is possible to put together machine tools in which are used vertical power packs placed at the edges of a central column, in addition to radial arrangements of power ~ packs. Conclusions 1. Type UN451 power tables have the following merits: increased opera- ting reliability due to the use of contactless end breakers; increased reparability of tables due to possible disassembly of hydraulic cylinders without taking down the power table and hydraulic feeder drive because of modular arrangement of hydraulic control panel to ensure easy change of any component requiring repair; lack of thermal deformations in heating oil in the hydraulic system because the hydraulic feed cylinder is attached to the rear face of the guide plate; increased height of power tables in conformity with ISO recommendations, i.e., increased rigidity; increased precision of tables (rectilinearity of motion) with simultaneous eli- mination of the need for periodic regulation of clearances in the guides using wedges; 5-6 fold increase in feed stability. 2. Type UN205 rotating index tables have high precision of indexing; wear of surfaces affecting indexing precision is almost non-existent. 43 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 r~c~ urrtt,lew U~~ UNLY 3. Type UN206 rotating index tables expand technological resources of - modular machine tools; they permit assembly of machine tools with radial and vertical power pack arrangements in various combinations. COPYRIGHT: Izdatel'stvo Mashinostroyeniye, STANKI I INSTRUMENT~ 1979 8617 ~ CSO: 1821 44 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY Ml:'CALWOItKING 1~:(1UTI'M~Ii`1' UDC 621.9.06-112.229.31 POWER TABLES WITH ELECTROMECHANICAL FEEDER DRIVE Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 22-25 fArticle by R. G. Chaadayev and G. I. Gorelik] (Text] Power tables with electrochemical feeder drive have been elaborated by the Minsk Special Design Bureau of Automated Lines. Their production has been assimilated by the Spetstanok Moscow Plant of Special Machine Tools and the Glukhov Plant of Modular Units. The adopted series contains six type sizes of power tables. In modular machine tools and automated lines it is possible to simul- taneously use power tables with hydraulic and electromechanical feed drive; they have therefore been made interGhangeable in conformity with GOST 21038-75. In the design of power tables with electromechanical driver, it is possible to use spherical helical rollers. Power tables are standardized units designed for moving a cutter or work at a working rate of feed and rapid stroke. Motors and clamping jigs holding work can be set on the tables. Figure 1 shows an overall arrangement of power tables with electro- mechanical feed driver; the dimensions are shown in the table. The power table (1) (see Figure 1) together with the electromechanical feeder (3) and control detents (2) is an automatic unit. The basic ~haracteristics of power tables types UYe4532-UYe4537 with feeders UY4722-UYe4727 and control detents models UYe9531 or UYe9532 are shown below. The parameters of the power table, which is a basic standardized unit in modular machine tools, must ensure performance of various technological operations with peak productivity. For this purpose, it is possible to produce stable values of working feeds within wide limits, various cycles of table platform movement, adequate rate of rapid stroke, high geometric precision of motion and reliability. 45 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 . FOR OFFICIAL USE ONLY ~ G, 15 3 Q 6 1 f. Z ~ ~ _ ~ p / - Byd6 ~ m a c ~ ~ Fiyure 1. Basic dimensions of power tables with electrome- chanical feeder drive IlpncocA~iunren~diuc pa~Mi�p~+. M~~ . 7xn tTOna I MoAea~ I ' I I ~ I I ~ I 7 I I ' I I I I q R H H !I L L L L~ L < Y1:45:1: 12. ;S~ ~50 I'!GO I 250 I:97 I 9~Q ( SOU I 400 ( 457 I 2':0 I;415 I 1~0 ( M2M1icl,b I I I O.t. 13. ' t. :5:1 I 0~. 12. 9a0 250 YF.Ib31 OS. 13. '!:1. :4;1 ~'?0 300 280 ?90 IONO GJO 400 157 220 S80 130 M~OX I.:i 2 04. 14. 2�1. :S{ 1310 G30 02, 12. :1n I100 �50 YGI5J4 03. 11. ~1:1 4U0 400 320 :)50 12~i0 800 4U0 57G ?70 460 IG5 M3yX1.5 2 04, 14; 'l~. 34 1480 630 1300 250 ~ 0'S. 13. ~!1. id 1�150 400 ~ ~ YF�.~595 04, Ia, 2�1. :{~1 ~00 450 ~GO 370 ~fiRO G30 ~7~ 270 560 160 M36X1,~ ~ 05. ~5. ':5. S5 ^O50 1000 0~:, 12. ?Y. 3? 1700 400 630 540 M100 410 ~ 930 I 250 Ei30 G50 290 690 200 M39X I.5 2 _ Yfi~S:lfi U4, t4, ?4. Sa 2300 1000 O5, I5, 25, :f5 2550 1250 i 0?, 12. 29. 1^ 1850 400 O:S, I3. '!3. ~1~1 p00 560 450 q~p '~OAO ~ 630 fi35 ^_95 BGO ?00 M48X1.5 ^ Yf:455; 0-1. 14. _'1, ;1.1 ' 450 1000 OS. I5, :S. :SS 2700 1850 Both power tables of the range and their feeder drives have been _ constructed according to a single design scheme. The lead screw (1)(Figure 2) is set in the housing (4) on four radial ball bearings. Axial loads on the screw are absorbed by thrust bearings which ~ 46 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY are retracted by a nut (10). A geared wheel (2) is placed in cantilevered fashion on the lead screw and the former engages the output wheel of the feeder drive. Table type UYe4532 UYe4533 UYe4534 UYe4535 UYe 4536 UYe4537 Guide width, mm 250 320 400 500 630 800 Maximum feed force, kgs 1000 1600 2500 4000 6300 10,000 Maximum output of feeder drive electric motor, kW 1.5 3 5.5 11 18.5 30 Working feed, mm/min 22.2-850 20.9-1020 9.1-810 8.4-700 7.5-845 7.3-815 Working feeds per cycle ~ 1 1 1;2 1;2 1;2 1;2 Rate of rapid stroke, - m/min 7 7 6 6 5 5 Feeder motor: type: 4AA5684U3 DPT22-4-C2 4AKh~0A4U3 output, kW: 0.18 ' 0.55 1.1 rpms: 1370 1400 1400 rast stroke motor: type: DPT22-2-C2 4AKh80V4U3 aA100S4U3 output, kW~ 0.75 1.5 3 rpms: 2850 1400 1425 Table travel, mm: 250;400 250;400; 250;400; 250;400; 400;630; 400;630; 630 630 630;1000 1000;1250 1000; 1250 Length of table with feed drive and control detents, rt~m 1260;1410 1390;1540; 1680;1~30; 1880;2020; 2330;2560; 1770 2060 1160;1630; 1930;3180; 2485;2715; 3085;3335 Weight, kg 245;262 388;423; 630;665; 910;945; 1412;1530; 468 725 1910;1105 1613;1778 2002;2113; 2880;2408 Note. To ensure two working feeds, the electric motor for working feed is replaced by a two-speed one of the same size. The lead nut (6) is rigidly.attached to the rear recess of the platform (7) of the table by pins (5) and screws. When the lead screw rotates, the platform travels along the guide plate (9). On the housing (4) is mounted a ring (3) which serves as a centering flange for the feed drive. With long table travel and consequently, long travel of the lead scrEw, bronze bushings (8) are placed in the intermediate ribs of the platform; these limit overhang of the cantilevered end of the screw. On the lead rig of the platform there is a steel abutment which, in the event of the need for precision stopping of the glatform in forward motion, rests on the rigid detent screw. The lead screw is advanced coaxially with the lead nut by ' 47 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 _ ~ .,.,a. virLl means of expansion pieces (11). After testing coaxial alignment, the housing (4) is attached to the guide plate (9} with two cylindrical Nin:; - (12) . ` J ....1 ~ J 6 1 8 _-r} ` . ~ ~ �g ~ - ~ g 6--! !1 12 6=6 aud A ' + 1" ~ _ o . - , i ~ r~ Figure 2. Power table with electromechanical feed drive. The base parts of the table with electromechanical feed drive have one - plane and one prismatic guide, identical in size, shape and position with the guides of base parts of power tables with hydraulic feed drive. _ The feed drive of the power table is attached to the rear end of the guide - plate, while centering it in ring (3). It is a reducer with cylindrical gears with two electric motors, one of which moves the table platform at working feed, while the other is for rapid stroke. The electric motor (5) (Figure 2) of working feed transmits movement via - six pairs of gears (situated in shafts VIII-IV) to a spline bushing seated on point bearinqs on shaft III. On it is installated an electromagnetic coupling whose outer discs are engaged with a strap (1) rigidly fastened to the shaft III. When the electromagnetic coupling is switched on, the bushing rotates the shaft III and then through the gear pair rotates shaft II with the output drive gear. The guide screw (shaft I), being rotated by the motor, moves the platform at working feed velocity, adjusted to the external size by replaceable gears (6) positioned under the cover. To replace them, it is not necessary to take down the drive. The range of control of working feeds adjusted by these gears equals 8. In the feed drive, the gears (3) and (4) installed during assembly are ~ replaceable. They det~rmine the modification of the drive in terms of feed velocity. Each drive has three modifications of feed velocity: O1--low feed; 02--average feed; 03--high feed. Practice of planning and debugging modular machine tools has shown that in most cases the adjustment of necessary working feed velocity by replaceable gears totally justifies ~ 48 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY itself. 5 6 ~ B 1 ---r~- ` ~ ~ L~r`--- _ .I. ` ; ~ i'===~_~ I ; . ~ ~ ~ ~ = ~ ! 'J,r~t =f--1 ; ~ ~I - ~ I I i' I.1 ~ i I � , ; ~ _ _ ; L ~ - ! _ ! ; ; i I ~ ~ , ~ ~ ` . I ~ i ( ~ ! I i ~ _ j t ~ Ib='i~ ~ ~ . 