SOV/136-59-7-12/20 I .7pe Ts IF -1.5 Stress Conditions in the Extrusion of Tubes of T A- 9 shows temperatures as funotions cf extrusion speed for various degrees of defoination. A typical oscillogram is shown in Fig 2, while Fig 3 shov;,i that for this, as for many other alloys (Refs A-13), the friction force remaIns at its maxi-murl value over a wide range of deformations, The variations in the friction factor and other parameters with temperatura (250, 275, and 3000C) are 6iven in Table 1. Fig 4 s-viows friction force for each of these temperatures as functions cf the ext:,iision speed. The ratio of fri.,tion force tc the plasti--deformation stress (true resistanee to deformation) for the average temperature was found "o vary ~,rithin the range 0.52 - 0.66. The experiments also enabled the DaramclUers for -'alculating tube extrusion forces by a simplified equation to be determined (Fig 6). The almost linear plots of minijaum extrusion force (tons) vs natural logarithm of extensi)n for temperatures of 250, 275 and 300'C are 8hown In Fig 5. Results calculated by the simplified equation and an analytical equation Card 2/3 published by Perlin (Ref 9). using the authors' published  SOV/136-.59-?.-12/20 Stress Conditions in the Extrusion of Tubes of Type TsAM 9-1.5 (Ref 6) graphs, are compared in Tab'.e 3. The analytical equation gives high values, especia:.ly at high degrees of deformation when a greater thermal affect arises on the production than on the laboratory s0ale. The authors consider the optimum extrusion-speed for tubes to be lip to 8, 3 and 2 mm/sec for 250, 275 and 30COC, respectivell. There are 6 figures, 3 tables and 15 references, 12 of which are Soviet and 3 German. Card 3/3  18-5ooo 78321 SOV/89-8-3-6,1/32 AUTHORS: Perlin, I. L., Nikitin, 1. D., Federchenko, V. A., D.-, Re3hetnikov, N. G. TITLE: Some Force and Deformation CharacteristIC3 of Working Uranium by Forces of Pressure PERIODICAL: Atomnaya energiya, 1960, Vol 8, Nr 3, pp 219-227 ABSTRACT: The choice of optimum thermomechanical conditions fo- worIcing of uranium is complicated due to possibilitie-- of allotropic transitions resultirg in modifications having different plasticity and strength. Due to Its high resistance to deformation and small heat capacity, uranium is often heated considerably during extrusicn and rolling and changes from a int8 a_ phase. Deform- ing samples from 90 to 60 mm at 420 'C by means of one stroke of a friction press, the t-amperature of the metal rises from 90 to 1000 C. Strong oxidation al,3o influences the temperature change in the metal duri!-,g Card 1/17 working. To enable the determination of conditions  Some Force and DeformatJon Characteristics 78321 of Working Uranium by Forces of Pressure SOV/89-8-3-6,/'32 for working of uranium by forces of pressure, the authors investigated the rolling, ressing, drawing, P and die forging of uranium. Figure 1 shows the influence of the temperature on the maximum permiss-4:--le reduction per pass of 15-mm-wide cast uranium samples. Uranium is exceptionally sensitive to nonuniform dis- tributions of deformations during rolling. For example, fine uranium strips (0.01~,-0.20 mm) may be obtained without fracture;reduction per pass 80-85%. The augmented plasticity is expla--ned as due to negligible nonuniformities in the distribution of deformation in the rolled strip. However, whon rol'-- ing cold thin plates with variable rolling direction, the resulting nonuniformities in deformations cause fracture of the metal. Figure 2 shows the results of investigations of the variaticn with temperat,.-ire of the mean specific pressure pcf, of the metal on the rollers. The temperature increase in the metal Card 2/17 during rolling at t = 6300 C causes a transition into  Some Force and Deformation Cha -actcrl.~;tlct3 of Working Uranium by Force.,.; o Prc-,:i:~ure E: too 0 4-) tv 1,7 E 19 PLO 'TV JM ikl i4kl O-W 7,V 6X ,,j It) Ralltmg tempeeature, 'C 78321 Fig. 1. Influence of temperature on rollabIlity cf uraniumi (x) no fracture of samples was observed. Card 3/17  Some-Force and Deformation Characteristics sj ;z J., Acc Card 4/17 78321 SOV/89-8-3-6/32 Fig. 2. Average specific pressure of metal on rolle:,s versus the temperaturei -first series of tests; - - -second series of tents.  Some Force and Defoi.-Iatiun, 78 3 ~) 1 of Working Urani= by S 0": "/,-- q3 3 the pha-se .-.TIch up ag ,taggered oscillograms. The aguthors also invcstilga'ted the mean specifIc pressure as function of the reduction at various temperatures and also as function of the initial state of uranium samples. They compared the results with `.he analytic equation of A. I. Tselikov (Proicatnye stany (Rolling Mills) M., Metallurgizdat, 1947) and found a satisfactory agi-ee- ment: -)(h p,P where (11 h)/H i.,,, reductio'n; hif, height of' ~,rip in the neutral cross section; ( = ~L ~24/ j~s h- coefficient of friction; D = diam of rc)llers); k 1.15 nY 0 3 (nY = coefficiEnt of strengthenin,; T 3 = yield limit in case of large plautir; deforma- Card 5/17 tions). The value of n Y is function of the reductic.r.  Some Force and Deformation Characteristics 78321 of Working Uranium by Forces of Pressure SOV/89-8-3-6-332 and temperature, and varies between 1 and 1.6. Figure 4 shows the absolute widening 6 b - B 1 - B of a sc~_iare sample 21 x 21 x 180 m-a with rollers 220 mm in diar7 as function of rolling temperature, The maximum of tl.e curves Is connected to the maxim ~m of the friction coefficient which in the 900-950 C temperature r-2j;ion is equal to 0.4-0.45. The authors note that uranilLm can be extruded in the temperature interval betweei, 250 and 1,0000 C, and they discuss In detail the extr,_~.,iicn characteristics of T - and CL -uranium. They empha- size that during extrLsion the uranium should not ,orre in contact either with air or steel tools. Toolz made from heat-resistant alloys, cartides, and ceramics i,;ith lubricants are i~sed for extrusicn of C-L -uranium. f - 'Ically While extrusion velocities of ~ uranium are prac, unrestricted, CL -ur;iii-lum is extruded using -,,elocities between 1 and 400 mtn/sec. The E.uthors investigated further the extrusion stresses as function of extruslon ratio, temperature (see Fig. 6), and production mode oil Card 6/17 the sample. The extrusion stre:js depends linearly on  come Fore,- ~nd D of Worl-:1.117~ UI-all-I l1:,. P'!- t. fill poll 4 Card 7/17 te.~P(-131lt  Ila 0 11 C ha r a Some Force and D--:~for, of Worj~jng Uranium IDY F 3 r c e.,:c -4 Tv w., ce -rs 1 4, Fir. Card 8/17  Some Force and (,~-. _,1. L of Working Uranl~:m i~:/ i il~ the lritei-,rul lnde-x of the degr,.e of and Fljurc. a nomograrn whose cro3l- hatched regloii ~3hov.,,~ the lnfl~wnce of the scale-factor on the. pressing sl res, when the ratio of the cort&,_~ner d la m e t e r,; e (I i, a 1 ~_~ ~ .Thtz! te~A,,,, also showed thal~ CDT) IWJ~ 1 (2~~ tht: f'ovi,, .,,, ui' i,ont:ic t 1'ri(,, t 1 on A:.~ iliirs p;i,~s throuvh I.rom thu noiriGirrain, th,_ nate orlijn, t!ul th,~ extrusion 0, pr c.--in bt- det(,rmin,:-d from -,he eq ~.itLoii: P', J." Of.0 -I' ti - .VP, 1, In analo~~y with Young's modulus the coefficient M the mod~ilus of the pr Figure 9shc,)vis Lhe varlation of thIs p e ra tu re .Extrudahl"Ity ipr or the Card 9/17 defired as: authors call the ?xLrusion str-ss. rriodiil~is with ~em- uranilim  zioine Forcc and De'lorniutlon Characterlz:tics of Working Urani= by Forces of Presoure IL t f-i k") I, -178321 sov,,/89-~- Fig. 8. No,,n( gram fcr determination of extr-islor. Card 10/17 stresses.  