1r-~ ~ - , ~ ~ r ! I t j I , f . , ~ ~ ~ ~ ~ ~ \ ~ - ~ ~ G~ v_n ff v lv I! l ~I 4 a z i - + ~ I Figure 3. Presentation of electromechanical drive for power table feed. On shaft V of the feed drive is placed a friction safety clutch (2) to adjust the amount of feeding force on the guide screw, permitting the power table to operate at the rigid detent. The momentum imparted by the clutch is regulated, if necessary, by screw (7) placed under the replaceable gear cover. From the rapid stroke electric motor (8), motion is transmitted to the table platform via a gear pair, shaft II, output drive gear and guide screw. The direction of platform motion is changed by reversing the electric motor (8) when the electromagnetid coupling is disconnected. The latter is swi:ched on after switching off the electric motor (8) so that the kinematic circuit of working feed damps the inertia of the flywheel masses of the electric motor rotor and the rapid stroke circuit. In the operating cycle of tables of types UYe4534-UYe4537, it is possible to accomplish two feeds. In this case, instead of a one-speed electric motor of warking feeds, a two-speed motor is used; the second feed is 1/2 the first. When the feed rate must be double or it is necessary to have several working reeds in a cycle, a d.c. electric motor or hydraulic motor (in the latter case a special reducing gear is required) is placed in the drive instead of an asynchronous working feed electric motor. Control detents (2)(see Figure 1) have a standard design for all tables in the series. By controlling the table stroke, they assure the required operating cycle of che latter. Spacing cams of the detents with aluminum blades enter into slits of the contactless end breakers type BVK, fixed 49 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 ~ va� v~ a ~.vi~u-, v~/L VL'1LL solidly, when the table is in motion. Commands go from the BVK to the machine tool's electric cabinet, and thence to the motors and clutch of the feed drive. The following operating cycles of tables are most commonly used: a cycle with one working feed (rapid approach--working Eeed-rapid extraction); a cyclie with two working feeds (rapid approach--first working feed--second working feed--rapid extraction). In the first case, three BVKs are used, in the second case--four. In both cases work ca~ be done with a delay at the rigid detent and the backstroke of the table to the extreme rear position (position of cutter replacement). In more complex cycles of table operation (with intermediate extractions in deep drilling, with travel., etc.) it is necessary to install additional traveling selectors or special ' control detents. The electrical equipment is completely assembled on the power table. Leads run from the control detents, electric motors, electromagnetic coupling down into a box with plug connector attached to the feed drive. When assembling or disassembling the table on the machine tool, it is only necessary to disconnect or pull out the plug connector without oisturbing electrical connections. The table guides and the screw-nut pair are force lubricated from khe lubrication station. With a pressure pulse every 15-30 minutes (according to the length of the table's work cycle) , dosers feeds a specific amount of oil into the lubrication points. The feed drive is lubricated by spraying. '~he bearing unit of the guide screw is filled with plastic lubricant. Power table types UYe4532-UYe4537 with feed drive models UYe4722-UYe4727 are planned on the basis of ogerating experience of series UM power tables. Prototypes of power tables with electromechanical drives of the unified range of standard subassemblies were manufactured and tested at the Minsk ' Plant of Automated L'_nes. In the tests they checked out the basic precision parameters of the tables: selection from rapid stroke to working feed, ending working feed with cycling of the traveling selector, stop at the rigid detent. These data confirmed that the power tables of types UYe4532-UYe4537 completely satisfy the modern requirementS of modular machine tool construction. COPYRIGHT: Izdatel'stvo Mashinostroyeniye, STANKI I INSTRUMENT~ 1979 8617 - CS0:1821 50 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040240060016-6 FOR OFFICIAL USE ONLY METALWORKING EQUIPMENT UDC 621.9.06-112-229.2:62-233.1 MULTI-SPINDLE BOXES OF UNIFIED SERIES UNYE-3100 Moscow STANKI I INSTRUMENT in Russian No 5, 1979 pp 25-27 [Article by V. M. Lobusev, Ye. S. Tukayev and A. Ya. Frenkel'] [Text] In modular machine tools and automated lines, multi-arbor boxes are ;aidely used to perform operations of drilling, countersinking, scrolling, reaming, rolling, routing and thread cutting. Each modular machine tool is planned to treat a specific piece of work; thus the number of arbors, their rate of rotation and intercenter distances - beteen *.hem, as well as the diameters and types of cutters, is virtually unlimited. This is a substantial hindrance to tl~e creation of a completely unified spindle box. The problem is resolved by using unified elements and subassemblies, from which it is possible to put together spindle boxes for treatment of various pieces of work. The basic unified elements of multi-arbor boxs are related to housing parts, arbors, intermediate shafts, gears, drives, e.lectric brakes, thread cutting tail spindles and lubrication devices. - Based on analysis of the design of spindle boxes of domestic production and operating experience, as well as a study of the experience of several foreign companies by the Minsk Special Design Bureau of Automated Lines, unified etements of spindle boxes series UNYe3100 was developed. Spindle boxes of a unified series (Figure 1) have significant advantages over earlier units of similar purpose. The precision of output parameters - of the arbors in assembly (radial play and mutual parallelism) is 35 percent high on the average. This was achieved by making tolerances stricter on the manfuacture of arbors, housings and detent flanges; by the use of radial ball bearings of the fifth class of precision set into clear openings of the housing (which permits fine reaming from one side without rebasing the housing); and by elimination of the thread as a tie component _ of the ball bearings. - The use of double bll bearings assures greater durability of support of the arbor and doubles its rigidity. Because of a change in design of the S1 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY housing, the rear plate and the front cover, the rigidity of the spindle box was increased by a factor of 1.4-1.6 with an increase in weight of 20 percent. - Mechanical treatment of all external surfaces of housing parts permits thread cutting tail spizdles, conductor plates, lunettes and other auxiliary components to be installed without using special casting and ~ improves the outward ~ppearance of th~ item. The spindle box is symmetric on two axes and can be rotated '0�; this makes it possible to select its - optimum size and improve the ov~rall arrangement of the machine tool. - The use of variable arbor projections makes it possi~le to reduce to or~e tenth the n~~mber of variat~le bushings (mandrels), whose durability is 1/3 _ to 1/5 c� that of the arbor. The fitting diameters for the cutter. meet inter~~ational standards. - Electric couplings in the drives eliminate the effect of assembly accuracy . of the electric motor on the precision parameters of the spindle box; because of the absence of radial and axial loads on the electric motor shaft, the service life ot the latter is increased. Unification of components of spindle boxes makes it possible to have - cooperation between the manufacturing plants, increase technical and economic effectivness of the manufacture of parts in large lots, facili- tates the operation and repair at user plants; this is very important for such high productivity equipment as modular machine tools and automated lines. The system of component unification of the spindle box permits a reudction in planning labor intensivess with a signficant improvement of quality because of the use of computers; they perform geometric and power calculations of the design, sketch the overall appearance, print out the ac;,ompanying technical specifications and produce ~~nched tape for machine tools with ChPU which tr~at housing parts of the spindle boxes. T~chnical Specifications - Number of arbors 1-SO Maximum arbor projection 80-260 - Diar.;eter of fitting openings in arbors for v~:iable bushings (mandrel:~), mm 14;16;20; 25; 26; 28; 36; 44; 48; 60; 80 Arbor rpm 10-3000 ~ Size of box (wihout arbor) , mm: ~ thickness L 375-395 , breadth B 400-1600 height 360-1250 _ Maximum box weight, kg 2800 Motor output, kW 1.1-30 . ~ 52 = FOR UFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY - There are two modifications of the boxes--horizontal and vertical, which have different lubrication systems. The series UNYe-3100 contains 23 type sizes of spindle boxes with dimensions from 360 x 400 up to 1250 x 1250 millimeters (GOST 22586-77) and thickness of 375 millimeters. If it is necessary to attach conductor plates, lunettes, etc. to the front end of the spindle box, instead of the Eront cover 90 millimeters thick is placed a mc~re riyic] cear E~Late 110 millimeters thick. In this case, the thickncs:; of the spindle box is 395 millimeters. The size of the spindle box is mainly determined by the position of arbors and the minimum distance from the arbor to the side wall of the housing, necesary to install ~~he gears and arbor supports. i _ _I~ , -1 ~ - 1 2 Q) 3 1 6) - - Figure 2. Installation of spindle box on power table: a) using gasket plate; b) using detent bracket. - Spindle boxes of series UNYe-3100 are mounted (Figure 2) on standardized power table s(1) and attached with either a detent bracket (3) or directly - to the table using a gasket plate (2). The size of the detent bracket (GOST 22585-77) corresponds to the size of the power table. But if needec7, a smaller detent bracket can be installed on the power table. Below are cited the data of applicability of spindle ~ boxes as a function of the type sizes of the power table and detent - brackets. Type size of power table (detent bracket) 2 3 4 5 6 , Size of spindle box (HXB), mm: minimum 360x400 360x400 450x500 SOOx630 630x800 800x1000 maximur.~ 400x500 500x800 630x1000 800x1250 1000x 1250x 1600 1250 Number of type sizes of spindle boxes mounted on power table 2 6 9 12 12 9 The maximum number of type sizes of ~pindle boxes can be installed on tables of type sizes 5 and 6 used most commonly. 53 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 rvn vrr l~lrw uoc V1VLT The applicability is determined on the basis of requirements of maximum - rigity of the spindle box/detent bracket system in order to eliminate overturning momentum (which occurs in reaction to the weight of the spindle box) and total bending moment (which occurs in reaction to axial cutting loads), which have a negative effect on table operation. I~ I I I xs n a , - _ _ - .14 ~ - - / ~ � % � ~ lj % / -I!. / _ . J~r. - " - ~.JZt-�^~ 1~ /1 - - - - - - ~ _ . . _~'''`L"' - - - I ~ ~'.irTy';r`.�_ ~ ~p 'c i / ~ \ ' % ~ 9 _ ~ ~ ~ ~ - ~ ~ 1 3 f S 6~ Figure 3. Drilling spindle box. I'igure 3 depicts a standard drilling spindle box of series UNYe-3100. The set of cast parts of the spind].e box of each type size includes a rear plate (2), by means of which the box is attached to the connecting flange of the detent bracket (1) ; a ho~~sing (151 which carries su~ports of the arbors and intermediate shafts; a front cover (7) which serves as a reservoir for lubricating vertical spindle boxes and a cover (3) which seals the assembly windows of the housing. In the box housing are mounted the arbors (13), intermediate shafts (10), drive shaft (6) of the pump and a shaft (14) for manual rotation of the arbors. With large projections or diameters, the arbors are mounted in � bushings (11). The blade pump (8) lubricator is mounted on the front cover (with piping outside the housing) or in the housing under the front cover (with piping inside the housing). In the latter case, in the front covers of large boxes a window is cut (covered by a special cover) which makes it possible to ~ change the lubricant pump without taking apart the heavy front cover. The arbors and intermediate shafts are locke~3 in the axial direction by stoppers and expansion rings. The arbors are mounted on radial ball 54 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 . I ' FOR OFFICIAL USE ONLY / ; % : ~ 4 . _ � i; ' ~ _ ~ , . . � ~:.r:c�:s:~~: . j'/ � S _ ~ ~"i: 'i1AY1~ . ~ � r~.r". ...~L ~~,R.:,1~ ~Qf.:::]14:~ B' li~ii'vi~""";J _ ~a ~ i . T ~ ~ 3 - - j'tt-- - - - - - ~ - - - ~ � _1 ~ - \6, 7 Q 1 \ r. ~ ~ ~ 4�--. _ ~ \ - Figure 4. Thread cutting spindle box. - bearings (5). The thrust bearing (12) absorbs axial loads. The in- - termediate shafts are mounted on radial ball bearings. Rotation is transmitted from the electric motor (17) to the arbor through an elastic coupl.ing (16). The required rate of rotation of arbors is assured by a system of gears (4) mounted in four rows (I, II, III and IV). The gears (9) (row I) placed~under the front cover can serve as replaceable gears if it is necessary to change the rate of arbor rotation. Each spindle box has a sealed circulation lubricating.system consisting of ~ a pump, inlet and pressurized pipelines, oil distributor, discharge tube - and chute. The reservoir is the housing of the spindle box. Oil is gravity fed from the chut into the gears of rows II and III. - In contrast to spindle boxes, the vertical model has a chuteless - luk~rication system and all the oil flow from the oil dzstributor is directed to row IV of the gears, whence by gravity it flows to the other gears and bearings. In the lubrication system of thread utting spindle boxes, a reversable type pump and oil distributor with exterior oil tap to the electromagnetic brake coupling is mounted; the oil is gravity fed back to the spindle box. The cover of the oil distributor is made of a transparent organic class which makes it possible to use the oil distributor as an indicator of operation of the lubrication system. The folloiwng oils are used for lubrication: I- 30A, I-40A, I-50A (GOST 20799-75). 55 FOR OFFICIAL USE ONLY ~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 L va~ VL ~ 1v~.~aL vuu ~/L\La Standardized spindles have kwo diameters series of fitting holes for the variable bushings (mandrels) in conformity with GOST 13876-76 and a - variable projection. An element which determines the minimally permissible intercenter distance between the arbors (see table) is the radial ball bearing. The thickness of the baffle in the housing wall between the two bearings must be at least three millimeters. When planning a spindle box it is necessary to consider the number. of openings and their juxtap~sition as well as the minimally permissible th;ckness of walls so that total axial force on the housing is not critical. When working under conditions of abundant ~ooling of the cutter, the spindle ~~oxes require protection against the entry of cutting fluids. Protection is provided by contact or contactless labyrinth gaskets, screening or cut-off by compressed air. In spindle boxes of series UNYe-3100, gear wheels of the sixth (at circular velocities over 6 meters per second) and seventh degree of precision with polished teeth are used. The width of the gear hub is constant and equals 40 millimeters, the width of the gear rim depends on the modulus. Thus a - gear with modulo 2 and 2.5 millimeters has a rim width of 25 millimeters; with modulo 3, 4 and 5 millimeters--a rim width of 32 millimeters. The minimum number of teeth is 17, the maximum 80. In the design of the spindle box it is possible to build in several auxiliary mechanisms: to monitor torque on the arbor (to protect the cutter _ against breakage), to adjust and lock the arbor in a desired position, to increase or reduce feed of individual (as a rule one or two) arbors with respect to feed of the entire spindle box. tndividual unified elements of the spindle boxes of series UNYe-3100 can be used successfully in�plunning drives of reaming chucks of original design. Thread cutting spindle boxes are a modification of drilling spindle boxes. The constant working feed per rotation of the screw tap is achieved by using individual copying nuts for each thread cutter. The thread cutting spindle boxes can be stationary; such horizontal boxes are mounted, as a rule, on side platform beds, while vertical models are mounted on bases. ~.~e thread cutting box (Figure 4), in contrast to the drilling one, has an attachment (2) with thread cutting tail spindles (7) mounted on the front cover of the box on rods (4); a mechanism (8) which controls the thread cutting cycle and is mounted on the front cover, rear plate or side wall of the housinq; and an electric brake (5) with electromagnetic coupling. After being rotated by the shaft (6), the arbor (3) travels along the copying nut (1) which has the spacing of the thread to be cut. A spring (not shown in Figure 4) compensates for misalignment of spacing (within 56 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY manufacturer's tolerances) of the copying nut and screw tap. Spindle boxes of the unified series UNYe-3100 manuEactured by the Stankoagregat Plant (Moscow) and delivered by cooperation of several machine tool construction plants, have been awarded the State Seal of Quality. - COPYRIGHT: Izdatel'stvo Mashinostroyeniye, STANKI I INSTRUMENT, 1979 8617 CS0:1821 57 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 � vi~ VL' a' ~.~.1t~L UJL' VLVLL . METALWORKING EQUIPMENT IiIS'TORY aF F1VL-YEAR 1'LANS FOR MACHINE TOOL AND TOOL BUILDING - Moscow STAtdK? I INSTRUMENT in Russian No 6, Jun 79 pp 1-3 [Article: "The Victorious Path ~f Our Five-Year Plans") [Text] At the end of April 1979, the SOth Anniversary of the approval of the First Five-Year Plan for Development of the National Economy of the USSR by the 16t~z Confer.~nce of the All-Union Communist Party of Bolsheviks, and in May, approval of the Fifth Ali-Unton Congress of the Soviets. In the resolution of the Central Committee of the CPSU "On the 50th Anniversary of the First Five-Year Plan for Development of the National Economy of the USSR" the magnitude and significance of the socialist five- year plans with which the enormous achievements of our country have been continuously connected in all branches of economic and cultural development, are clearly revealed and analyzed. rifly years ago, the heroic struggle of the Soviet peoples for implementa- tion of the I'irst Five-Year Plan, which played a prominent role in the _ realization of Lenin's Program for the building of socialism in the Soviet Union, developed in the direction of the Communist Party. The realization of the First Five-Year Plan insured the creation of a strong material base for the building of the socialist society. The successful execution of the First Five-Year Flan dashed the hopes of the imperialist reaction to see the Soviet Union fail economically. The outstanding historical significance of the First Five-Year Plan also consists in the fact that it was the beginning of the application of five- year assignments in the basic form of economic planning, and it converted them to the large organizing and nobilizing force of the building of , communism, in the matter of proving the superiority of socialist methods of economic management over cagitalist methods. Successively carrying out the f ive-year plans for the development of the nattonal economy, thr Soviet people, under the leader.sliip of. the Communisl ~Party, insured unheard-of rates of economic and social conversion and the growth of power of our country. 58 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY In Cfu~ tl~rec~ lncantple~Cu prew,tr l::lv~~-year ~ilanb our pec>plc~ cc~mpletecl l~l~e feat of industrialization of the country and collectivization of agriculture, it insured its defensive capacity, providing a strong, material-technical base for our victory in World War II. The epagee of the postwar restora- tion and development o� the national economy augmented this feat. Ttie scales of the construction increased especially in the phase of making the transition to the developed socialism and under the conditions of developed socialism. A powerful economic and scientific-technical potential for mature socialism was creuted in ttie country. The volume of industrial production in the Soviet Union presently exceeds the 1928 level by 128 time.s. The core of ~he economic policy of the CPSU is insurance of a stable, balanced development of heavy industry the foundation of the economy. In 1978 the production of ineans of production in industry (group A) had increased by 272 times by comparison with 1928. Thanks to the planned use of the advantages of the socialist economic sys- tem in the USSR, historically unheard-of rates of development of industrial production were achieved. In the last l0.years the volume of industrial production in the USSR was doubled. At the same time Great Britain required - 29 years to double its production, the Federal Republic of Germany, 18 years, France 17 years, and the United States 16 years. On ttie eve of the first five-year planning period, the country had 24 million scattered peasant businesses equipped with a primitive inventory. At the present time the agriculture of the USSR is a large, mechanized production facility in which the processes of specialization and concentration based on intereconomic cooperation and agroindustrial integration are taking place actively. _ The first five-year planning period opened up the broadest space for realiza- tion of the cultural revolution. Today complete middle education of the youth is realized. Every fourth scientif ic worker and every third doctor - on our planet are citizens of the Soviet Union. A Soviet man was the first in the world to penetrate outer space. The Soviet five-year planning periods are also plans for the social progress of our country. They serve in the achievement of the highest goal of the socialist social production the most complete satisfaction of the material and spiritual needs of the pe~ple. Using the advantages of the centralized planning, the socialist society eliminated unemployment in the First Five-Year Plan while tens of millions of workers in