Some'Force and D:~formatLon of Working Uranium b FDrcr~:.; oV Pre.,,,surc. 's~ 3 "-'.1 `12 Fig. 9. Modulus of extrusion stress of uranitn ',Er.c;US temperature. Card 11/17  Some Force and Deformation Characteristic-, -of Working Uranium by Forces of Pressure 0 Or 78 32 1 S OV118 9 -8 - 3 is shown In Fig. 10, where the tipper curve is the -aria- tion of t~e maximum extrudabilitT tinder a pressure of 150 kg,/mm , and the lower Curve is obta--ned using pr = 15 kg/mm 2. '/ -Uranium has extrudability above The author3 discuss further the 3tructure of the proci- ucts and Table 2 exhibits the mechanical propert~E,- of the extruded uranium. The au-~hors discuss varic-uE lubricants used during drawing, and present in Table 3 and on Fig. 11 some results concerning drawing of uranium. WItI, heating one can obtain uranium wireZ 2 mm in diam and less. Modification of heating conditions allows the production of 0.1-mm uranium wires. Uranium can be die-forged in the CL and Y temperature regions with ram velociti up to 6,000-7,000 mm/sec- Any tr-3n- Card 12/17 sition into the )y region due to overheating, will cause  Some Porce and DA'onnaT-!o,, -1, 8 3 of Working Uranium b, Fc)r(,,2:~ o;*' SOV/89-8--) k tu Card 13/17 Fig. 10. Extrudabllity of uranlum versus temperat~ire.  '78321, SOV/89-8-3-6,/'32 Table 2. Mechanical properties cf extruded (a) Initial state of uranium; (b) tensile strengtn; (C) elongation; (d) reduction of area; (e) extruded at; (f) extruded in CL -phase with subsequent hardenirg fhnp-j)hase. a b 13b, % d e0 350- C . . . 143,0 9.2 S. D 4!.~ 7W-7,50' C - 6t.3 9.2 4, t V) goo, . . . 80, U 7,6 4") 41 75 7 11 6 . . L , Notes (1) Each figure represents the arithmetic r value from three measurements. (2) Small Gagarin- Ije Card 14/17 samples were tu,,ed during tests.  Ov A., Table Drcv,ifi,, dra-ging radio. (a) Initial. sllai.( t,ar; diam,; final dlam;(d) dra.-.1:x, ~;er pa-5; (e) of dra,.,~ing; (f) dr" (g) arineal~--~; (h) re~- liminarily dt-Corm,--d. a b 0, 111.7 1 2G."() 47 Card 15/17  Some.Force and Deformation Charact-eristIcs of Working Uranium by Fcrces :;f' Pre.--s--.,re do. go oPdcP6k-#~aOIOt7j I L~ `u 32 1 SOV, kL U 3 Fig. 11. Relationship he-t~%reen draalng parameters an(I Card 16/17 drawing ratio per pa:iL;.  Some Force and Deformation Characteristir3 -18321 of Working Uranium by Forces of Pressure so V/89--" - 3- "/-, 2 SUBMITTED: crack formation. The authDrs also d:.sciss brief!" '.~,e conditions for flat die fo-rging of' 0- andj urani-z-,. There are 11 figures; 4 tables; and I') -Sc- ,,- referenceL. February 23, 19'~() Card 17/17  18.8200 '(5397 sov/149-2-5-23/32 AUTHORS: Koroll, V. K., _~erlln, I. TITLE: Deformation Resistance of,TsA?1 9-1.5 P.lloy Within Tempera- ture Range of Hot Working by Pressure PERIODICAL: Izvestiya vysshilth uchebnyl(h :,avedeni~. Tsvetnaya metal- lurgiya, 1959, Vol 2, Nr 5, Pp 159-166 (USSR) ABSTRACT: Zinc alloys are now used by railroads and other industries as a good substitute for antifriction bronzes. Such an alloy is TsAM 9-1.5, consisting of 8 to 10% Al, 1 to 2% Cu, and 0.03 to 0.06% Mg, the balance being zinc. This alloy corresponds to state standard GOST 7117-56. Previous studies were conducted by German authors (Beier, W., Wolf, V., Nr 8, 1939; W(?iss, E., Metallkunde, Nr 4, Z. Metallkunde , 1940), and by Vinogradov, S. 11., Dnestrovskiy, N. Z., "Special Bronzes and Brasses;' Metallurgizdat, 1945; they cover, however, only slow rates of deformation (10 to 120 mm/min), while hot working by prezz-sure involves a high rate of deformation. The authorEi studied the latter Card 1/6 using a tension-testing machine with e. pendulum dynamometer  Deformation Resistance of To-AM 9-1.5 75397 41loy Within Temperature Range of SOV/149-2-5-2-~//-32 Hot Working by Pressure with a ram spced of 0,2, 1.6, 2.5, and 168 /3 e a drawing bench a- attachment for tensile Ft:,~d a recording, device for preparing a pri:iiary dlaCram ~)~' means of an oscillograph. Specimens w:~re rods of B-mm, OD and a length of 40 to 80 = (GOST 1.~97-1~,`). The installation is shown in Figs. I and 2. Th- 6eforr-natiu,~ of the specimen can be recorded simultaneo~,;sly cr, the photographic plate and by the osci'Llog.-aph. The resu!'L3 of tests are given in Table 2. From T~ible 2 it appears that the TsAM 9-1.5 alloy acquires a considerable streng%hen- ing only at the beginning (up to 10% reduction), then sof ens rapidly at 5eforniation 6peeds of 2-5-10-3; 2 .0'7- .10- , and 6.25 -10- l/bec. However, at a deformat-11cri spoz-d of 2.1 .,,/a~c a certain increase in the st 6ess of plastic tension is observed, even at 300 to 350 - One can conclude that at slow speeds the rate of deformation does not influence substantially the resistance of the al.-.oy. The maximum value of the speed factor (6.4, ishich --.s the ratio of Card 2/6 the stress of plastic tension at any speed and any  75397 sov/149-2-5-2.j/')2 Now 10- 01 0 0 0 0 5 0 -.0 to Ito FIg. 1. Diagram of installation fDr simultaneous de,;er- mination of applied force and cross section of the specimen during stretchin (1) Reverser; (2) dynaino- meter; ~3) light source; N) screen; (5) resistance heat; ( )_plvanometer and thermocouple;,PJ93ower supply; tdj photographic camera "Zenit-S ; time recorder; (10) oscillograph rectifier; (11) oscillo.- Sard 3/6 grapl~ POB-14.  7539Y ISOV/1 4 9 - 2 -2L! 5 6 7 8 rp 9 Fii. 2. Electric circtilt for recording of tensile --tre3:3. 1 Transformer 220 '1211 v; (2) capacitors, 211 v, ~O m-i'; 3 choke; (4) rectifier DGTo-211; (5) milliammeter; ~6 coil resistors (R, woricing, K, compensation); ('~) regulating rhoostat 2 ~Q microammeter; (9) loop Card 4/6 oscillograph.  Deformation ResiQtance of TsAM 9-1.5 Alloy Within Temperature Range of Hot Working by Pressure ASSOCIATION: reduction ratio, to the stress ofc3l.astic tension at a deformation speed = 2.5 - 10- se corresponds to a temperature of 3500. At 200 0 it is down to 1.3. There are 2 tables; 7 figures; and 10 references, G Soviet, 2 German, 2 U.S. The U.S. references are: Gonson, Moor, Proc. ASTM, B. 40. 1940; Mend,,choun, J. Appl. Mech., December, 19114. Krasnoyarsk Institute of Nonferrous Metals. Chair of Metal Working by Pressure (Krasnoyars'kiy institut t*vEt- nykh metallov. Kafedra obrabotki metallov davlenien) 75397 sov/i49-2-5-2:V--,2 Card 5/6 card V6  S1 182/6O/O0C)/0T)/004/'(D 12 A 1151 /A029 AUTHORS: Perlin, I.L.; Fedorchenko, V.A. T=% On the Press Forging TeclMology for Uranium Id Uranium Alloys PERIODICAL~ Kuznechno-shtampovochnoye proizvodstvo, 19 0,&,No. 9, pp. 12 - 18 TEXT. The article presents a review of infDrmation on the technology Cf forging uranium. The information sources are Ame~ricai (A.I.M.E.). or in English language, including manuals; proceedings of two *Lnte,~national conferences in Geneva (1955 and 1958). The two Soviet sources referred to (Refs. 5 and J5) are only mentioned. The first deals with pecularitiev of pressing L>~Ili~um` zircc- nium,Auranium and thorium,4and the latter with work safety. All illustra'tions are from foreign sources. There are 11 figures and 15 references; 9 English and 6 Soviet. Card 1/1  PARTIN, I-L-; YNDURCHMO, V.A. Squipment and protective devices for tho production of heat-releamiag elements for atomic reactors. TSvet- me".