capitalist countries are continuing to suffer fro�n unemployment. From five-year period to five-year period, the actual income of the popu- lation, the payments and advantages fr~~m the social funds, the retail commodity turnover of the state and cooperative trade are growing; national _ 59 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 rUx urrl~t~ U~~: UNLY education and public health are developing continuously, the living and working conditions of the Soviet people are improving. One of the most important social problems the housing problem -Is being solved success- _ fully. In the country about ll0 million square meters oF living sp~zcc~ arcr put into operation every year; 11 million citizens have been moved to new apartments or they are improving their own housing conditions. The apartment charge has remained unchanged for a half century. An important and ever-increasing role in t}ie standard of. living of thc Soviet people is being played by the social consumer funds. The payments from these funds amounted to 105.5 billion rubles in 1978 as opposed to - 90.1 billion rubles in 1975. At the present time the Soviet Union occupies f.irst place in the world with respect to support of the population with medical ~;ersannel. Last year Sl million people took rests G~ the sanatorium and hEaJ.th resort facilities, rest houses and tourist bases. The Communist Party, developing and realizing the Leninist plan of industrial- ization and development of heavy industry, solidly aiid consistently has - followed a course to thP creation of a powerful base for Soviet n~u~.tibranch machine building. The 14t~ Congress of the A11-Union Communist 't'arty of Bolsheviks adopted exceptionally important resolut3.ons in December 1925 defining the general development of Soviet machine building industry. In accordance with the goals stated at tY~e Congress, the USSR was to be con- vertc~cl from the country which imported machines and equipment to a country tltat produces them in an amount which would permit us not to depend on the capitalist world economy. lluring ttie years of the First Five-Year Plan, the mean annual growth rates of gross production with respect to industry as a whole were 19.2%; with respec,: to machine building and metal working Che rates were 41.3%. Branclies of machine building which have not existed before arose in the country. These included tractor builcling, automobile construction, machine tool building, agricul~ural, chemical, mining and metallurgical machine building, and the aviation industry. The process of the growth of the capacities of Soviet machine building continued at accelerated rates also in the Second Five-Year planning period. The gross production of the branch inereased by 2.8 times during these years. The f irst years of �urk by the Third Five-Year Plan noticeably advanced machine buildin~. Its production incre.ased by almost 1.8 times in 1940 as opposed to 1937. The Soviet machine building advanced to first place in ~urope and to second in the world. The far-sightedness of the policy of the Communist Party played an excepr_ional role in the preparation of our industry ior the conditions of war time. The high level of development of machine building during the years of the girst.five~year ~lanning periods made it possible quickly to assimilate and persistently build up the production of materiel and ammunition. 60 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY In accordance with the requirements of the national economy, even in the subsequent five-year periods machine building developed and is developing at leading rates. The fixed industrial-production capital of machine building and metal working at the beginning of the Tenth Five-Year Plan amounted to more than 25% of the value of the capital of the entire country. In solving the problems stated by the 25th Congress of the CPSU with respect to ttie growth of the productivity of labor in the national economy, _ i.mprovement of tlie efticiency of social production and acceleration of scientific and technical progress, the role of machine building will per- sistently increase. Tl~e development of the machine tool building and tool industry is organically connected with the development of Soviet machine building in accordance with the f ive-year plans. From the First Five-Year Plan to the present time the scientific aid technical progress in machine tool building has been determined by the development of machine building production, improve- ment of the metal working processes, raising of the technical level of mactiine building production. The collectives of the enterprises and organizations of the machine tool building and tool industry, widely celebrating the 50th Anniversary of the First Five-Year Plan for Development of the ~iational Economy of the USSR, are simultaneously celebrating the 50th Anniversary of the creation of Soviet machine tool building as an independent branch. In June 1929 the Council of Labor and Defense of the USSR decided to organize the State Trust - for Medium Machine Tool Building, which established the beginning of the formation and development of the si~ecialized production of inetal cutting mactiine tools. '1'I~e C;unununist Party and the Soviet Government have given a great deal of attention to ttie development of machine tool building, the design and con- struction of machine tool building and plants, and the training of special- ists. ror the training of the designers, technologists and researchers, the Moscow Machine Tool and Tool Institute was created, the machine tool building departments were organized under the ~iVTU imeni N. E. Bauman and ttie Leningrad Polytechnical Institute imeni M. I. Kalinin. In 1933, the Experimental Scientific Research Institute of Metal Cutting Machines (ENIMS) was built. The ENIMS has priority in the creation of ' theoretically new processes and equipment; all phases of technical pro~ress - of Soviet machine tool building are connected with its activity. During the years of the First Five-Xear Plan, the Moscow Machine Tool Building Plant imeni Sergo Ordzhonikidze, the Gor'kiy Milling Machine Plant, - the Moscow Kalibr Tool Plant, i~foscow Frezer Cutting Tool Plant imeni M. I. Kalinin were introduced into operation. lluring the years of the Second and Third Five-Year Plans, machine tool build- - ing proceeded with the assimilation and production of special and specialized 61 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR GFFICIAL USE ONLY machine tools rec~uired by the developing branches of m~.chine building. During this period, the Khar'kov Machine Tool Building Plant imeni S. V. Kosior, the Kiev Automatic Machine Tool Plant imeni M. Gor'kiy, the Saratov Plant for Heavy Gear Cutting Machines, and so on went into opera- tion. In.1939 Che Kramatorsk Heavy Machine Tool Building Plant imeni V. Ya. Chubar' was put into operation. In tlie prewar period of development of Soviet mact~ine tool building, tlie types and sizes of all forms of universal machine toals were expanded, and the production of special Machine tools was assimilated. The production of large machine tools and the first unit machines was started. The unit machines served as the basis for the subsequent creation of automatic machine tool tines. Beginning with the first year of World War II, machine tool building was converted to the filling of the orders of the military industry and the production of machine tools for the def~nse branches. During the war years large machine tool building enterprises were organized on the basis of the plants evacuated to the eastern regions of the country, and the new plants were also built. In the Fifth Five-Year Plan, the production of large, heavy and unique machine tools developed. The production of vertical lathes for machining products with diameters to 16,000 mm, gear-milling machines with ma.chining diameter to 5,000 mm, screw-cutting lathes with machining diameter to 4000 mm and spacing between centers to 30,000 mm, and so on was mastered. This period was also characterized by the development of the production of automatic lines. The creation of complex automated proc'uction of automobile pistons was a great technical achievement. Another important step in the technical development was the wo~K with respect to creating the complex automated shop at the GPZ-1 for the production c~f ballbearings and roller bearings with a total number of 1.5 million per year. All the machining operations, the monitoring, assembly, anticorrosion treatment and packing operations were automated. During the postwar years the large machine tool building centers were created in the RSFSR, the Ukrainian SSR, the Belorussian SSR, the Georgian SSR, the Lithuanian SSR, the Armenian SSR. At the present time the Soviet machine tool and tool industry includes specialized enterprises for the production of inetal cutting machines, automatic and semiautomatic lines for machine building, forging and pressing and casting equipment and also equipment for the woodworking industry. The branch also includes plants for the production of inetal working tools, abrasive and diamond tools. In 3 years of the Tenth Five-Year Plan, 707,000 metal cutting machines and 161,700 forging and pressing machines were built. In tl~e overall produc- tion of inetal working equipment, the proportion of forging and pressing 62 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY machines is increasing. This corresponds to the trend in the development of machine building tectinology. Thus, i.n 1978 the proportion was 19% as opposed ro 15.6% i?i 19f~5. Tt~e most characteristic feature of scientific and technical progress in tlie - field of creating new types of machines, machine tools and equipment (along - with increasing their productivity, precision and reliability) is a higher level of automation of control of the basic mechanisms, the production processes and quality of manufacture. The types and sizes of automated equipment are growing from year to year. In ttiis respect, a'i:road transition to the creation and the production of inetal working equipment ~aith digital programmed control is charactE~ristic. Thus, in 1978, 7300 machine tools with digital programmed control were manufactured as opposed to 1588 in 1970. During the 1970-1978 period, the national economy also included more than 40,000 machine tools with digital programmed control, among which the pro- portion of multiple-tool machine tools with devices for automatic tool changing is increasing. The rates of production of machine tools with digi- tal