- 33 no-818&93 Ag 160. (WIRA 13:8) Oluclear reactors--KateTials) (Radiation protectLon)  FERLIIqP I.L.j SHAPIRO, V.Ya. Comparative analysis of power conditions in pipe drawing with floating and fixed cylindrical. mandrels. Sbor. nauch. trud. GINTSVET~ET no.33:299-304 160. (WRA 15:3) (Drawing (Metalwork))  KOROLIV V.K,; PERLIN, IJL - Prinimal uchastlye TSYUY GO-FAN [ChIU Kuo-f g), s udre~ni_ -_ - - -,, an Production of-bimetal tubes of TSAM9-1.5 - duralumin alloys by means of press forging. Sbor.. nauch. trud. 3INTSVETw,r no.33: 310-317 '60. (MA 15:3) (Laminated metal) (Forging)  IVANDV, A.I.; PERLIN,_I.L. Establishing the basic parameters of drawing steel-alunLinum bimetal wire. Sbor. nauch. trud. GINTSVETMET no-33:324-330 160. NIRA 15:3) (Wire drawing) (Lamdnated metal)  S/ 136/61/000/001/005/0 10 1:193/E283 AUTHORS: Perlin 1. L. and Glebc.v, Yu. P. TITLE: Determination of the Shape of the PLane of Contact in Extrusion with a Ple.stic Pressare Disc PERIODICAL: Tsvetnyye metally, 1961, Na. 1, pp. 72-75 TEXT: The problem of keeping to minimum the weight of the discard from extrusion billet becomeE particularly important in extruding costly metals or alloys, and the present article des- cribes a method of achieving this end. The method proposed is based on the application of a conical die, used in conjunction with a spacing disc of a plastic metal (with deformation characteristics similar to those of the extruded material), placed between the extrusion ram and the extrusion billet. The principle of the method- is best explained by referring to Fig. I which shows (1) the extrusion billet; (2) plastic metal disc, and (3) extrusion ram, before (A) and after (B) extrusion. The salient feature ot the method consists in that the mating surfaces of the extrusion billet and the spacing disc are not flat, but convex and concave, respectively. If the correct shape of the curved interface (line Card 1/3  S/136/61/000/001/005/010 E193VE283 Determination of the Shape of the Plane of Contact in Extrusion with a Plastic Pressure Disc D-C-E, Fig. 1,A) is chosen, it becomes flat (line D,-C'-E,, Fig. 1,B) after emerging from the die, so that. the tail end of the extruded rod is free from the "piping" dofect and does not have to be discarded. A method of determining the correct shape of the curved interface from the co-ordinato net pattern, superimposed on the meridian face of an experimental billet, is described. Apply- ing this method to alloy,40b (D16), extruded at 420 0C from a billet 40 mm in diameter, to an 18.4 nim diameter rod, the present authors found that the correct interface constitutes, in this case, a quadratic paraboloid. It is concluded that if this method is employed in extruding metals at relatively low temperatures (below 5000C), the extrusion process can be carried out without producing a discard from the extrusion billet. TI-iere are 4 figure5 and 2 Soviet references. Card 2/3  S/136/61/000/001/005/010 El),3/E283 Determination of the Shape of the Plane of Contact in E-xtrusion with a Plastic Pressure Disc Fig. I Card 3/3 4v A PKC, 1. CXCMa K npoUCCCy npeccommn C I?-IaCM4CCXOfI f-POKAUKOR A - AO HAqal- nrue:ca; F - nmie Oxommam". "p"'Iecce;I-, npeccvem" me. fs.na; 2 -.rII#rt"qHaR npoxAajKa: 3 npeCC-wjkA5*  S1149A A006/AOO1 AUMORSt Perlin, I.L., Glebov, Yu.P. TITLE: On the Shape of Elastic Zone in a Die During Pressing Through a Single-Channel Flat Die PERIODICALs Izvestiya vyashikh uchebnykh tavedeniy, Tsvetnaya metallurgiya, 1961, No. 2, pp. 1,31 - 133 TEM The shape of the deformation iseat in pressing.through flat dies is determined by the elastic zone. The effect of various factors on the magnitude of elastic zones has been dealt with in a number of publications (Ref. 1 - 4). However, they do not explain the causes of a constantly equal shape of the sur- face separating the elastic zone from the deforming metal volume. The shape of this boundary represents a trajectory of the motion of peripheral layers of the pressed metal. Investigations of this boundury provide data on: regularities in metal flow during pressing; characteristics of the surface of slip in the de- formation seat, and on the effect of the aforementioned boundary on force condi- tions. The authors attempt to explain the causes determining the surface shape of the elastic'zone. For this purpose it is suggested to use the principle of the least work and the least time for the trajectory of motion of metal particles 1/000/0)2/014/017 Card 1/3  s/149/6 1/000/00;2/b 14/0 1 y A006/ADOI On the Shape of Elastic Zone in a Die During Pressing Through a Single-C haxL-iel Flat Die (Fig. 1). The trajectories of particles from poin-t A to B can be determined ana- logous to the solving of Bernoulli's problem of the braohistochrone which shows (Ref. 6) that the given curve Is a cycloid (Fig. 3" which is concave in the motion direction of the point and resembles by its shape the boundary of the elastic zone, Another method of demonstrating the concave shape of the curve formed by the tra- jeatory of a point moving at high speed and mViimum time is shown in Figure 4. The straight line m - m, parallel to axis x, c;7osses the poss1ble trajectories in points a, d, f. Time is gained when the shortor section is passed at a lower speed and the longer section at a higher speed,, Sections of the course, passed by a point at the same level and by different trajectories, are in the relation Ac < < Ad < Af, i.e. at the beginning of motion at lower speed, the concave trajec- tory provides for a shorter course, and for a longer course at the end of motion at maximum speed, since 'the section of the trajecto-.7. below m - m are in relation Be ',', Bd > Bf. Thus the shape of the elastic tone surface during pressing through flat dies, corresponds directly to the principle of the least work. This Is Im- portant when developing methods of determining forco conditions for pressure work- ing of metals by the least work principle, usIng variational calculus. Data ob- Card 2/3  s/14q/6i~=/OD2/o14/oi7 AOO6/AO01 On the Shape of Elastic Zone in a Die During Prestsing Through a Single-Chermel Flat Die H ta3ned may be used for designing pressing tools. Figure 4: Figure.13 Schematic drawing of an elastic Schematic drawing explaining the shape of the zone during pressing with a flat boundary between the elastic and plastic L die. zones during pressing through a flat die. 9 A There are 4 figures and 6 referenceas 5 sovielt and I non-Soviet. ASSOCIATIONS: Krasnoyarskiy institut, tsvetnyXh metallov (Krasnoyarsk Institute of Non-Ferrous Metals). Kafedra cbrabotki inetnllov davleniyem (De- partment of Pressure Working of Metals) Card 31-3 SUBMITTED: October 5. 1960  8/149/61/000/005/005/008 AO06/A101 AUMOR: Perlin, I. L. TITLF: On force conditions and metal flow rates during the last stage of pressing PERIODICAL: Izvestiya vysshikh uchebnykh zeLvedenly, Tsvetnaya metallurgiya, no. 5, 1961, 170-173 TEXT: An investigation was made for the purpose of analyzing and making more precise the concepts of the effect of friction forces during the last stage of pressing and of the nature of changes in the strained-stressed state of the deformation seat atihis stage. The investigation was carried out with direct extrusion of a round rod through a plane die. Factors were studied affecting basically the slide speed of the pressed metal over the contact surfaces of the pressing tool during the last stage of pressing when the press plate begins to enter the reduction section of the deformation seat. Formulae are given to ca:_ culate the volume feeding the pressed work piece, the decrease per second of the feeding volume and the rate of sliding and f'.ow through the cycl~ndrical surface. It was found that the mean sliding ra-te of the pressed metal over the Card 1/3  s/14q/6l/000/0()5/D05/OC8 On force conditions and metal flow rates ... A006/AlO1 contact surfaces of the press plate and the die, End the flow rate of the metal In the plane which Is perpendicular to the pressing axis, are inversely propor- tional to the current height of the ingot in the containers; these rates Increas~. sharply with a rapid decrease of the height. Thin increase In the flow rate of the pressed metal and Its sliding rate along the press plate end surfaces and the die, when the press plate enters the reduction section of the deformation seat, and the less marked increase of these rates prior to this, are explained as follows: before the press plate enters the deformation seat, the volume of the latter does practically not decrease, and the same amount of metal is supplied as is delivered to the pressed work piece. After the press plate enters the deformation seat, its volume decreases inevitably. This entails an increase In the flow rate of the metal and its sliding over thu contact surfaces of the press plate and the die, at an unchanged volume supplied to the pressed work piece per second. Thus the basic cause of the sharp increase of the pressing force during 'the last stage of the process, is the increased sliding rate of ~h~ pressed metal along the contact surfacen of the press plate and the die. There are 2 figures and 1 Soviet-bloc reference. Card 2/3  9 S/149/61/000/005/005/008 On force conditions and metal flow rates ... Aoo6/AIOI ASSOCIATIONS: Krasnoyarskiy institut. tsvetnykh metallov (Krasoyarsk Institute of Non-Ferrous Metals); Kafedra oorabotki metallov davleniyem (Department of Pressure Working of Metals) SUBM'."I"IrED: March 9, i961 k,/ Card 3/3  S/i8o/61/ooo/oWoOl/020 E193/E383 AUTHORS- Berman, S.I. and Perlin, I.L. TITLr.. Scientific and technical problems of plastic-working of nonferrous metals by the operations of the squeezing group PERIODICAL:. Akademiya nauk SSSR. Izveistiya- Otdeleniye tekhnicheskikh nauk. Metallurgiya i toplivo, no. 6, 1961, 3 - 7 TEXT. Rapid expansion oZ the national economy envisaged in the new programme of the Communist Party of the Soviet Union will necessitate a corresponding increase in the production capacity of the nonferrous metal-workina, industry and in the range of the materials produced. This, in turn, will necessitate the introduction of new techniques, aggkimeration of various fabricating processes and their intensification attained mainly by widerapplication of electrical heating and by increasing the speed of deformation. Some of the problems created by these developments and means of their solution are discussed briefly in the present paper. Card 1/5  s/iBo/6ii/ooo/oo6/001/020 Scientific and technical .... E193/9383 1) It is suggested first that the quantity of rolling stock produced can be increased by incorporating the malting, casting and rolling operations in one continuous line. This system is at present applied on a small scale in the production of aluminium foil and wire, and work is in progress on the development of' a similar process for the production of copper-wire and rod. The main difficulty in applying this process -to melting two-phase alloys is their tendency to segregate dur:Lng casting, as a result of which, lengthy homogenizing treatment, difficult to incorporate in a continuous line, is neceissary. In this connection, it would be desirable to nearch for alloying additions and/or methods of casting whi.ch would ensure homo- gene-ity of the billets. 2) The output of tubes could be incroased by changeover from extruded to seam (straight or helical; welded tubes fabricatod by a continuous process. The results of tentative investigations have shown that this technique could tie successfully employed on an industrial scale for fabricating copper, brass, nickel, alumir-lum, duralumin and other nonferrous--metal tubes. However, Card 2/5  s/i8o/6i/ooo/oo6/001/020 Scientific and technical E-193/E383 before this technique can be usefully cidopted, problema will have to be solved of producing consistently high-quality welds which will possess practically the samo mechanical properties and corrosion-resistance as the material outside the welds A reliable method of continuous testing of the quality of the welded seam would have to be developed. 3) The efficiency of extrusion processes could be increased by reducing the percentage of wasto material; this could be attained by extruding without the formation of extrusion discards , by increasing the extrusion speeds and by the appli- cation of extrusion techniques sim:Llar to those used in cable-sheathing. 3) It would seem desirable to explore the possibilities of using ultrahigh pressures in extruision, wire-drawing, rolling and forging processes. In addition to other benefits, solution of this problem would bring about an increase in the strength of the f 'inished product and a corresponding reduction in the quantity of metal consumed. Card 3/5  S/180/61/oo(VO06/001/020 Scientific and technical E193/E383 The difficulties associated with the shortage of' some metals ca-n be overcome by wider application of clad materials. In this connection, there is a need for development of new methods of thermal and mechanical treatment which lorould ensure the for.- mation of a high-strength bond between the core and the cladcling materials, 5) High priority should be given to research and development work on powder-metallux-gy technIques, partIcularly as applied to dispersion-hardened materials. 6) Friction between the tool and the fabricated metal is an important aspect of all metal-working processes. A search should be instigated for more efficient and cheaper lubricants and more attention!hould be paid to the problem of pressure- feopding the lubricant into the deformation region. 7) More attention should be paid to pracess-control and intipection at every productiion stage. Work should continue on the devel,?Rmgnt, of reliable and accurate testing methods, and the stektiatici_ cess control should be more widely used. Card 4/5  SABol61/ooo/oWool/020 Scientific and technical E193/Z383 8) There is an urgent need to devolop the theory of plastic working of complex shapes or difficult materials (titanium. tantalum, niobium, germanium, uranium, thorium, beryllium, etc.). 9) Since the number of nonferrous semi-fabricated and finished articles of different shapes and sizes, made by plastic-working processes, exceeds 20 000 positions, more attention should be paid to specialization of new plants whose location should be ch-DSen in a less haphazard manner. Card 5/5  26798 1"54 1"0jt- !;/136/61/000/007/0C'2/002 19111/E480 AUTHORS. Berez, A.A., Koroll, V.K., Perlin, I.L. - i__ TITLE: Experiments on the industria production of zinc alloy- armco iron bimetal strip PERIODICAL: Tsvetnyye metally, 1961, No-7, pp.65-69 TEXT: Laboratory investigations by the authors (Ref.l: Koroll B.K., Bushe N.A. VNII zheleznodorozhnogo transporta, Transzhellorizdat, Moscow, 1959 and Ref.2: Koroll B.K., Perlin I.L. Byull, TsIIN TsM, 1961, No.3) showed that, in principle, bimetal strip of alloy 1AAMg-i.5 (TsAM9-1.5) with armco iron could be produced by rolling: subseouent tests on bearings of the material were successful. For wider service tests a batch of the bimetal strip produced under industrial conditions was needed. Its production served also as a check of the proposed (Ref.2) rolling conditions consisting, essentially, in the production of an aluminium-clad billet of TsAM9-1.5 alloy and its combined rolling with armco iron. The aluminium was of AAl (ADI) or AO grade and served as the binder. It was clad onto the alloy by hot rolling (250 to 270'00 on a two-high mill (650 mm dia rolls) Card 1/5  26798 S/136/61/000/007/0()2/002 Experiments on the industrial Elll/E480 at 1.3 m/sec rolling speed with 22 to 30% reduction per pass. Rolling vras continued to a clad-billet thickness of 5.5 to 6 mm, the ingot being 30 and the aluminium 1.3 to 10 inm initially, The aluminium and TsAM9.