programmed control will also increase in subsequent years. Machine tools with small electronic digital programmed control systems are finding broad application. Operations are continuing with respect to the creation of complexes of hifih-output metal-working equipment controlled from computers. Beginning with the problems stated for machine building by the 25th Congress of the CPSU in the area of increasing the productivity of labor and increas- ing the production efficiency, the collectives of the enter~rises and organizations of our branch must work still more purposefully on creating a broad nomenclature of the most improved, automated equipment. By the end of the current five-year period, it will be necessary to ;.nc.rease the production of automatic and semiautomatic lines by 1.7 times, special and unit machines by approximately 1.5 times, forging and pressing automatic machines and presses with feed and receiving mechanisms by 2 times by comparison with 1975. It is also necessary to expand the output of forging and pressing and casting machines with programmed control. In tiie area of casting machine building, new sets of machines have been built for special methods of casting and for automated flask and flaskless forming lines, lines for manli�~cturing cores, machines for the preparation and distribution of mixes based on ucw '�-inders, and so on. Important technical problems are being solved by the branch with respect to the production equipment for the woodworking industry. By the end of the five-year planning period, the production of woodworking equipment will increase by more than 1.5 times by comparison with 1975. In this case the proportion of automated equipment in the overall production volume will be 31% in 1980 as opposed to 14.2% in 1975. - 63 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 r~oK ur~r'iCIAL USE ONLY Important goals have been set in the Tenth Five-Year Plan for the enter- prises and organizations of the tool ind ustry. Tool production is expand- ing witti the application of natural and synthetic diamonds and other super- hard materials and alloys; a large nomenclature of high-precision tools, tools for automatic lines and for machine tools with dig~ta.l programmcd r.ontrol liave been assimilated, Thc~ procluction of t~ols with n~nreshar~,cn- able hard-alloy tips is to be increased by 3.8 timcs by the end of thc five-year period by comparison witli 1975. Its proportion in the overall production of hard-alloy tools will increase to 44-45% in 1980 as opposed to 15.6% in 1975. The production of cutting tools from superhard synthetic materials is developing at liigh rates. The production of tools from tungsten- _ free liard alloys and mineral ceramics has been organized, The improvement of the qualtty of the tools is one of the most important goals of specialized tool pla,:ts. In the tool industry, the production of abrasive and diamond tools has great specif ic weight. The abrasives industry is producing a broad nomencla- ture of abrasive tools, including elbore tools. Abrasive tools using bakelite binder for power stripping will increase the productivity of the machining by almost 3 times. The production of tools based on ceramic binder for precision thread and gear grinding and for high-speed grinding has been assimilated. The production of cutting tools based on cubic boron nitride is increasing, which will provide a savings of hard alloy. - A significant increase in the product~ion of new and improved types of abrasive tools is the main goal of the remaining two years of the tive-year period. The proportion of basic tools in the tool production will be 26.9% in 1980 as opposed to 3.1% in 1975. The production of abrasive tools made of elbore will more than dcuble. Tlie prodigy of the last five-year planning periods is the branch for the production of diamond tools. At the present time almost all forms of diamond tools known in world oractice are being produced in the USSR. The Soviet Union has become a large e:cportc~r of tools made from synthetic and other superhard mat~rials. The production of diamond tools had increased by 8 times in 1975 by comparison with ].965, and during the Tenth Five-Year Plan it has increased another 1.8 times. The production of diamond tools in the Soviet Union is distinguished by a high level of concentration and specialization. In recent years, the pxoduction of monocrystalline and - polycrystalline diamonds has increased significantly. The planning system for the socialist method of production has made it possible in the shortest possible time to achieve high levels of development of Soviet machine tool and tool industry. The five-year plans have at each stage of econamic development of our country determined the goals of _ the branch; they have insured concentration of material and financial resources f.or their solution. 64 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY 'llie collectivcs of the enterprises and organizations of the Ministry of ttie Machine Tool Industry are celebra~ing the 50th Anniversary of the Machine Tool and Tool Industry with great achievements in the fulf illment of the goals stated by the 25th Congress of th e CPSU. Tl~e production workers, engineering and technical workers and office wo rkers of the branch have widely developed socialist competition under the motto _ of "All new reserves f or economic growth into action." The workers in the - machine tool and tool industry will celebrate the SOth Anniversary of the . . First Five-Year Plan of Development of the National Economy of the USSR which played a prominent role in the realization of the Lenin program for tlie building of communism in the Soviet Union, by fulfillment of the social- ist obligations adopted for 1979. COPYRIGHT: Izdatel'stvo Mashinostroyeniye, STANKI I INSTRUMENT, 1979 10845 CSO: 1821 65 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02108: CIA-RDP82-00850R000200060016-6 F012 OFFICIAL U5~ ONLY MI:TALWOt:KING LQUIPMENT UDC 621.9.06-529-183.2:681.586 ANGULAR COORDINATE GAUGE FOR DIGITALLY-PROGRAMMED MACH INE TOOLS Moscow STAP~I I INSTRUMENT in Russian No 6, Jun 79 pp 22-23 [Article by G. A. Lebedev, L. Ye. Kraytman, A. M. Tuv: "Angular Coo?�dinate Gauge for Heavy Machine Tools With Digital Programmed Control and Digital Display" J [Text] Among the large number of designs o~ feedback sensors for angular - measurements, the most widespread are r.he selsyns, rotary transformers, reductosins (redusins), inductive converters, circular inductosins, and so on [1-3]. However, their use in the assemblies of heavy and unique machine tools is complicated for the following reasons. When joining the sensor to the axis of rotation of the aGsembly, an additional error arises (reaching - 15" [4]1 as a result of noncoaxialness and eccentricity. In addition, building in the sensors in areas which are difficult of access inside tl~e rotating assembly complicates its installat~on, operation and maintenance. _ Tl~ese c1e,Liciencies can be eliminated if the sensor is made in the ..orm of a device which permits measurement of the linear displacements of the assembly with respect to the arc of a large-radius circle (the measurement precision - is higher, the larger this radius), and it is a structural part of the _ assembly. On the basis :,f the rectilinear contactless transmitting selsyn of the PBSD type used in the machine tools with digital programmed control produced by the Novosibirsk Tyazhstankogidropress Plant imeni,A. I. Yefremov, experimental � and experimental-industrial models of angular contactless transmitting selsyns were developed, manufactured and tested. This sensar (Fig 1, a) has a gear ~y scale 1 executed in the form of a ring ~or a part of a ring) and fastened to the rotary assembly, and a stationary magnetic circle 2 with poles. The phase and output windings are arranged in a defined sequence of the poZes. _ The phase A windings are located at the poles nA and are opposite-series connected. The phases B and C windings are located correspondingly on tHe poles t1B and ]I~, and they are joined analogously, In order to receive a - large signal and decrease the error caused by inaccuracy of manufacturing the scale and the ,nagnetic circle, the number of pairs of the poles for - each phase will increase by comparison with the minimum number equal to two. 66 - ~ FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-00850R000200064416-6 FOR OFFICIAL USE ONLY ' s c ~ e a` / s o` /j` _ . A p~ d~ n, T . , _ ` Z / � � i . t t f b~ a) Figure 1. Schematic diagram of a gauge (a) and diagram of the installation of magne.tic circuits for the compensation of errors caused by beating of the scale (b) When an alternating current is fed to the wind~.ng EF in the phase windings there is an emf induced which on shifting the scale with respect to the magnetic circuit varies in accordance witli a law which is close to sinusoidal. On stiifting the toothed scale by an amount that is a multiple of one angular step of it, the voltage in each phase varies by complete period, ' that is, by 360 electric degrees. The shift between phases is 12Q electric degrees which c~rresponds to displacement of the scale by 1/3 of a step. This gauge, similar to the ordinary selsyn can operate both in the trans- _ former mode and in the phased mode (in the latter case the windings A, B and C are fed by a triple-phase voltage, and the voltage phase in the EF winding is a function of the scale position). The angular pitch aM of the poles ~f the magnetic circuit of the sensor and the angular pitch a of the scale teeth are related to each~other by rhe rel_ation aM=aP (2qn~+1)/(2q), where q j.s the number of pllases of the sensor; n=1,2,3... is the structural coefficient. 7'he angular pitch of the scale is determined from the condition that the discreteness of the digital display is 0.001� (3.6") and that the digital _ ~ programmed control unit Razmer 2M divides the period of the output signal of the sensor by 200. Beginning with this, a=3.6"�200=12', and the number of teeth zp=360�/12'=1800. For the experimen~al model of the sensor (n=2, q=3) aM=26'. The angular scale is a toothed rim of diameter DP cut by the modular cutting tool (m=1.25 mm). The effect of the errors in manufacturing the teeth und the oscillation of the scale and also the deviations of its shape frbm circular on the accuracy of reading the coordinates can be signi�icantly decreased if thE magnetic circuit 3(see Fig 1, b) is placed diametrically opposite to the magnetic circuit 2, and their out~ut wind- ings are connected in opposite series. 