-1.5 ingot surfaces were wire-brushed, Only aluminium blanks thicker than 8.6 mn showed signs of creeping off, but still to a very small extent, The work confirms results obtained previously (Ref.2) on thinner ingots. To find the aluminium thickness giving the best adhesion, 5,5 to 6 mm thick alloy strips clad with various thicknesses of aluminium were levelled and cut into 235 to 420 mm sheets- these were annealed at 2500C and pack cold-rolled with a pickl;d 7.2 x 235 x 500 mm billet of armco iron, A two-high nill (700 mm roll diameter) was used with paraffin as the lubricant, The iron and aluminium surfaces were wire-brushed. Satisfactory adhesion of tha alloy y 8.6 and with iron occurred only with aluminium cladding originall, 10 mm thick. Unsatisfactory adhesion was due to high residual stresses (Ref.3: AynbInder, A.B. 12.d-vo AN Latviyskoy SSR, Riga, 1957) and irregularities of the contacting surfaces, Since thicknesses of-base and cladding in bimetal strip are required to Card 2/ 5  26798 S/136/61/000/007/002/002 Experiments on the industrial EIII/E480 very close tolerances, the authors studied factors influencing distortion of the individual layers. Pack rolling of different alloy/iron thicknesses and ratios was carried out with pack thicknesses of 12.9 to 16.86 mm (approximating to industrial practice). The two-high mill was used, 52 to 54% reduction being effected per pass. After rolling, the thickness of individual layers was measured by a published method (RefAs Gostev, B.I., Zillberg, Yu.Ya. Aluminium Alloy ACM(ASM) for Heavily Loaded Bearings, GITI mashinostroitellnoy literatury, Moscow, 1959). Neither pack thickness nor thickness rations had any effect on deformation. The final and initial thickness ho and HO of the pack and tile final and initial thicknesses hF and HF Of tile iron were found to be relatod by the expression ho /h F J-CHO/H r)0.81 Recommended rolling conditions for bimetallic strip of 3.6, 4,6 and 6.2 jnm thickness are shown in Table 3. Shear-strength investigation of bimetal specimens taken after each pass showed that generally this rises with increasing degree of deformation; however, heat treatment after reductions of over 50% is essential Card 3/5  Experiments on the industrial ... 26798 S/136/61/ooo/oo7/002/002 Elll/E48o for highost strength. Resistance strain gauges were used to measure rolling pret-sure. Be--aume of the different mechanical rropertios of the layers, the equation for the average working stresses Pav for ea-~h deformed layer assumes the form Ptot Bav VDA. h where Pilot is the total roll force in kg; Bav is average strip width be'ore and after rolling, mmi Ah Is absolute reduction of one of the layers, mm; D is roll diameter, mm, Calculations show that with 4.6 and 6.2 mm thick strip, a decrease in average specific pressure in the first pass is also a factor leading to poor adhesion, R.A.Peskina and A.S,Gul,rayev participated in the work. There are 2 figures, 4 tables and 10 Soviet referen:es. ASSOCIATIONSz Mikhaylovskiy zavod po obrabotke tsvetnykh metallov (Mikhavlov Non-Ferrous Metals Treatment Works) A.A.Berez ' Institut tsvetnykh metallov im. M.1,Kalinina (Non-Ferrous Metals Institute imeni Card 4/5 M.I.Kalinin) Y.K.Korol.1 and I.L.Perlin  FERLM, I,L* Indices 'of specialization wO continuity of industriall processes in the press forging of metals. !zv. vys. ucheb. zav.; tffvet. met- 4 no.3:148-152 161. ORRA 15:1) 1. Krasrioyarskiy institut tsve-tnykh metallov, kafedra obrabotki metallov davleniyem. (Forging) (Indust:rial organization)  BOCHVAR, A.A.; BELYAYRV, A.I.; PAVLOV, I.M.; PIAKSIN, I.P.; GIIIZHIKOV, D.M.; PERLIN, I.L. Iletr Stepanovich Istomin; on his 80th birthday. Izv. vys. iicheb. zav.; tsvet. met. 4 no.4:161-1.63 161. (MIRA 14:8) (Istomin, Fetr Stepanovich, 1881-)  PERLIN, I.L.; GLEBOV, Yu.P. Determining tho ohape (11f cont.a- .1~rfw,-es in pre-s workil- vo, ~ I plaatic s I ~I' ~r:,,. , :,:;!f . .34 . .]: 7-1--7 i; Ja 61. '.~JRA a".J) 1. 1 .  PERLIN., I.L. Fressare determination in tube extrusion with use of pointed stepped-cone mandrels. TSvet.,uet. 34 no.10:77-79 0 161. (MIRA 14! lu.) (Metal-working machinery)  PEFILIN _"L. doktor tekhn. nauk, prof., otv. red.; KIIDRYAVTSEVA, L.V., ved. red.; SUSHKOVA, L.A., tekhn. red. [Metalworking ~y pressure; drawing. Termihology) ObvWtka matallov davleniem; volochenie. TerminologUh. Mbb*&O Izd- vo Akad. nauk WSR. 1962. 15 P. (Its; SbDraiki rdbraindue- mykh terminov, no.61) (MIRA 160) 1. ":ademiya nauk S&SR. Komitet nauchno-tekhnicheskoy term,_ nologii. (Drawing (Metalwork))-Terminology)  HASE I W07, UPLOITATION SOV/ 598.5 Rokotyan, Ye. S., Doctor of Technllctl !;oInnooo, od. Prokatnoye proizvodntvo; sprevochnfli (Rolling Induntrjr; 11tindbook) V. 1. Moacow, . Metallurgizdat, 1962. 743 p. Er-mtn clip inserted. 9250 copies printod. Authors of this volumo: B. S. A!~qronkop CnndidaLe or Tctchninnl Sciences; V. D. Afaraslyov, CandidnW) of Ttolmicol L;c1rrcof); M. Ya. Brovvin, Enginoor; M. P. Wmilov, Enrincer; A, B. Vornik, F.-irivenrl K. A. Golubkov, En,lnoar; S. 1. Gubkin, Acridemician, AcedriV Of SClf,13COS JCJt; A. Yo. Gurovich, F~nginoor; V. 1. Diivydov, Candidate or Technical Scionocal V. G. Dro%d, Erginnor; N. F. Yarinolayov, Enpinoorl Yo. A. Zh1jk(~vAcb-.Uopha, Fnpirmer; N. M. Kirilin, Cnndidate of Technical Solonceal 14. V. Kwynov, En,-,ine(ir; A. It. Koron, Zne~nvor; A. A. Forolev, FrofoODor; H. Ye. Kugnyonko, EnrIneorl A. V. Laskin, Engfimcr; 0. it. loev1t&nek1y, Engincisr; V. M. LuC;(wvkoy, Enginanr; 1. H. M,)yorovich, Cnndldn%o of Technical Sciencos; M. S. Ovchr.rov, SL)j-imor; V. 1. Panternak, Engincor; 1. L. Perlin, Doctor of Tochnical Sc!.onoon; 1. S. Pubedin, Candidato of Tochnical 3olonass; Ye. S. Rokotyun, DoaWr of Tochnical Scioncos; M. M. Satlyan, Cardi- date of Technical Saisnonal V. V. 31mirnov, Candidate of Tachnio4l acirincon; Vo S. Sadmov, Corresponding Hamber, Acadomy of Sciences UMRI 0. P. Sokolovekiy, Card 1/0  Rolling Industry; Undbook SUI 598 5 EnCinoor; 0. P. Scolov'yav, Engino)or; M. A. Sidorkovich, En,~Jnaor; Y(q. M. Trntlyakov, Enginoor; 1. S. Trishovskiy, Candidate of Technical Scluncoa; G. N. Khenkin, EnGinoor; ani A. 1. TneW;ov, Corresponding 1,nnbor, Academy of Sciences USSR. Introductiont A. 1. Trellkov, Corrosponding flonbar, Academy of Sciences USSR; " a ~.~~Iokotyan, Doctor of Technical Sciatires; and L. S. Al'shovskly, Can- di'date i T'.c6lcal Sciences. Eds. cf Publishing Housoi V. 14. Gorot,inchonko, R. M. Golubehik, and V. A. Hymov; Tech. E;d.t L. V. Dobuzhinokaya. PURPO,,Za ThIs handbook Is Intandol for tacluilenl paroonnal of rotallurgloal and machin-3-bullding plants, scientific recoul.ii Inotltu0a, and planning and do.