67 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 . run Urrll,tt~L u~~. UNLY In order to decrease the intrapitch error of the sensor, the magnetic circuit 3 is shifted with respect to magneCic circuit 2 by half the . angular pitch in the scale, that is, by 180 electric degrees. In this case ~he basic harmonics of the intrapitch error with corresponding inclu- sion of the output windings are mutually compensated. For more complete error compensation it is possible to place severai pairs of ma.gnetic circuits around the scale, joining their output windings. Tliis design has tl~e fol.lowing advantages: 1) high precision of ineasuring the rotation of the assemblies of the heavy machine tools; 2) the possibil- , ity of using digital programmed control units applied on heavy machine tools for programming the rotation of the assembly; 3) convenience of l-.lie installation and operation and maintenance of the sensor. A11 of this per- mits bro~rl application of the sensor in heavy machine t~ol building: on the sJewing tables, vertical lathes and also rotazing stocks, the planing and milling slides of the combined and specialized longitudinal-machining � machine tools. , When testing (Fig 2) the experimental model of the sensor for reading the angles of rotation, the modules of the digital display type.F5071 and Razmer 2M-1104 were used. The error ~f the sensor was estimated in the scale pitch interval (12') by a glass optical rule using the OMS-6 micro- scope where the displacement by one micron on the scale of the rule corresponded to rotation of the tooth scale by 0.1�39". The discreteness unit of the module F5071 (on switching it to the "Diametr" regime) corresponded to rotation by 0.36", ancl the unit of discreteness of the _ Razmer 2M-1104, rotation by 3.6". The intrapitch error of the sensor when combining the output windings of two eliametrically oppositely arranged magnetic circuits was on the average 4-5," rhat is, it was co~nensurate with the discreteness of the digital programmed control unit. ,f ~r 5 . . _ L ; , f . I ~ ,M,, . ~ _ , i ,i '1 Figure 2. Device for testing and experimental model of a sensor: - 1-- digital display module type F5071; 2-- reading microscope with scale division 1:nicron; 3-- magnetic circuit; 4-- optical rule; 5 toothed scale 68 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY n��'r~" ~ 1) ' ~ i ~ ~ z ` ` J , ~ ~ ~ p . ' ~ .i . J IO 90 --tSQ.' /B0 ?10110i70JO~R JJ9 JQO 0 60 90 1 0~'!a0 1lU140 t10J ~~ytpad ~ ` ` _t_i'" ) 1�u o om 1-rr o opam ~ ,yt~s o) ?0 /0 ~ / _ 90 ~ o__ o -tra o n~~> , �p , ' ~ ~ t ?t0 JO t _ b) . Figure 3. Accumulated error ~ of the sensor with respect to ~ the angle ~ of rotation of the toothed scale: a-- for testing of an experi.mental model of the sensor on a bench; b-- when testing the experimental-industrial model of the sensor on the model NS-3 rotary table Key: l. angular seconds 2, degrees 3. lst rotation 4. 2d r~tation In order to determine the accumulated scale error, a theodolite with scale division.of 1" was instelled coaxially with it on a rod 800 mm high; the mark was fastened to the opposite wall of the shop at a distance of 20 m - f.rom the theodolite. The toothed scale was rotated manually, noting the angle of rotation every 10� with respect to the digital display module. At the indicated points the angle of rotation was monitored using the tl~eodolite, and after every 90�, also using optical rules and OMS-6 micro- scopes. The accumulated error ~(Fig 3, a) was determined on connection of both two and four magnetic circuits. It was established that for two connected magnetic circuits the accumulated error was 10" for measurements with a range of 90� (curve 2) and 17" for measurements with a range of 10� (curve 1). On connection of four magnetic circuits, the accumulated error could be decreased to 2-3" for measurements with a range of 90� (curve 4) and to 8" for measurements with a range of 10� (curve 3). It is also necessary to consider that the instability of the measurements using the theodolite is 5-6". The experimental-industrial model o� the sensor was developed considering installation of it on the model NS-3 rotary table which was equipped with the "Razmer 2M-1104" digital display. The latter made it possible to realize preliminary selection and automatic positioning both with respect - to the displacemenr. coordinate of the slides and with respect to the angular coordinate. 69 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02108: CIA-RDP82-00850R000200060016-6 run Urrt~ttu. u~~ UNLY Technical Specifications of the Table Dimensions.of the operating surlace, mm :?o00:K3600 Greatest displacement of the slides, mm 2000 Rates of displacement of the slides with respect to the bed (continuous regulation), mm/min 13-1360 Rate of rotation of the rotary section, deg/min 2.5-169 Discreteness of the digital display: displacement of the slides, mm U.O1 rotation of table, deg 0.001 Lift capacity, kg-force 50 000 Overall dimensions (lengthXwidthXheight), mm 5700x4250~:i200 Weight, kg 36 000 The parameters of the experimental-industrial model of the sensor are as follaws: DP=3600 ~n; z~=1800; m=2 mm; aM=14'. The structural design for the attachment of the sensor provided for the maintenance of constant currents between the scale and the magiietic circuit independently of the beat of the sc ale. ~ During tests on the first four tables sensors were installed with two magnetic circuits arranged diametrica111� opposite. Their series-counter connected output windings are connected to the channel for exact reading . of the Razmer 2M-1104 device; the selsyns of the type B2RG multibit sensor, the output gear of which with z=20 teeth was engaged with the toothed rim of the scale were connected to the remaining channels. This method of connection is explained by the fact that in contrast to the digital display module type F5071, which is a cyclically absolute system and outputs complete information about the displacement of the ob~ect on connection of only one precision sensor to it, the Razmer 2M-1104 device is among the absolute systems and requires installation of a multibit sensor. The accuracy of the rotation of the table and the emergence of it at the given coordinate was determined using a theodolite installed on a mandrel with respect to th~ center of the table. In order to check the stability and the error in the pitch interval of the scale, in addition to the theodolite, a clock type display was used with scale division of 0.01 mm in contact with a support located on the edge of the table at a distance of 2000 mm from the center; a displacement by 0.01 mm with respect to the dis- play corresponded to rotation of the table by 1". In order to check the stability o� the development of the preliminary selection on the panel, the same coordinate was selected a multiple number of times to which the table was fit automatically. The dispersion of the readings with res~ect to the display did not exceed 0.02 mm in this case, which corxesponds to half the value of the discre~eness. ~ Giving the displacements with an i.nterval of 72", the pitch angle of the scale (12') was passed through 3 times; the maximum accumulated error in FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 FOR OFFICIAL USE ONLY this interval was 11". The error for a complete rotation of the table was determined (with an interval of 10�) with connection of both each magnetic circuit individually to the system and the combined windings of two magnetic circuits. As is obvious from F'ig 3, b, the errors from the individually _ ~ connected magnetic circuits (curves 1 and 2 respectively) did not coincide with respect to sign (for the magnetic circuits are arranged diametrically opposite); the maximum error is ~46". This error is cottmiensurate with th~ component caused by beating of the scale (e=0.45 mm) and it is equal to ~p= 4e/DP=52". For jointly connected magnetic circuits the maximum error is 17" (curve 3). Thus, the installation of two diametrically opposite magnetic circuits with corresponding connection of their windin.gs to a significant degree decreased the error component caused by eccentricity of the sc.ale. The installation of four magnetic circuits at an angle of 90� also compensates the error components caused by deviation of the shape of the scale from a circle. BIBLIOGRAPHY 1. Abramzon, E. L. "Inductive Rotary Table with Programmed Control," METALLOREZHUSHCHIY I KOIV'TROL'NO-IZMERITEL'NYY INSTRUMENT [Metal Cutting and Monitorii~g and Measuring Controls], Nauchn.-tekhn. ref. sb. (NlImash), No 12, 197?.. 2. Akhmetzhanov, A. A. SISTEi~iA PEREDACHI UGLA POVYSHENNOY TOCHNOSTI [System for Transmitting an Angle with Inereased AccuracyJ, Moscow, Energiya, 1966. 3. Akhmetzhanov, A. A.; Lukinykh, N. V. INDUKTSIONNYY REDUKTOSIN [Induction ReductosinJ, Moscow, Energiya, 1971. 4. Bychatin, D. A.; Gol'dman, I. Ya. POVOROTNYY INDUKTOSIN [Rotary Inductosin], Leningrad, Energiya, 1969. COPY.RIGHT: Izdatel'stvo i~lashinostroyeniye, STANKI I INSTRUMENT, 1979 - 10845 CSO: 1821 71 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY METALWORKING EQUIPMENT UDC 621.914:4:061.4(437) - EXHIBIT OF SPECIALIZED MACHINE TOOLS FROM SOCIALIST COUNTRIES Moscow STANKI I INSTRUMENT in Russian No 6, Jun 79 pp 34-36 _ [Article by 0. I. Aver'yanov: "Machine Tools of the Drilling-Milling- Boring Group at the First Specialized Exposition of Metal-Cutting Ma.chine Tools and Forging and Pressing Equipment From Soc,ialist Countries"] [TextJ During the period from 8 to 16 November 1978, in Brno (Czechoslovakia) the FirsC Specialized Exposition of Metal Cutting Machine Tools and Forging and Pressing Equipment from Socialist Countries was organized (the People's _ Republic of Bulgaria, the Hungarian People's Republic, German Democratic Republic, Polish People's Republic, the USSR, Czechoslovakia and Yugoslavia were represented). At the exposition, 140 units of equipment were shown, among which about 25% represented machine tools of the.drilling-milling- boring group with manual control and with digital programmed control. In the proposed article, a study is made of the most interesting machine toois of this group reflecting the trends.in the development of world machine tool building. The basic advantages of the multitool machine tools . shown at the exposition are the broad technological possibilities of machining, the high degree of automation (about 80% of the represented _ machine tools of the i.:vestigated group operate in the automatic control - mode), and use of modern digital progratmned control systems. ~ The People's Republic of Bulgaria presented an interesting complex made up of two jig-boring machine tools, model RV 001 (equipped with 8-spindle turret heads) and a robot which loads the machined parts. Each machine tool is.equipped with a digital programmed control system, model Programma 30. In addition, it is possible to note the producCive universal model RV 110 milling machine with~manual control. ~ From among the machine tools of the Hungarian People's Republic it is nece~sary to note the machine tools of digital program control, milling machine model MV 16-11NC -nd multitool model TC3CNC and MCSOOCNC. The model MCSOOCNS machine tool (~'ig 1) designed for complex machining.of cast iron and steel housing parts (the dimensions of which do not exceed SOOx500x500 mm) aroused special interest among the specialists in that it 72 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY is made up of standardized assemblies. The standardized assemblies include tlie main drive, the feed dr~ve, the tables, the device for automatic tool and product replacement. ~ ; . ; - M ~ ~.w... f' . i h ~ ~ Figure 1. Multitool model MCSOOCNC machine tool (Hungarian People's Republic) ~ � ~ a) b ~ I ~ c) Figure 2. Schematic of the campositions of the multitool machine tools (Hungarian People's Regublic) based on standardized assemblies: a-- with hc~izoz~tally arranged spindle; b-- with - vertical arr~nged spindle; c-- with turret head The main drive is manufactured in three executions: 1) the DC mot~r and the three-step gear box (basic execution); 2) the asynchronous motor and gear box in which the rpm of the spindle is switched using electromagnetic couplings; 3) the adjustabl.e DC motor connected directly to the spindle of the machine tool (for machinin~ parts made of light alloys and nonferrous metals). The spindle stock is also made in three executions: 1) with . horizontally arranged spindle; 2) with vertically arranged spindle; 3) with _ eight-spindle turret head. The basic technical parameters of these compo- sitional versions are presented below. 73 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY Execution of the spindle stock With horizontal With vertical With - spindle spindle turrc~t head No of. spindlc~ti 1 1 ~i Rpm limits of the spindle: For machining steel-cast iron parts 35.5-1~00 35.5-18Q0 35.5-1800 The same, by order 71-3550 71-3550 71-3550 For machining parts made of light alloys and nonferrous metals 140-7100 140-7100 140-7100 Engine power, kilowatts 11-15 11-15 11-15 - Greatest torque on the spindle, kg-meter 80 80 80 ISO spiuule cone number SO 50 50 The f eed drives with respect to all coordinate axes are identical and consist ; of a high-moment motor and screw-nut transmission. The limits of the _ operating feeds are 1 to 2000 mm/min, the fast displacement speed is 10 m/min. _ The tables are made in the following types: 1) the dividing rotating table ~ with square face plate (500x500 mm) which can have circular feed; 2) the universal rotary-inclined table with square face plate (500x500 mm) which provides for maching parts from five sides; 3) the stationary table - (500x800 mri); 4) stationary table (500x800 mm) witl~ built-in rotary-dividing � table (Eace plate 500 mm in diameter); 5) stationary table (SOOx800 mm) with two built-in rotary-dividing tables (face plate 500 mm in diameter). . The structure of the automatic system of the tool made up of a tool holder and manipulator has two executions: 1) with drum type holder for 30 tools; 2) with chain holder for 36, 40 and 48 tools. Fig 2 shows the schematics of the composition of the multitool machine tools based on the above enumerated nomenclature of standardized assemblies. - Among the machine tools presented by the German Democratic Republic, it is necessary to note *re model FQ400 bracket-milling machine, the two-standard ~ig-boring machine model BKOZ 14UOx2240 and the multitool machine tools models C500/03 and CBK02900 with digital programmed control. ' The Polish People's Republic was represented by the multitool machine tools me3e~ FUM63P;M with vertical spindle and a holder for 24 tools mounted on a stationary standard. On the machine tool the following technical designs were realized: main drive electric motor with 15 kilowatts power; feed drive using high-component motors; the application of a turret (Polish - People's Republic production) with reading precision of 0.01 mm in the feed drive; hydraulic unloading in the moving ~oints of the table; guides made of polymer of the polytetrafluoroethylene type; the model USNMIJMS331Fc digital programmed control system (development and production of the - . Polish People's Republic). i ~ 74 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY ~~m~ng Lhe Sov.i~~t machine tools presented at the exposition, great interest was aroused among the speci_alists by the 6904VPiF2 multitool machine tool (procluction of the Odessa Precision Machine Tool Plant imeni 25th Congress of chc~ CPSU) and the 6906VMF2 (production of the Vitebsk Atachine Tool l;uilcling Plant imeni S, ri. Kirov). The machine tools are designed Lor all around mactiining of housing parts of inedium size from four sides witliout :idjustment. Tl~e coordinate displacement of the cross table and the head- stock, the speeds of their displacement and subsequent clamping, tlie spindle rpm, tool changing and the machining cycles are programmed on tlie macliine tools. There is a possibility of manual introduction of. diameter and ligl~t correction for the tool, The operation of all assemblies of the m~zcliine tools is monitored by a digital display. _ '1'he most numerous exhibit was that of Czechoslovakia. Some of the technical solutions realized in the machine tools of the drilling-milling=boring group are investigated below. Fig 3 shows the model FQH50A multitool machine tool designed for machining (under small-series production conditions) of housing and flat parts with greatest weight of 750 kg, the dimensions of which do not exceed SOOx500x500 mm. The milling of various surfaces, drilling, boring and reaming of holes and tile machining of ttie inside threads are real.ized on the machine tools. '1'I~e composition of tlie machine tool is in accordance with the scheme that is traditional for milling macliines with digital programmed control (the t~racket headstock is displaced vertically along the side guides of the standard rigidly attached to tlie base of the machine tool; the table of tl~e machine tool is a cross table). Tl~e main drive is realized from a 16 ~:ilowatt DC electric motor and a two- titeP gearl~ox c:ontrolled by electromagi:etic toothed couplings. The contin- ~ious regulation of the spindle rpm is insured within the limits of 14 to 2000 rpm. The headstock is balanced using a hydraulic cylinder. 'Ilie feecl drives w~th respect to all three coordin~tes are standardized; rl~e motion from the high-component DC motors is transmitted directly to the ~ ball screws 50 mm in diameter with a pitch of 10 mm. Continuous regulation , of tlie feed is realized within the limits of 10 to 1000 mm/min, the high ~ speed with respect to all three coordinates is 10 m/min. The extreme posi- tions of the moving parts of the machine tool are limited by terminal breakers, Line inductosins are used as the measuring converters. The rotating and dividing table is executed in the form of a separate unit which in assembled form is installed in the cavity of the longitudinal slides. The discreteness of the angle of rotation of the Lable is 5�, 13efore rotation the face plate of the table is lifted by a hydraulic cylin- der, and.then it is rotated by the required angle as a result of longitudinal clisplacement of the table slides (for rotation of the face plate by 5� it is necessary to displace the slides by 5 mm along the X-axis). 75 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 rux urri~l~, u5~; UNLY . , x - , , ~ < ' ~ . a ~ ~ ~ ~ i L d r ~ u ~r ~z'�'' _ i~~` ~t. ~ ( ~ ~,i . s." ts _ . ~ ~ . ~ 4 ~ . ' . . . ~ ~ 7 . . . . . .r i . ~1 ~ . i ~ . . ~ . Figure 3. Model FQH50A multitool Figure 4. Model FCR50NC machine tool machine tool ~Czechoslovakia) ~,ith digital programmed control and turret head (Czechoslovakia) The drum type tool magazine designed for 30 tools is located on the head- stock. Before replacing a tool, its vertical position is changed to horizontal by a manipulator. Then by using a double-clamp arm, the tool - is changed in the machine tool spindle. A machine tool was shown at the exhibition, in the magazine of which the tool was arranged in technological sequence although it is theoretically possible also to use a coded tool. The tool change time is 8-12 seconds. The tool is equipped with units for lubricating the headstock and stabilizing its temperature. Lubricat.ion is fed to the responsible moving joints from a central system. In the ordinary execut.:~n the machine tool has the following precision indexes: positioning precision +0.02 mm (with respect to the X and Y coordinates at a lens~th of S00 mm), division accuracy (of the rotating table) +3". ror the analogous machine tool of increased precision the indicated characteristics are +0.015 mm and +1.5" respectively. The machine tool was shown at the exposition with the programmed control - system model Philips 6663. The program is fed into memory manually (when machining the first part) or by magnetic tape. Fig 4 shows the model FCR50NC machine tool with turret head and model NS350 digital programmed control system, and Fig 5 shows a vertical milling machine model FC50V. It is interesting to note that both machine tools are made up of the same base assemblies (vertical standard, base, cross table wir.h dimensions of 500x2000 mm). The model FC50V machine tool is equipped with a device for climb milling. The control of the automatic operating cycle by the given program is 76 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE OIdI~Y realized using adjustable stops. On the basis of the model FCSOV machine tool it is possible manufacture a machine tool with program c~:,ntrol and also a machine tool with elecCrocontact forming unit. During the work of the exposition, a scientific-technical symposium was held on the problems of inetal cutting machine tools with digital program control which was participated in by representatives of the member countries of the CEMA. In one of the reports specialists from Czechoslovakia dis- cussed the prospects for the further development of mach.ine tools with di~ital programmed control in Czechoslovakia