- sitm organizations. It may also be ureful to studws at achoolu of highor education. COV91ULEL The fundamentals Of P18Dtic deformation of motels am d1ocuoood aSong with the theory of rc-Iling and drawing. tl3thoda of doterminine the power con- ewq)tion and the forced In rolling with plane surface or grooved rolle,ftre Card ;V*  Rolling lndustr~r; Handbook S)V/ 598 5 1 . Determining the capacity of a-c: motora 131 2. Determining the capacity of d-c, motors on the basis of measured parameters of a motor 136 3. Determination of the power consumption from the experimental curves 140 Ch. 7. Methods of Analyzing Power and Force Parameters of Rolling Mills (I. M. Meyerovich) 1. Dateermi ning the pressure of metea on rolls 148 2. Determination of torque 153 3. Determination of tension 155 4. Determination of electric parameters of rolling-mill motors 155 5. 1--3thodsfc)r calculation of the Eiequencecr reduction 156 Ch. 8. Fundamentals of the Theory of Drawing (S. 1. Gubkin and 1. 'General Fnf7o-rmation on the process and the stress-strain state of the deformation canter 157 Card 8/19  PERLIN, I.L. Determining the capacity of a rolling mill drive and metal pressire when rolling on smooth rolls. Izv. vys. ucheb. zav.; tsvet. net. 5 no.2:124-128 '62. (MIRA. 151-3) 1. Krasnoyarskiy instItut tsvetnykh metallov, kafedra obrabot.ki metallov davleniyem. (Rolling mills)  PERLIV, Illya Llvovich [Theory of the extrusion of metals) Teorlia prestjovaniia metallov. Moskva, MetallurgLia, 1964. 343 p. (MIRA 17:12)  ACCESSION ITR: AP4015111 SIO 136/64/000/002/0062/006!) :AUTHOR: Perlin, I.L.; Glebov, Yu.P.; Yermanok, M.Z, Effect of temperature, degree and rate of deformation on 'the deformation strength of aluminum alloys. SOURCE: Tsvetny,*ye metally*, No.2, 1964, 62-65 TOPIC TAGS: aluminum alloy, D16 aluminum alloy, V95 aluminum alloy, AD31 aluminum alloy# deformation strangthp:deformation rate, defo:M- ! :ation temperature, deformation strength temperature funotion ABSTRACT: The effect of different temperatures (360, 420, 4800) and various deformation rates (0.19, 0.8, 220 and 880 mm/sec) on the de- formation strength 8.1 was Investigated for D16, V95t and AD31 allualnum alloys. 7he deformation rate v affects S ,4 ; and with increased &et- gree of deformation~p, the IntensIty of the growth of 1% is decreasdd and In some cases even lowered (for LD31 ~j Is lower at a rate of 14 seo~-l them at 4 see.-' ). The cul-Ves which show the dependence of Q, on degree of deformation have a maximum, and It Is also showmi, that  ACCESSION HR: AP40151-1 the degree of deformation depends on temperature and rate of deform- ation. As temperature increases the maximum on the curve is shifted In the direction of smaller defoniation values; and with Increasing rate of deformation, It Is shifted in the direction of larger dciform-!. ation values. Working diagrams (fig. 1 ) of the U = f (t") relationship were oonatruoted by extrapolation from experimental data for the 3 ,temperatures investigated. Curves are also Included for the moi:'11, probable deformation periods enootmtered In extruding the given &110~s The lower curves 4w show the Initial values 0orresponding to S'~J~ forl ~tl = 3-6% and minimum. rate of deformation w = 0,03 seo-1 Or1g., art.1 has: 3 figures ASSOCIATION.- None SUB CODE: MZ DAME: ACQ: l2Har64 ENCZ: 01 rwo My SMI 009 SUBMITTED: 00 OTHEk: D03 2/f 1, Card:  "'A CBS 0140 AWA6044/0i* MN!e 4 latioaft be resistano6l and the 'cIT"'e, slid Dreo Wnk o -mew 8-~. f Wt zo,~ i"bilya rad 96 135-, 141.'_ d" SOURCE., __T "TAGS ceg-.'~ ago 6, z be"' -a, ungat me ou" -world-IV: 6 tOi tb _--on d:witfi Vie, ol""* 16 bm-`66166 R40A of ibffect 6t 6tr h; value-j4_8 -for relatIV6, stralnj~ up d~ mwj found oorroctly t, ~he! rate -6 rljg~,' I (if th6.1jc16vu shows the value of Od -depending onj Wdd reases, the miximium-S shiftedAmi, ird an . gr _d iii iViddbo. - 1b lbe. pteoe p*ef, the authors d6riv e s r Wing aj; e-'of Gtrp - i 0 dePam 9,0~(~iire6amiro, reoi at bJ& degre -bf -strain. It wu -ft hil~de-n,,wg~prooesis:~chiiigd"i along a cr as the degiee of straii Incream Bhow-, -damped.]Purv ec" nt -ROOM iZW~IA 1'ni4irMa'ODS*gy-oflpformation.Kpplroacl~losa ittainma)dra m bg that, 0 T*O' i of strahlt are considered In tbefirst,'at a constailf t8nipel4w X),'thD' in. the p  N V A uu#jI sit to ittv MCI -first fot t3 oilcofistAl found that xnalm* -it V44 'i jo.~ &,lbeglod Ing ma= traijz, tlw. I d6gr6es d6or- 6aw -of rize 0 Sd st we, at J. VONZ j* ME.: SUB L ZNO mA 00 ollm -1, Y-. d 115 4  Jf  Ar 4 ) '0i)r to 6r 0 A(01. , r /01m/u/00/m/0066 , Vi OQ,83 x4 jd _t6arink.-"' 6 f -ire Id ed 1 mA1 !~v i ii 7 s -A a _J -8 eta 83: If o-A p4hell tt' a t-6, delve- ani~' ni 9( c v 0 b" e Th e t L 4 i ps~ on r eces it -o '-esta r1mum u t wt h 'apsirt'!_ ucb -strip's4m 14 C: a ex- ion v a or ve I -or used- it' beat c angers.~ - eupross dth, thickness-and:_91 pal4ing _fIDtCe:p 061i thevi xonge, trip:,, -them, weld -at ng,th, d it reciprocal'of the ~Deijo -an th :with h a suf Ict*nt -Accu, 61 tk _rdjjt*g_:" _4,~ Ittidd44an, _q _'-~tbel...Cqn dgii-Uti* we 44d in OL 02  Izj.-. zq~ '~W:to4ftibltsb, ha -OfirmisiiblC 1~ill the i t i.C C --art XV go ;:14 f _1~777 -166 AM JE OTMMv: ~000 p': F I- WT ~~, i ~~ '.11 ~1~7 --- Fz Ji 5;z L2 IV ON  PLRLDI, I.L..:;- GLF,-,-X)V, Yu.P.; YMMMMA, M.& ChartLcter of ',,he dependence of the resistance tz~ deformnt-"nn on the degree of deformation In recrystallization prc)Ce:3-ges followLng the pressure workInj of' metals. Izv. vys. uchelb. zav. ; tsvet. me~. 7 no. 4035-141 "64 ("I,:RA 1") ~ I )  L 43713-66 WT lip t E. MW -C )AIL ACC NRs -~f600501 SOURCE CODE: UR/olli(-)/6(./c):)o/ool4,'Olil./0116 .Z2rlin.,. I (Professor) ; _qheliunov, V. A. AUTHOR: ORG: none and Durelwuin -yT)e al.lo _p2Lider loys TITLE: Nmch toughness of SAP (sintered aluminum I' SOURCE: IVUZ. Tsiretnaya Mf!talllurgiya, no. 4, 1966, 1114-116 TOPIC TAGS: 6 Lvd alumi 4U pmiar allok, dispersion strengthened metalp motal property/SAP aluminum alloy, D-16 aluminum alloy ABSTRACT: In order to evaluate the behavLor of SAP alloys under conditioni3 of .plastic working,a new criterion is proposed. The author introducer, "specific notch toughness" (b ), which is a ratio of notci,,i toughness in mkg/cm2 to tensile st:rength in kg/mm2. 4e temperature dependence oC bk was &termineA for five alloys: ,g&-_1 J6-9% al4minum oxides, SAP-2 q- 39 aluminum oxide)['SAP-3 (13-17% aluninum -4 --23% alumin-umoxi&4, aad D-16 (see Fig. 1). A significant increasei oxide) LqAL -J~7 - lk of bk begins aPdifferent temperatures, depending on the aluminum oxide content of alloys. The pattern of the bk-temperat'are curve reflects the actual behavioi: of the alloy under conditions of plastic defomation and its actual toughne138, For Card 1/2 1  L ACC NR, AP6030501 SAP-1// SII'-2 Fig. 1. Temperature dependence of bk for 44. S AP- SAP and D-16-type allwa. - /SAFLSj SILP-af eel SAP-1 D- 16 ~D- 16.. IN too JM 40 instance, the b of SAP--3 at 500C has a magnitude identical to that of SAP-1 at 250C, which means that the former alloy requires a higher temperature of plastic deformia- tion than the latter. Orig. art. has: 3 figures. SUB CODE: 1l/ SUEM DATI:: 29Mar65/ ORIG REF: 003/ ATD PRESS: 5075 ^Lf2 hs  L: vc,  PERLIN, I.L.; MIRPA, I.G. Metboas of-rating for,-03 neeipd for thi- t~parlng apart; of welded strip. Mvet.rpt. 38 no.3!:80-83 * 165. (KTRA 18-.6)  , Tj ~F77TF7777777 'Y' k__IDV _9 ==Off b A of,defojm on on be de-' mil, `i~ Tect of e e e 00-.' alid, dgadol! 17- I, res-i-StO-e of ~Magnesilmn ealoys! on 777- e- :_A ~d -uiagnesit*~ JIM P_v_---*d6f6xIhitioA~ We e orrA,,Ion- resilftance~i, au4p iomeilii_ t ';k Wormit:' rue j - Lon ~:b$~f preodurej tensile tes't deld point n 6~6 bf ~,the-i4jor par6etere -quired to deteftine..tbeitliermomet,baideal: _,6:Cthiv_6~6seeslbf metalworking- a urep at', well as io~~ r:L 4-,-' prope ~q ile 0 1 gm W, e d' 0a. i"'e8ista-ace to-def "d f ng~`t 1 e~y e -poitit.). 8 d. 'The: authDru ]A on M *~-re 84 ntal _e ovilt - ' f OP , experize estigatioin--vf- the of ivig&sij6i~ id3.OYB Ide'r f~iig-66ire#"oviding --td-the-pr, solng process,':; Thrie vi~~Vb couimC61Y;VSe heli ~,~nt 4: um- aj~a auoys were o1 ected for- the t1 ent - Y`a~ftentslym) Alp zhj, ~rangeei fr, ti, 78~'. C_j Yq.,, Sij.-Bt oa~ 0.01 ed *.;Ojjvted-tv_tenGi1e estop since t its, -tylie qypos p" i U66)"'Cirmolves -the a~o'i~ e of- friction:,vhiob:~affiztjs-ria~i,'~d3~,.+tbe: 14 m , - &~ - t r 406" ie Perroi a: at irei' Oxi covx'eg-~ i essi JLThq.,J~eots w4 &~. e etiperata n .ORGJ!d~ exertei rungin n nomal prep ing) the: tehille Sti. ' I a V_  ~779-6 *axCo"7-2 at AP.5C 1-17 6 -0 j "hi 4 U ~' v of _S' ~__Plohed i O~L % -be#! a of tb d N UAJ*~ #0 resefici 'ixed-Idepee--of de"formatfool the v6 -0 a 1.0 6. to-~ e v J~qam a! Aefdi. =t n ri Th llix te-'(f.rM Mo'A :74d~_ ie-876olnicildeslv~ h -de grees of lAeftomations: amounting to d M_ !0 an em - . e!l - . t 9'-t*' _--nittiNi :Ijic ~ea a- Ithe-geom ~17--Of'the sped i meas , pe3 -makes-i posilbj~e, to. - erw~h~ _4-16r _bicli6i_ie' ee- ,of: AeroxZ;J_on*. _-_The jreA -for t~'ii bi tt~4t- 'I may sa'increaseln,t 8 F~ is C eloiat6t-l -.7 ibt 'of.- -a oind deer 6n Oe. proportion - of - ibeAvM4d_deff*#on'.--. - naterl, I cor t6i~,hikci. The ~61rtalnj4 valu6t' Of-- 8 ~b -vaed for dynamic coumlatioj d lqW_ e ,g kermination of. 8 it i -q;')q')eddLentilto~~Lcbn~~...i.- lo I acU tate the dd Abe., 414- O'Of-D tp $feWt_ liot-dura t donni, to ,e; A I T1 sli Of- aourse~ provi ~s :0 tho. vpter 'Upnd Otthe ts Od ~ fcd~ er 10und of revepce:.- b 1 TiSorous. th deteiiir, the, 11:10 de'l;-r- a-; gxep a A-_& 6d si 1, Oj6lg 4- istion-his- nati- velop ea it Mt.. `00 VC K. 0 .ar  PERLIN) i.Id Fcrm of thr~ of tvnt!t,tit.14. con',oct. at.rr-tinrp Jijr,~nj, fcrg,'.ng of cylinders L~nd during rol.);np wi" 3.mootn rolls I. IZV. VYS- "Pheb. -'v.; t!:V-t. mat. P rin.1-245-14" 16c. 1;",g, 1. Moskovskiy vE!chprrjy rif,tal',urp,-,cherk-Ay In3titut, ktAfF-dra obrabotki metall.ov davlorilyeme  lit. fi r.x t anci  GILIDENGORN, I.I.S.; FEFLIN) I.L., prof., doktor tekhn, nauk, rukuvod~',e. raboty Cold extrusion of bimetal pipe. '4"Svet. met. 38 no-5:73 t-~v 165, ( 1~ ipA : E : C,  FE%,ITi " I.L. i KAY,'~M)MV b A. ; KOlfAI-FVA, N,M, S -I e: ~. lr3n c," r 11'. ing svei-.-- f ~,r zin, , '.S ;I I.. . 11 , - . i ---, , , ~,, D I --.z (m ~ )  PERLI N , M.S.; DOZORETS Yu.L.. PCPOVA, L.1, Had A. na I-! *, 1 1,e L -dj no I 13i '- n I t- t - 9 -a ume n , -j f t i,.;,r a t( X, ~~O:? I s ; resul ta of a 6- year s!~udy. Med. rad. 8 nc,.9, !~, 20 S 163. (14IFiA )".0 1. Iz kafed-ry rontgenollarrLl I ruedi~slpsRoy radiologil (zav..- dotsent 'A.S. Perlin) . go,3pitz--i noy kzav. - di-tsent Yu.L. Dozcret~'I 7-ebskog-) mE)dit.,q!ngkcg(,  PERUN, M.S. ... I . ---, -1 , , Work of the Vitebsk Roentgenological and Radirlogical Society. Zdrav.Bol. 7 n0-8374 Ag 161. (IffitA. 1~'2) (VITEWIL-A&DIOLOGY, MEDIGAL)  FM ,ill" , :1 . j . " s k v ~' ~ Solut!on of the I'Irst !'o Axmi-rl- ~,u ~ i ( ' r ~ .-- I,.-- ':)I e m ~ T. t ~. - theory of i'l-I Wea I by ~111 k~!' '-A Ivid 1. vpl,v,re. Inzii. zhi~r. ~'~ i~! . ' z, -- 161~ ~' P. ! 7 .'Q ' . lnstitu~' mfspha-''  - Z- - , - ., P i v , - - . . : V . .- 4 ~ I . , -1,.) ~ *. ,~ 1 . : I-; t ! - , , .1 ,, - r". , I .. " , , r , ~ i . '. r . i ; ". , " ., -a '. ,, .e - . . .1 . I ., r -~ ., . I . . .1 " , (,: 'I '7'f! * C, L ! , r~ - . . n.~~ . . Z- jr. " _i !-" . - : " - .- ()(Si~ l-, . - - I : v -,: . 0 : ., ,  27798 S/1508/60/0213/000/011/,'022 D2151/D305 AUTHOR: Perlin, P.I. ~Moscow) TITLE: Approx1mate method Of solving the elast:Lc-piasti,'- problem PERIODICAL: Akademiya nauk SSSR. Otdeleniye tekhniche8kikh nauk. Inzhe:nernyy sbornik, v. 28, 1960, 145 - 150 TEXT: A method is proposed for solving the elastic-plastic p1rob- lem with planar deformation and planar stress. A solution is then obtained for the case of a plate; weakenA* by a circular hole Vrith stresses at infinity. The case of completo enclosure of the PIELS- tic zone of the hole L1 is considered. (See Fig. 1). L 2 is the boundary of the central part of the zone. A circle L 3 is drawn with radius through the point a,,~q = /a/, /b,/,- /a/), Kolosov- Muskhelishvit- functions qp(z) and z) are introduced which'are analytic in the stresses zone, i.ft the region between L 2 and L 3' if Card 1/8 dr,  Approximate method of ... 2779n s/aos'/6o'/02e/ 000, 0 1 1/ 022 D251/1)305 the expansions of (p(z) and V(z) Aave no singular poi-nta, then a bolution is obtalned for the auxiliary elasilt: robi. m o' a plate With a hole L 3 with boundary conditions cf(t) 7t !-t~T --- f ( t Expanding f(t) in a Fourier aeries witha~,,finite number of terms gi-- ves 7-nn 2 k + I 2k+l f(t) ~ ~ a L-j 2k4l(~L 2k*-.- P k=O [Abstractor's note,~ i not defined]. Determination of .he%W-Oeff.:~-- ciente a and 0 leads simulune-3usly to finding the intermediate points of the boundary~ A, pencil of straight lines is considere d, commencing from the center of the circle and maiting angles (W-12,1 (1/m+l) with the ccordinate axes (m ia the nu4b~r of ine lint?),' By the approximate solutllon of the ela.8tic-plastic problem of order m is understood the totality of poilats 8, situated on the lineii of the pencil and the points a and b~ satisfying the condItions ela- ve Card 2/6  2779n S/508/60,1'028,/000/01 11022 Approximate method of ... D251/D305 ted below. It is assumed that the boundary passeF through some -,,o- tality of points t i" Obtaining the components of stress tor s., ~ij and the fig a relationship is obtained between the componenti3, hav- ing 3m + 4 solutions. The 1, will be correctly chosen if the ecila- tions satisfy conditions ar'laing from 2m + 2 of the unknown coeffi- cients of the expansion of f,11t) wid the coefficients u 0 and t30 gi- ven by X + Y a.,- I.P.-I .1 !~ 1; X, 4 ` 1 4 Where the boundary d--ffer.9 from a cir-le, the anC. y-[-L,, conTlnua,,~_on of cP(z) and '0(z) right up to L3 io not. possible. The E-Ilipsea L4 passing through a and b is -onbidered (F,-,g.3).. In thIs case (1) L 2 may lie outside L 4' (2) L 2 may IiE ins.'de L 4' (3) L2 and L4 R,ay intersecT. In case (1) applicatior of the me-. hod Is possible if in the analytic continuation of cp(z) and J(Z) ~o L 4 there are no sin- gular po-4Mts, In case .2') the conformal transforma--on Card 3/8  Approximate method of 60, 1_1~9 (~'O D2 D~ ~. 