in detail. The creation of such machine tools (with any automation level required for the customer) is based on the principle of unit construction of machine tools from standardized assemblies. �~ry;., ~ , 'i_, i yy, . ~ 'a� ! : ~ ~4 z,-' r.t. ' ~ pM~ ~ ~ Figure 5. Model FC50V vertical milling machine (Czechoslovakia) 0 + - ~700 3675 Figure 6. MCFR A80 unitized machine tool (Czechoslovakia) The following basic restrictions are adopted; 1) table width 630, 800, 1000 and 1250 mm; 2) versions of compositions of the machine tools with ta~le width of 630 and 800 mm: longitudinally moving table and transversely moving standard; t~eadstock with horizontal spindle (arrangement on the standard, bracket or sy~netric); headstock with vertically arranged spindle or turret (placement on the standard symmetric); 3) versions of the 77 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 rucc urri~ttw Ua~: UNLY compositions oE the macliine tools with table width of lOQO and 1250 mm: lon};i tucliiially movinfi Cable and transversely moving standard; sta~ionary Cablc~ znd standard ~aith cross displace*~ent; neadstock with horizontal spindle (placement on the standard bracket); 4) drum type tool magazines (witii limited number of cells) and chain type (with the number of cells necded by the customer. '1'f~e model MCI~ItA80 unitized macliine tool (Fig 6) was also shown at tl~e - exposition. It is made up of standardized assemblies. Tl~e vertically arranged headstock is equipped with a four-position turret; the automatic tool changing is done in two positions of the turret; number of tools in the magazine 15. ~ Technical Specifications I)imensions (widthXlen~th) of the table, mm 800x1750 Vertical stroke of the headsrock, mm 750 Limits of the operating feeds, mm/min 1-3000 Engine power, kilowatts ~ 15-24 Conclusions 1. The first specialized exposition of inetal cutting machines and forging and pressing equipment from socialist countries again confirmed the trend in the development of machine tool building aimed at creating highly auto- mated machine tools which insure complex machining of parts with one setting of it. 2. Wf~en building the machine tools of the drilling-milling-boring group witli digital prograrrmied control, the principle of unitized construction of tl~e machine tools from standardized assemblies is widespread. COPYIt[GHT� Izdatel'sr��o Mashinostroyeniye, STANKI I INSYRUMENT, 1979 10845 CSO: 1821 78 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 I FOR OFFICIAL USE ONLY METALWOItKING EQUIPMENT F.AST GERMAN ARTICLES ON NEW MACHINE TOOLS Digital Program Machine Tools Moscow STANKI I INSTRUMENT in Russian No 11, Nov 79 pp 2-4 ~Article by P. Sachowitz and W. Pabst: "Soviet Digital Program Control Machine Tools at the Experimental Center of the Ashersleben Machine Tool Plant"] [Text] In the plan for the further development of technical cooperation and the sharing of information between the scien- _ tific-technical iournals of the GDR and the iJSSR an agreement has been reached between the editors of the journals FERTI- GUNGSTECHNIK UND BETRIEB (Berlin, GDR) and STANKI I INSTRUMENT about an exchange of articles. T}~is section contains articles that were written by special- - ists from the GDR and sent to the editors of the Soviet jour- nal bv the editors of FERTIGUNGSTECHNIK UND BETRIEB. We have in turn sent our colleagues from the GDR arricle bv~ Soviet specialists. which are being published in FERTIGUNGS- TECHNIK UND BETRIEB No 11, 1979. In tiie GDR's metal workinQ industry DP ~digitally programmed] metal cut- ting machine tools from the USSR are being used more extensively; these machine tools promote a significant intensification of production. _ The first Soviet DP machine tools were delivered in 1973 to the "7 Oktober" Machine Tool Building Combine in Berlin.* At the Wema enterprise (Asher- sleben) r~f the "Frifz Heckert" (Karl Marks Stadt) Machine Tool Buildin~ Combine in 1975 an experimental center was organized, where the Soviet DP machine tools are in operation. The most itnportant tasks of the ex- ~ verimental center are*: testing the first importe~ Soviet DP machine tools under conditions of the GDR's machine tool building industry; the Scliuckar D Aufbau und Ergebnisse des Experimentalzentrums mit sowieti- schen NC-Maschinen in der DDR. F~RTIGUNGSTFCHNIK UND BETRIFB, 25 (1975). S. ~ 79 FOR OFFICIA,L USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 ~ FOR OFI~ LC1AL. U5E ONLY clr~iwing up of unified operational norms for these machine tools; and the solvin~; of problems for the improvement ot production. The resulte of the tests are being passed through the technica.l center of the Soviet Export-Import Aasociation V/0 "Stankoimport" to the plant manu- facturers of the ma.chine tools in the USSR for use in further improving the product. The work of the experimental ~enter is making a significarit contribution to socialist economic integr~,tiou. - Upon conclusion of the first stage of the constr~action of the experimental center in Navember 1977 in the city of Asheraleberi there wae a conferenoe of the u~ers of the Soviet llP ma.chine toole. Partiaipating in the con- ference were representatives of the GDR's Minietry of Machine Tool ~uild- ing Indu~ try~ of the Saviet manufacturers of the DP machine tools, V/0 - Stanlcoimporta the National Foreign Trade Enterprise WMW Export Im ort (Berlin)~ the nationa.l enterprise Importservice (Kaxl-~'[ariss stadt~~ and the users of the Soviet DP machine tools. Discussed at the conference - were the experience of work of the ext~erimental center and the prospects for ~he further use of the Soviet DP ma.chine tools. Below are examined trie more i.mportant ma.tters that were diacussed at this conference. - From 1975 through 1977 at the experimeatal center the follawing DP mar- chine tools were set up: a horizontal milling and dril'ling machine tool~ mode1.2611F2; a vertical-drill ma,chine tool~ model 2R135F2 witih a revolv- ing capstari; a semiautoma.tic centering lathe, model 1B732F3; a horizontal milling arid drilling machine tool, model 2Ao22F2. The first organization^~ measure was to cr.�eate a group for the technologi- _ ca1 preparation and maintcnance of the DF' machine tools. The fl.inctions of this group inCludes ~uch ma.tters as the a~sembly and pu.tting into opera- tion of the machine tools~ traini.ng personnE~l~ the pro~ra~mn.ing~ mainte- ziance arid general coordination as well as ~h~ r~eliminary tuning ar~d use of the tool and the securing of the billets. An office for coding was for~ned based on exi.sting GDR offices fox the man- r ufacture Af the punched tape. The centralized turiing of the tool using - Soviet BV 2015 instruments wa.s organized to ad3ust the tool to the milli.ng and drilling machine tool:s and t.ie BV 2010 for a.d.3usting the tool to the lathes. ~ IInger ~i. E~cperimentalzentrum fur sovjetiche NC-P~Ta.schinen. -"Die Ylirtschaft", 32 (1977)r 12. _ 80 ::~OR OFFICIAL USE ONLY , APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY The presence of a sharp cone (7 : 24~ in the spindle of the horizontal milling and drilling machi.ne tools makes it possible to use an instrument of GDR production. During borin~ they uae drill bits with hard a11oy bladea for working at increased cutting modes, The cutting bar assembly is fitted out with modern control drill bite. The use of crowned drills for procesaing the holes for t~.e whole reduces the number of work trans- fers~ A new boring tool designed by the Schnalkalden machine tool build- ing combine has been tested and manufactured according to TGL 31699 norms. Particularly good results were obta.ined during ~he work by the tool with two cutting edg~es. On the vertical -drill machine tool with a revolving capstan there were no occurrences of difficulties with the use of the tool, because eix spindles have a Morae cone. On the semiautomatic lathe an ef- ficient tool of GDR produetion is used. The billet clamp is accomplished ~ using standard means that are used in production. The assembly and putting into operation of DP machine tools were carried out by Soviet specialists. The acceptance of the machine tools was con- ducted according to conditions of acceptance of the plant-manufacturer con- sidering the special requirements of the user. Training on maintenance of the DP machine tools, working on them and on programming took place dur- ing their b~ing put into operation with the help of Soviet specialists~ who repreaented the plant-manufacturers. In additi on a training course was organized at the manufacturing plants. The programming was accomplished primarily by hand and was only partly _ ~utoma.ted. For the semiautomatic centering lathe it was possible to use a postprocessor that was developed by the Research Center of the machine tool building industry (Kaxl-Maxks ~tadt). This same resQaxch center de- sip,ned a postprocessor for the model 2A622F2 ma.chine tool. The maintenance of the ma.chi.ne tools during the warranty period wae per- formed by the plant-manufacturers. Following the warranty period malad- justments were eliminated jointly b3~ the user~ representativea of plant ~ - manufacturers and the '."echnical Ceni;er of V~0 Stankoimport. The DI~ machine tools in tne L`xperimental Center work with a full load ~ for three shifts, At present tach machine tool is serviced by one worker; in the future it is plar~ned to have multi-machine tool servicing. The horizontal milling and drilling ma.chine tool, model 2611F2~ (Fig. 1) is m~~.nufactured by the Ivanavskiy Heavy Machine Tool Building Pl~.nt imeni 50-letiya SSSR and is intended for four-sided~ chiefly finishing~ proces- I sing of complex housing parts wei~hing up to 2,000 kilograms. The coaxial holes can bn processed from one installation. The machine tool has a = lengthwise ssliding stand~ a transversely sliding turning table and a ver- tically sliding spi.ndle drill chuck. The frequency of revolution of the spindle is ~ritched by program. - On the model 2611F2 machine too:L it is gossible to perform drilling, bor- - ing, countersinking, hole expan~iing, threading, face processing~ circular ^ groove cutting and milling on a right angle cycle. The cutting of cixcular 81 FOR OFFICIAL USE ONLY ~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000200060016-6 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000200064416-6 FOR OFFICIAL USE ONLY grooves and reverse countersinking axe accomplished manually; all rema.in- ing operations are done automa.tically. Constant cycles are used when pro- cessing holes. .nr-- ~ ~,:,~..w.~..