5 M. A is used to transforn The Interior of the uni-, cir~.e .n -uhe Tane onto the interior of L4, Lei L; be -.he greatest contour corrE-Srond- e f, ing to a circle in the t-plane deEi~,,_rlbed ins,-de L2,, ThL- app.:cation of the method is pussic,e if '~Q(zi and 14)(z) have no singuiqr points inside L21. The conditions for appiying the method .'n case ,3) are similar to those for (2), The so.L,tion of the problem of a p"Late with an elliptical hole, may be -carried out as for a -r-;ular hD,.e, by means of a conformal transformationtij ln Ihe case of large plas- tic zones, it is not possible -1-o use the elastic soiation 'to sa- tisfy exactly the boundary conditions on arcs of the#:ircumference. In such cases (Fig, 4) an eilipBe L4 passing through a and b is used. The boundary conditions for arcs of the circumference will be satisfied for certain points. A contour L5 passing through t1l'a points i, a, b is to beJound LAbs-tractors note-, i not defined),I, Presumably the points f&,, ; wbleh the boundary ;:onditions hold]. ti Card 4/8 t1K  27798 S/50 60/028/000/011/022 Approximate method of ... D251YD305 will be found from the condition that the conformal transformation which maps the inside of the unit circle in the r' -plane onto the inside of L5 is of the form m, + M2). Y A(` + '3 The method given ma,Y be extended to the case of non-circular,, 'but symmetric holes. The best case of satisfaction of control equations takes place when -the intermediate points lie on an ellipse corres- ponding to the solution of L.A. Galin (Ref. 3: PMM, v. 10, no. 3. 1946). There are 4 figures and 3 Soviet-bloc references. SUBMITTEDt January 20, 1959 Card 5/8  lid rly!:-.. r r t, i r f- r I t i c i d, o I L i I -tic colo! I-,, J! c - T C-7  FMIN, P.L,kand.fiz.-matem.nauk Slastoplautic distribution ofstressen miound apertures. Trady MITI no.5:30-40 160. (MYRA 13:10) (Illaisticity)  FUMNS P, I,, kand. fl a. -matem.nauk Properties of Infinite theory of elasticity o 12'5-133 160. mys-tems of eqmstlons In probleps on the doixbly connected bodies. Trudy WTI no.5: (Blasticitir) (W.PA 13 - 10)  ACCESSION NR: AP4037101 S/0256/64/004/002/0275/0280 AUTHORt Perlin, P. 1. (1.109cow) TITLE: Solution of the first Inasic axisymmetric problem in elasticity theory for a region bounded by an ellipsoid and a sphere SOURCE: Inzhenerny*y zhurnal, v. 4, no. 2, 1964) 275-280 TOPIC TAGS: axisymmetric problem, elaetticity theory, stretched surface, elestic equilib:~ium, shift modulus, PoisGon coefficient ABSTRACTI.- The author solves anlaxiay=etrio problem for a region bounded by an ellipsoid and a sphere by a method which is a modification of a method given by in a previous paper for solving the first basic problem in elasticity theory -,,'or a region bounderl by two surfaces. He effects his solution by deriving an infillite' Wstem of equations for the unkmown coefficients in his proposed representation. The system can be solved by successive approximations. He treats the case w1iere the normal component is equal to I and the tangentW component is equal to 0. Orig. art. hass 12 fornulas. ASSOCI4TIONs Institut zekhaniki AN SSSR (Institute of Machmnlas# AN SSSR) 1/2 Cesd  ACCESSION NRt A.P4037101 SUMUTTEDs 20APr63 SIM COMO Ab, V.A Card- 2/2 IUVE Acql 05JV=4 NO-REP SM 002 EXCLs 00 OruRl 001  FARLB. P. 1. Moskva) I-- - Approximate solution of clasoplastle problems. Inzhosbor. 28:145- 150 160. (MIRA 13tlO:I, (Itinsticity) (Plasticity)  NILQWV9 M.N.; -PERLIN, S.I. -- Nature of changes in the :omposition of organic subBtaazes of peats as related to the degree of Lheir decomposition and type. Pochvo-redeaie no,3:77-82 Mr 163. (MIRA 115:3) 1. r,.entr&llnaya torfo-b)lotnaya opytrLaya stantsiya. (Peat)  GILIKAN, T.F.; PARLIN. S.M.; LNMI:, A.Z. Ilectro consistometer for determining the lprooessing time, getlatl-- alsation, and hardenizg of resins. Plast.masay no.lls68-71 160# (HIM 13:12) (Resins, Synthetic)  MLIN. S.M.; TUROK, N.M.; GRINIAT, V.N. Processing of poly-vinyl chloride into articles by molding und*r pressure* Plast.massy no.6:26-30 160. (MIRA 13:11) (11thylene) (Plastica--Molding)  ( PfRIIN, S.M.; SOBOLIT. D.Ya. Instrument for determining the coefficient of a Up friction. Zav.lab. 26 no.12:11406-1408 160. (MIRA 13:12) 1. Vossoy=W nauchno-lealedovateliskiy i proyektno-teklinolo- gichaski:7 Institut UgOVU09D mehlustroyent". (Teating mchines) Opriation)  S/"-l So/ .) / 0c, B004,/BOtJO AUTHORS- Perlin, S. M. , Gil' tan, T. P, , WAlfMIWI;.~J0 TI TLE: Stud~' of the of harJk.,r"1,6 A Polyester Rf'3ins b~ tl~(, Mk~thl(l PERIODICAL: Pla.stichesk-lye mass,,,, v360, No. 10, pp. TEXT: The authois studied the ha.rdening degree of KH-1, (Pl-i) r~Zl-~ the U.Se of different initiators and cataly"s. The previojsl~- pr-rf-~rm-j tests for Rock-well heat, bending :3trength, and water absorption 3h,~s,,J that no clear kLowledge can be obLained concerning the hardening on -.h.--- basis of physicomechanical tests. An inveStigation was th-~ref-ie -on.1,;-t- with a Schevenaar differential di--atometer of the firm Am3ler, D~ia-;iti curves displayed breaks with insufficient hardening of the resin Ih.,- following optimum values were obtained fo-- the addition 3f catalyst: 3% cumene hydroperoxide (initia-:or) and 6-8% cclal* (catalyst . At 1 . '5;~ benzoyl perox! de and 0. 6~o' d3. methyl an., I j ne a cor.q et t- hardening was attained only af ter repeated heati ng, D1 latam,3 tr 1 c cul of the following glais reinforced piastic~ were also taker,. 1) 5a~- Card 1/2  Study of the Gcm:)letci,, -L A' ~-nirq~ ;f 6/111 11 r-C'131-c'I U113 at ur ate d Po 1~ k-,st,~-r Rt-s . ns I,, *7~ D i I i;. t t r aB 0 0 B C " C Method pheno" ' f ormal dehy i,- rf~- si 1 tl~ 7 C polyei3ter resin with -lu,s, ro(,~- 4) polyester resin with blus8 mat Th~ A' curves showed tnal in uii specirneiis ~.ardenir,6 inc-cm-~'--'-. TI. figures, 4 tables, and 6 references: 2 Soviet. US, a;, I Card 212  2 3 D 2 AUTHO RS %NP E"j and Sobolev, D. Ya. 1.0 z $4 TITLE: Device for Determi~ning, the Coefficient of Slidinj~ FCLCtiOll PERIODICAL: Zavodskaya laboratoriya, 1960, Vol. ?(,, No. 12, PP. 1406-1406 TEXT: The device suggested perm:.ts Jetermination of the coeffi~,ieil- of friction in the wearability teat of plastic and other materials in %ne case of dry friction, with water, with lubricants, and in the p:7es?,,Ice of abrasive material. The coefficiert of friction is determined hj iiz; , er t a 1 n - ing the friction torque produceJ in tile pair of specimens teateJ, ,) 14! of which rotates with motor drive, v!hereav the other is firmly fusten ~a to tne axis which is connected with t:,e meEsarir~1-7 part of tile device. 'the divice consists of three main parts, vi2,, ti,e ~~)e.-Lting, :J.Lusuring, and j it mp i-,,, devices. By means of this device, the coefficients of' E;liJinF fric u n f several pairs, were deti.,rminvd. T1.(j !i-ction lounui In th(i lovic4i i oll 1 1* are determined ny the losses in the bal' bearings luring rotation indicator and the blocks. Taring of the device is described. Tntere ..re Card 1/2  i;evice for DeteriLining t:,e Coefficlent of Sliding Friction B020',B056 1 figure and 1 table. ASSOCIATION: Vs c s oy-j znyy n au c h. i o -s- s& I o vz., t e i I s,. i"ro t; J :~ 1! e:i k i y -, n s t i t, j ' Li o In u ~;o ma sh i!i,) S t i-o y e ri iy a (All-Union L~cienti fic Research, Design, and Te-,hnological Institute of Coal Machinery) Card 212  G'UBEIN. Sergey Ivanovich (deceai3edj. Prinimal uchastiye STOROZHBI', )I.T.. M IN, I.Ta., reteenze:at; SMIRNOV, V.S., red.; MLAHOVSKLYA, .- I.-A.. r4id..izid-va; ISL311TOYETA. P.G.. takhn.red. [Plastic deforiwtion of wtalej Plaaticheaketa deformateliej metallov. Moskva. Gos.nauchno-tekhn.izd-vo lit-ry po chernoi i tovetnol matallurgil. Vol.l. (Physicomachanical principles of plastic deforwtionJ Fiziko-mokhanicheakie oanovy plai3ti- chaskoi deformatell. 1960. 376 P. (MIRA 13:2) (Deformations (Machaiiics)) (Physical metallurgy)  G o s ere t r Il not, )I SO: