SCIENTIFIC ABSTRACT SYSOYEVA, T.K. - SYSUYEV, YU.A.

V -!*. R T r. T, 7V - Scme data cL the bloloo cf LIvonece anurensis Cer~ftfeidt (Crustaces, Isolode), Zoo-, '7 hur. 4, 1952. 1952 9. Monthly List of Russian Accessions, Library of Congress, Cctober IIJ53. Unclassified.  8Y60"-170iAl T. .*,.. "The Biclogjr of the Yclin,7 of Some -vvJty Basjr. in Ic A,~,,pro~luct- ~L Sci, 'I'cscov State U, '-'oscow, l."153. Corm-mercial Fisl, in t'-- Amur in Tneir 5chools.11 Cand B-Jol (MhBilcl, No 1, Sep 54) SO: Six~% 432, 2) i.ar 5c,  -RARAIMIKOVA,.A.S.; BARSUKOV, V-V-; POITOMARMO, I-Ya-; T.K.; KWKHLINA, N. S. Morphological characteristics, distribution, and feeding of young voll fishes (Anarchichas lupus L., A.minor olafsen, A.latifrons Steenstrup et Hallgrimsson) in the Barents Sea. iool. zhur. 39 no.8:1186-1200 A& 160. (VMA 13:8) 1. Polar Institute of Marine Fisheries and Oceanography, Murmansk, and Zoological Institute of the U.S.S.R. Academy of Sciences, Leningrad. (Barents Sea-Wolf fish)  LEYTIS, Z., inshener; SYSOY9VA, V., inshener. O=NWMW* Namial of track development &M organization of shunting operations. Kast.ugl. 5 no.6:24-26 is '56. (NutA 9:8) (Donato Basin--Mine railroads)  UYUS. Zalchar Moiseyevich; OYAVA, Valentina Aleksapdrovne; RATNIKOVA. A.P.. redaktor izdat-5-sr, W, Mv? aine '1~ redaktor e1 a va, CImproving woric organization of underground transportation in mines of the Donets Basin] Uluchshenie organizataii raboty podzemnogo transports na shakhtakh Donbassa. Moskva. Ugletekhizdat, 1957. 70 P- (MMA 10:7) (Donets Basin--Mine haulage)  LEYTES, Z.?4..--SYSOYXVA, _Y-A. Field of efficient use of conveyer transportation in the extraction sector. Hauch. t rudy MGI no. 20:38-44 158. (MIRA 11:8) (Mine haulage) (Conveying machinery)  BUCHNEV, V.K.9 prof., doktor takhn. nauk; KALDIN', R.A.p 4otsent; KORABIEV, A.A.p kand. tekhn. nauk; MONIN, G.T., in2ft.; BRT I V.S.9 kand. tekhn. nauk; MEREIJLCTV9 V.Ye., inz3j.; ALEKSEYEIKO, V.D.t inzh.; ILISHTEW, A.M., kand. tekhn.nauk; GELESKULt M;N.1, kand. tekbn-n-ax, KOBISHCHANOV9 M.A., kand. tekbn.naukj DOB40VOLISKIY9 V.V.9 kand. tekhn. muk; MALYSHEV9 A.G., inzh.)- VOROPAYEV, A.F., prof.p doktor tekhn. nEnk; LIDINq G.D.9 prof.p doktor tekbn.nauk; TOPCHIYEV9 A.V.p prof.; VEDERNIKOVj V.Lp kand. tekhn-.muk; KUZIMICH9 I.A., kand. tekbn. nauk; LEYTES, Z.M., inzh.;-AJ"AX..A.-p-kand. tekbn. n=k; MEIAM, Z.M., kand. tekhn.nauk; inzh.; RARPILOVICH9 M.Sh.9 inzh.; MELIKUMOV9 L.G., inzh.; BOGOPOLISK]YI B.Kh., inzh.; FROLOV, A.G.9 doktor tekhn.naak; KHVOSTOV9 F.K.p inzh.; BAGASHEV, M.K., kand. tekhn. nauk; KAMINSKIY, I.N., inzh.; PETROVICH, T.I., inzh.; ZHUKOV, V.V., red. izd-va; LCUILINA, L.N., takhn. red.; PROZOROVSKAYAy V.L.9 tbkhn. red. [Mining engineers' handbook]Spravochnik gornof;o inzhenera. Moskva, Gos.nauchno-tekbn. izd-vo lit-ry po g3rnomu delu, 1960. (MIRA 14:1) (Mining engineering-Handbooks, manuals, etc.)  1ESIN, Konstantim Koxistantinovich- 8-Y-S-CYEVA, ... V_. A.. Iotva red.;, ABARBARCHROK, F.I., red. ik--vaY N.D., tekhn, red, [Safety problems connected with underground transportation in coal mines] Voprosy bezopasnosti napodzemnom transporte ugoll- nykh shakht. Iloskva, Gos. nauchno-tekhn.izd-vo lit-ry p0 gor- nomu delu, 1961. 39 p. (KIRA 15:3) (Mine haulage-Safety measures)  SYSOYEVA, V.A,,, kand. tekhn. nauk; LEYTES, Z.M., kand. tekhn. nauk Analysis of the length and volume of transportation in under- ground haulage by electric locomotive. Vop. rud. transp. no.5* 210-226 161. (MIRA 16:7) 1. Institut gornogo, dela im. A.A. Skochinskogo. (Mine haulage) (Electric locomotives)  LEITES) Z.M.., kand.tekhn.naukj SM30UNA,, V. ,_kand.tekhn.nauk Technical and economic comparison of electric locomotives with storage batteries and diesel locomotives. Ugoll 36 no.12:45- 48 D 161. (IAIM 14:12) 1. Institut gornogo dela, im. A.A.Skochinakogo. (Mine railroads) (Locomotives)  kand. tekhn. nauk; SYSOITWA V.A. , kand. teklin. nauk; LETPHS I . n. j VAYNSE T:Zj7, !.A. , kcand. P'5tubllohing optimum flow-sheets for underground transportation with the help of graphic methods. Ugoll 38 no.8:53-57 Ag 163. (MJRA 11:11) 1. Institut gornogo dela im. A.A. Skochinskogo (for Leytes, I`y- soyeva-). 2. Moskovskiy gosudarst-ennry universitet (f;r Vay-n- "Ilteym).  Syl~f - , . - . , 1 ~; nd. WE Im. rimik; ANITONIOVSKAYA. M.A. , ill:511. I'L.11.ySis cf ilhe systemo and t-~chnical means of underground tranoportation in mines of the Soviet Union. Ilauch. soob. IGD 2 6, :5-20 165. (MIIIR.A 18:9)  ILYTES, Z.M., kand. tekhn. nauk; SYSOYEVA, V.A., kand. tekhn. rauk; CHER'i-ENIKO, Ye.B., inzh. Cost parsz.,,eters of underground transportation in mines working sto-eply pitchIng seams. Nauch. soob. IGD 26:21-32 165. (MIRA 18:~,)  -nn i. to khn . n-.1 u K, 1. SYS( YINA, V. A. , kand. tti ~,hn . n,"u'r-. GUD.!'.f)V, V. P. ANTONOWAAYA) M.A., I.nzh. c.." mQdeling nder-ground t~,ans,,-crtatlon. Uvl;ll 40 nr-.9~35-38 NIRA 18310) 1. ins-t-' t.ut- gc-ncgo da'la i.m. A.;A.SlkcchLn9kogc,,  (M) /EwA (d) /T/FX'P(t)/17-4P(b) ASD(m) -3 MXo1/JD Al"C'ESS'10"i '~N-(: A340 4 7 5 3 4 S/0277/6L/000/008/9.009/ooog SOURCE: Ref. zh. Mashinostr. mat.j konstr. i raschet detal. mash. Ctd. v-y*p., Abs. AUTHOR: Astaf'_7 V S T s y~:p~~Lrka .qva, Ye. V. SVsoveya. Chumak TITLE: The problem of the use of high strength steals CITED SOURCE: Sb. Le7irovaniye staley. Ktvev, Gosteldiizdat USSRf 1963, 14-20 TOPIC TAGS: hiph strenf7th steel, heat 't-1;reatment', work hardening/ steel 45M1-NMFA,,' steel _401',hNVA, steel 371-ail";ZA TRANSLATMAI: Methods for Increasing, the static and cyclical strength of high strongt~i steels by heat treatment and work hardening are surveyed. An investigation of the eff"ect of thermoviechanical treat- ment (austenitizinr partial coolin3 to 47o-6oooc, u _~ at 930-9500c, 1 doformation of 25-50-,, hardeninG, tez.-ipcrin~, at 1000C) on the strent-Ith of L51-2iN--71A, 401-27iNVA, and 37niNZA steels showed that strength was Card 1/2  Card 2/2 A 4.-1 V  ,tltc'cd bY   . - I / / , I)-zv- -.~ C -- -P- v?l/ V 11" I MYFNTS, V.L . : KRASIKOV. B.S.: SYSOYETA, V.V.; GUSEVA, I.V. , Investigating the adsorption of aliphatic alcohols. Part 3.- Adsorption at the passage from aq~ieous solutions to alcohol solutions [with surmary in Nnglish]. rest. IaU 12 no.22.-14.8-151 1-57. (MM 11:2) (Adsorption) (Aliphatic compounds)  C, AUThORS: laeyfats, V. L., Krasikov; F. Sysoyeva, v. ,T., 5L-_1,._i,7/2:: I. *j. Guseva, . . TITLE-. Irriest.4-gation of Adso,_-ptiop of Aliphatic Spi:- 3. ITT. Adsorp"on it - -J~ at the Transit Froin Aqueous t-o Altxholic SOjU140r!_ -.7aniye adsorbtsi-i alffatichesirikh spirto~.. HI. AdEorbtsiy! pri perek-hode ct vod-nykb- .,,a,9tvcr,_rcv 'tz sp,Jr-',cY-,-jm). PERIODICAL.4 Vestnik Leningrad3kogo Univarsitata Seriy~-_Fizikf. i ni-aii, 1957, Vol.. 22, Mr 4, Pr, -_!.48_!5-_, (ussR"'. ABSTRACT: Examined was the adsorption of ethanol, n-propanol and fso-provanoll in: a concentraticn of 16 to 15.1^-3 mow], on the Hg-electrode, by . measurement of the volta_6a, whin.1i criginated from the c a ty of ap ci. - the double layer and the eiect~-,de_ potent-ial. The prc-sen" of the alcohol-hydrates in the 5olution be explained by the fact, tha,~ part of it is to be found in the double layer even if there is no tendency to specific a1scrp-or 41.~ , the ~;apac-t,-, of 'he double layer goes down. -the detcrotijn of the from the doub7 layer can only be eMcted f the k, h re are fz-ee water molecules pre- sent, in the (no hydlr_-~e_= of "he typo R.0,F2 OH.11?0). There are 4 figures, I -,'-,ab.Le, and 5 r_cfezences, )- of -Wii,~h axe Sla- Card 112 Vic.  Investigatica o--:' adsorption of 11-1. 5 1, 7112;) Adsorption at the Traniit From aque.--iie- ",,- SUBMITTED'. February 22, -11956. AVAILABLE. Library of Card 2/2  AUTROBSt Krasikov, B. S., Sysoyeva, Ve V. 2 o - 324-4-4o/63 TITLXa The Zero Charge Points of Some Metals and Alloys (Tochki nulevogo zaryada nekotorykh metalloy i splavoy) PERIODICALs Doklady Akademii Nauk SSSRt 1957~ Vol- 114, Nr 4, pp. 826L828 (USSR) ABSTRACTo It was revealed in the investigation of the Zero-oharge poten- tials of metals (In-3) that this value is dependent on a num- ber of factors, including composition and state of the metallic phase. In the case of the mercury-thallium system it was shown that this value varies according to the proportion of the con- ponents in the amalgam. The research was carried out in order to-measure the potentials of the zero-Dhargog in order to ob- tain some new knowledge on the dependence of qn.3 on the com- position and state of the metallic phace. Objects of the expe* ~.ment were monooryal-Galline nickel and ferroniokel alloys* Fig.1 records the ourvess oapaoity-potential of the zinc electrode. They indicate that.the sero-oharge potential changes according to metal structure. Apparently the energy of emission of the electron from the metal changes also , in dependence on the compactness of the atom-packing in the crystal lattice of the Card 1/3 metal, and therewith Tn-3 of the metal changes as well.Poor  The Zero Charge Points of Some Xetals and Alloys 2o-33A-4-40/63 compactness of the packing facilitates the emission of the electron and thereby the displacement of In-3 in the direction of negative values'. The measurements of f,.3 of pure metals,- which were also obtained by electro-sedimentation, are in good agreement with published data. In the case recorded here;(fig. 3) there a rather abrupt change ofj, to was observed due to an alteration of the content of that in the alloy which posc- sesees a stronger nigative value than TnO' The uniformity of the dependence-curye of the zero-charge po ential of an alloy proves, according to the authors, that the ferroniokel alloys obtained by electro-sedimentation form solid solutions. Thus it may be said that in the absence of factors capable of d*. .,tuVbing the uniformity of the change in zero-oharge potential in dependence of the alloy composition, the zero-chaxgo paten- tial of the alloy could be determined already at a oomparatift- ,,qly low concentration of iron by the energy of the electron emission out of the iron- a metal which possesses a stronger negative If value. The reaults reported in this paps;r em- phasize the nfi~csss,ty to take into account the composition and the state of the metallic phase at measurements of the zero- charge potentfal. There are 3 figures andpo references, 9 of Card 2/3 which are Boylilt.  The Zoro Charge Points of Some Metals and Alloys 2o- 114-4-40/63 ASSOCIATIONt Leningrad State University imeni A. A. Zhdanov and Scientific Research Institute for Telecommunication (Leningradskiy gosu- darstyennyy universitet im. A. A. Zhdanova-i Nauchno-issledo- Yatel'skiy institut telefonnoy svyazi) PRESENTED: January 2, 1957 by A. N. Frumkin, Member, Academy of Sciences, USSR SUBMITTED.:* December 11, 1956 Card 3/3  50) PHASE I BOOK EXPLOr-ATION SOV/22!6 :Iektrokhiml!. 4th, Moscow, 1956. Sov::hchanly:opo Is rn I (Transactions of the Fourth Conference on Elect Tru ....I rochemistry; Collection or Articles) M~sco-, Ird-va AN SSSE,* 1959. 868 P. Errata elip Inserted. 2,~:,C copies printed. Sponsoring Agency; Akademiya nauk SSSR. O~deleniye 'cAlmIcheakikh uk.*- Ed"itorialoBo:rd1z~dA.N. Prumkin (Romp. Ed. ) Academician, O.A. Yealn, Prof*aa r$ S. Zhdanov (Resp;cSecretary), B.N. Kabanov. Pro. feamor, S. . 2 anov (Heap. 3 retary); B.M. Kabanov, Prcre3aoru Ya. M. Kolotyrkin, Doctor of Chemical Sc4ences; V.;. Lasev. P.D. Lukovtaev, Proreabor; Z.A. Solov-yeva-, V.V. Stander, P-Ofellsorl and G.M. Florlanovich; Ed. Or Publishing House: N.G. Ytgorov; Tech. Ed.% T.A. Prusakova. PURPOSEt This book Is Intended for enam-1cal and electrical engi- neers, physicists, metallurgists and researchers Interested In various aspects of electrochemistry. OVE AGE; The book contains 127 of the 12B rvports presented at I t_ the Fourth Conference an Elect rochemlAtr~y sponsored by the Depar ment of Chemical Sciences and the Institute of PrLyalcal Chemlatrj Academy of Sciences, USSR. The collection pertains to ~Ifforant branches or electrochemical kinetics. double layer theories and galvanic processes In metal electrodepositon And Industrial elect- rolysis. Abridged discussions Are given at the end of each dIvI- nion. The me jority of reports not Included here have been published In Periodical literature. No ;Arsonalltles are mentioned. References are given at the and or =oat of the articles. ---A.A~-Znoano,vafoor..!kiy-Polytechnic Institute !=cr.-- A.A. Zhd nov), Influence of Aging Processes on the Work of Alkaline-Zinc Elements 768 Lu1;htceev;a1j. Theory .1 Processes Occurring at Oxide tF -Purces of Current 773 A., and-_V_L__L*vIAa_ Mechanism of the Activa- _~~~ron Ilectrode With $.a 11 AddltIons of Nickel Oxides 781 -Balulig-va-It-A. , _VA. ry_uQjt. and L.D. Z-vbft (Institute of ElectrOchemletri7reademy of Sc11_e`nc_e_&,_0S3jn. Using Tagged At om a to Study ProcessesIn Chem.4cal 5ourceA of Current 788 Danl v qM _Unta V V S.- ~ va, and N V_ _71INKiova edova;i ur gorcd36:oy I n'. BeltakOy AvyazI M niaterstva avya!! SSSSR - Sclent-fic institute of Rural and Urban Co=untcationn. min 1. try Of Communications, USSR), 'nvestigat of Fuel Card 31/34 and R. "_ !~Ar_shte7r( Institute for Elect. rochemlatry, AS USSR. M-oj~o~j.~ I_ro__n--Zar0on Element Sol _LeYkIA_-D_I. (Institute of Electrochem!stry, Academy of Sciences, USSR). Effect of Salt or Oxide Layers Formed in Dlscharjt~ or Charging Procealaea on the P&33'vu,-Icn or Battery ziect.- rodes A2111AkIlk, S.F. , and L.A. 4cOnt_jycs_ Influence of, Cathodic Polarizi-tilo-n at LwiYi~-Peratu,s on tne Anode Potential or an Iron Electrode in an Alkaline Solution all Discussion IS.A. Gantican, U.S. LIdOrenko. P.P. Yupp*ta. A,r. Xwenofontov and contributing authors) 814 PART X. ELECTROLYSIS IN THE CNEXICAL INDUSTRy 821 Card 32/.34  T P-, i- S OV. A r o t Iu c t i c n o f A 11 o,,~ s oro n V17 ck e 1. 'cY S e c- G'- 11 QZ-OLIS L: 1 Pc tro I ytes (PO -ILLC'!-OY I -J";!~.' pl. avo-.r z'n-e-, - --7. zn iem iz 101), CL: Zh-~zrnal urihla-dnoy khimii, 15'5", r 1, pp 1')i---152 (11j"I"RI -j- -~C'Y: Thie ;-lutaor 1,;reserts the rozultZ o- a seric3 of experiments sho-aing the practical posoibilit.; of uoin-- the chlorous e lectrolyte for coating with the 2e - 1:1L alloy various U concentrations of its components. The temperature of the electrolyte was maintained aith Lin accuracy of "' 0.20C. Electrodes used -.,;ere iron ones (of Armco-iron) and nick-el ones of the N-000 grade. Certain relations were found between the composition cf the alloy obtained on the one hand and the temperature of electrolyte, the ratio of com- ponents in the electrolyte, and different correlations of densities of current on the iron and nickel anodes, or, the other hand, and these relations are presented in g7aphilcal .Lorm. The following conditions are recommended: the con- centration of the sum of iron and nickel in the electrolyte should be 100 g1l; the density of current = 40 amp per Card 1/12 s-,uare decimeter; temperature = 700C. The thickness of  s OVAC, - 5 9 - pf-o !-,;CtiQn C,~ Alloyc (,-I' Iror. V.,'ith ;.ickel Settli., :-'rom: C'hlorous cu--,tin- can attain 10.5 mm and ever higher. tD There ai~,- 4 -.ncl, 16- references, 4 cf winich are So-iiet, En~lioh, 1 japa-ncLe, 7 American,. 2, Gerr--ar and 1 unl.,3cnti- fied. ED -April It'5" Ca--?-d 21-12  250) SOV/119-59-6-7/18 AUTHORS: Daniyell-Bek, V. S., Candidate of Technical Sciences, SysoYq.Y_a,_.V_., ,'engineer TITLE: Electrolytic Coatings of Iron - Nickel Alloys (Elektroliti- cheskiye pokrytiya zhelezonikelevymisplavami) PERIODICAL: Priborostroyeniye, 1959, Nr 6, PP 17-18 (USSR) ABSTRACT: The utilization of the coatings mentioned in the title is based on the consideration that with a content of from 30 - 405/6 iron they are not inferior to nickel with respect to their protection against corrosion. The authors worked out a procedure,iby which an iron - nickel alloy is precipi- tated from a mixture of iron- and nickel chlorides at high cuErent density (40 - 60 a/dm2). Electrolysis occurs at 70 C. The anode is an iron and a nickel anode each. The electrolyte contained 25 g11 Fe and 0-75 g1l Ni. The noxious influence of trivalent iron was eliminated by the addition of citric acid. There are 2 figures and 1 Soviet reference. Card 1/1  OVI 1. 7" ol~ V. 33 i n ts V. C- I.he App-lication ef '11-drocarbon Fu ~,J i '-,'I or ~cn 45 o-it I i1 i 1 c! - t r ol (0, r~rirenvtiii v z,:iurivil rVAadnoy Irldriii, Vol "'CX H, IN"C: pcsoibilit.lo of wind- fut:;! tic,n,3 awl bro,-Jc~-stin- uw.:- ratuses in areas -,t i~,i trici t- is i-orestiZatcd here. The of L;enGrato1.---; i.- -1, ~:Cn- so liqidd 1 fcr t'A"L venient 3 . , urpose -nadc. b- R- '. 7 tr t:!c f!c--rcIuz;ic:1 th,-It --i-Au-ce,; r-f hv-.-.rcc:2-, 41- 1.;,6. U.w:c if, a olinc en,:;[Irt: t~;--Grc-ticnl 1 cl-,~ Of 1-10-1-15 i if tho "C- I (100c,: !-,r,- ez-..f e 11-o(Iucc cac. rl~-,y fz.(jl:-, tbL~ clectroclhz~uicul of the -jurnin.-- -f ~~.,:.oo- r 7 line. .'n cxperiment sho-:,,s that the optimum 'feuperatu e i I GO- C'. -~I 1 t,,-- -.-rf C1.8-0.9 v, the cu !e; 2 75COC: 1'z-ent den,,it,; 1-0-1-5 : 1, -  SO V/8O-1712-I;-'-:J r-1! 4"no _,ipplicatiop of' liyzirocarbon ILel i.-n Element-- '.C." t.-: er :icvera, i-Iour", D L i-,, cyrdained thc by Fao permeability -re 5 -,rap'.*_,o. -here cas, 8, Of V.,11-ioh are -Ac-C."k-1-ic iI1,j*Lcw; P; r-fluctior, of var' of Ulu ~1- etc. I set of 2 t,:Lles, refe~-C- -3nviet, ~r7) GCI-man, ;-Cric-P, r,57 ~---rd 212  5.5400 77516 SOV/80-33-1-25/49 AUTHOR: Sysoyeva, V. V. TITLE: Investigation of Polarization Curves in Chloride Electrolytes PERIODICAL: Zhurnal prikladnoy khimii, 1960, Vol 33, Nr 1, pp 147- 153 (USSR) ABSTRACT: This is the second article of a series on the electro- deposition of iron-nickel alloys from chloride electro- lytes. Polarization curves of electrodeposition from FeCl2 and NiCl2 solutions and also from mixed (FeCl 2 + + NiCl2 ) electrolytes of different concentration at 20-700 were obtained and investigated. From the capacity values of the dpble layer were calculated the current densities per cm of the true surface (D d' usin- data on current density, related to 1 cM2 of the M geometrical surface (I d' In Figs. 1 and 2 polariza- card 1/9 tion curves are given in -10-9*ik and coordina.tes;  1[r) v 0 Z, L. " til Cp tga~. lot) 110PIde Of Pol C .slec IV1 Za t ".0131te, On Cux'ves 77516 'OV180-33--i 07 J 01 C, c OVIde 9 x C U.Vve tz, V); (131 ei ee t.VO a Of Ca.rcl 0 1 t e 11., ' value 13rte elect 1 cm '4. Of 10 " - (A) -l'ojepost t on I me Of the -' ') el 6 -r (it, _1 , t 0 geometr. ec t;170_1 a Ode f ron rnpl~ Of the Cm Dote t-vue ,-Zcal te -Pface; t ce it ejec- 0 20C 21, 3 at ro, a t Table 1: Val.~L eqUation fol, a and b co,13tant SOV/80-33-1-25/4_q Re lon,~ c"lOr1de discharpr c In the T.-,f,,.l Of ej ej Y e,,, -,c t"03-Yte (DH - 2.9) Perature (In 0 rOlYte m- (2) cor J-n, 11-i anc, (3) 1 '; .1p,),, (,?I 111v); tric tion acid; (it) tern_ (7) b (j., meaSUreCl (In yplcm2); (6) a (3) -7 (141 (-5) (6) L 16) q- 25 Ni 15 20 a, 40 44.8 908 908 1 70 4z0 8US 112 0.26 2 50 Ni 67.8 724 100 0.31 15 20 Go., 102 40 0.33 70 60.4 876 108 3 91.4 766 0.27 00 696 96 0-32 too Ni 15 40 179.7 810 tal 0.33 70 205.0 722 100 099 4 00.0 98 - 25 p0 15 20 648 035 40 f 38.0 94 6.3 70 12-9.0 954 75 n 5 102.0 915 79 -.39 50 Fe 847 0.39 Card 3/9 15 132.0 82 0.31 70 l, 0.0 77 9 .889 0.38 100 Fe 15 20 4.0 &U 79 0.38 79.6 82 0.36 40 907 75 0.39 70 66.4 863 ~797 82 0.36 59.7 80 0.39  77516, soV/80-33-1-25/49 Table 2. Dependence of double layer capacity on the condi- tions of electrodeposition of Fe,Ni, and Fe-Ni alloys: (1) electrol te Nr (according to Tables 1 and ~); (2) y 0 temperature (in C); (3) capacity,(in ~U/cm-) of the double layer on the samples, obtained at the following I k (in amp/cm2). (1) (2) (3) 1 10~ 1 2,5- 10-1 1 1 - to- i.5 - to- 1 .10-1 2.5 - t0-1 10-1 1 2.5 -10-1 20 46.9 45A 44.2 . 45.3 49.6 70.4 90.0 1 70 - 68.4 67.8 67.2 67.7 68.0 71.4 98.0 4 40 - 09.4 119.2 122.4 121.3 127.0 t36.3 180.0 6 70 - 69.0 63A 60.6 59.3 59.6 60.5 73.0 7 20 - 44.0 41.7 40.4 40.4 40.0 41.0 49.7 9 70 - 49.0 40.0 36.2 34.4 34.2 34.3 34.9 Card 4/9  investigation of Polarization Curves in Chldrlde Electrolyte,,, as 2 3f af 4 3 ? 77516 SOV/80-33-1-25/49 13 Fig. 2. IV/log I curves in electrodeposition of Ni from chloride electrolytes, (A) and (B) are the same as in Fig. 1. Electrolyte Nr 3 at temperatures (in 00: (1, 11) 200; (2, 21) 400, (3, 31) 70". (1,2,3) at I on 1 crP of geometrical surface; (11, 2', 31) at I on 1 cm2 of the true surface. Card 5/9  lnvestij~alk.'Ion of Polarization Curves In Chloride Electrolytes Card 6/,,,,) 77516 0OV/80-3-,-1-25/49 J Fig. 3. Comparison of ~Vllog I curves for the individual components of the Fe-NI alloy in electrodeposition at 700. Electrolyte: (1) Nr 4; (2) 75 g/liter of Ni and 15 g/liter of citric acid, pH = 2.9; (3) Nr 7; (4) Nr 7 (partial polarization curve, corresponding to the iron precipitation); (5) the same for Ni. All curves at 1 on I cm of the true surface.  r--* rE] Card 7/9 -4 --cIr-ji la -es, -Li. FiEg. a I -:es are D-, Frc,m rl he data o~,-Iained, -,,-Ie ~;;ere made. The !,-rue --urvent dei-,,silrlli~s clat-, b~ caliculared by meas, -1rinz the capacitf-es of' Layers ~)r- the Fe, Ni, and Fe-Ni electrodes. The Phase in tne process of electrcdeTDc1,i',J;.cr-I :)r alicy from cvtiori.de electrol- cI a ,-a r~--e o f c u rren- de ns 1, t ite s a r--;i !-d~- pha s e .Th e a r, ex p r e s s 6-, s h, -41 sr au, J fo-,- hiS ccn~-iuc-l seri4es c.4~' ~x~erir,.,,ents in the Lab-crarocy of :~;l ~',je Lpnirlgrad, O.r,-IeL- ~)f Len-in, Sll-ave Uni-t,,&rs-l1-:!, -,r.ere 4 -,ables; 5 fi,clpures; a-id 15 refe r e n c. e sI f-," , S , I U , KI ~, S ~),l i e t The U S. anrd~ U.K. reCerences are-, E A --Ilar-d, ind. ~,LL, 1~5,2 M, K. Trans. Aw, ELecrrocn. Scc.,  i Er at "LO!', 0 1' PC, la r, i ~rl in Chlo.ride Electru 1 yte-- SOTT ASSOC IATI.Ol,j'; Sc n s e -3 ri T L I NF, u,,-. h. o',,, a t e Z SUBMITPTED: July I., Card 8//q  investigation of Polarization Curve3 in Chloride Electrolytes -17516 ISJOV/80-33-1-25/49 Table 3: Value of a and b constants in the Taffel equation for electrodeposition of'Fe-Ni alloys from chloride electro- lytes (~H = 2.9) : ~a)(electrolyte Nr; (b) electrolyte compo- sition in /liter ; c ) citric aced; kd) temperature (in OC); (eT C measured (in i~ F/cm (b) ( e) (d) ~,L(l,mv) b(14MV) (t Fe NI (c) , 20 40.6 793 ID8 0.27 7 25 75 15 j 4U 6-1.8 7:18 113 0.27 70 50.2 64 9 123 0.27 20 48.0 916 130 0.22 8 50 50 15 40 42.8 AM 132 0.21 70 48.0 728 f42 0.21 20 4:1.7 n1a 113 0.26 9 75 25 !,0 49.0 M 128 0,24 70 34.8 1 8 65 1 05 0.26 Card 9/9  S/080/62/035/011/003/011 D287/D307 AUTHORS: Sysoyeva, V.V., and Rotinyan, A.L. TITLE: The effect of chlorine ions on the kinetics of the cathodic deposition of an iron - nickel alloy PERIODICAL: Zhurnal prikladnoy-khimii, v. 35, no. 11p 1962t 2430 - 2435 TEXT: The present investigation was carried out because of the ab- sence of information regarding the effect of C11 ions on the kine- tics of cathodic deposition of an Fe-Ni alloy during gradual tran- sition from the sulphate to the chloride electrolyte. Sulphate, sulphate - chloride and chloride electrolytes, containing 1.06 mole NO and 0.19 mole Fe/1, viere used. The experiments were carried out in a 200 ml glass cell, in a water bath maintained at 250C. The PH of the solutions aas controlled with a glass electrode and main- tained at PH 3 (� 0.2). Total and partial polarization curves were plotted for each electrolyte. The alloys wert analyzed for their Fe-content and, if required, for the Ni-content (using Trilon B). It was found that the Fe-content in the alloy increased (under the Card 112  S/ORO/62/035/011/003/011 The effect of chlorine ions on D287/D307 given experimental conditions) with increasing Dc (cathodic current density) at low current densities; it reached a maximum and then started to (Jecrease slightly. On transition from the sulphate to the chloride electrolytes the layer arid) consequently, also the co- efficient of coarseness of the surface were found to increase. Sub- stitution of SO4 ions by C11 in the electrolyte resulted in a dis- placement of the total as well as of the partial polarization cur- ves of the Fe and Ni separation. The partial polarization curves viere used for calculating the adsorption potential which is obser- ved during the deposition of the alloy from the chloride electroly- te. The calculated value is in good agreement with literature data determined by other methods. There are 8 figures and 3 tables. ASSOCIATION: Kafedra elektrokhimii Leningradsko-go tekhnologiches- kogo instituta imeni Lensoveta (Department of Electro- chemistry of the Leningrad Technica.1 Institute imeni Lensovet) SUBMITTED: February 16, 1962 Card 212  3/080/62/035/012/004/012 D444/D307 AUTHORS: S gye . _v (-Y� _a,__V,V..__and Rotinyan, i~.L. TITLE: Depolarization and overpolarization effects in the formation of an Fe-Ni electrodeposited alloy PERIODICIM: Zhurnal prikladnoy khimii, v. 35, no. 12,.1962, 2653-2661 TEXT: The present investigation was devoted to the study of the mechanism of electrodeposition of iron-nickel alloys from sulphate electrolytes. Zlectrolysis was carried out under various conditions, the alloys produced being analyzed and polarization curves being obtained (both by the ordinary and the potentiostatic method). Mixed electrolytes- contained 1.25 moles (Fe2+ + lqi2+) pet__- liter. For a given electrolyte and temperature the potentialwas a linear function of the logarithm, of current.density. The slope of the line is given'by 1/cx : for the mixed deposition this is equal to the sum-of half the slopes for the separate depositions. With high nickel and very low iron concentration nickel is deposited Card 1/2  S/080/62/035/012/004/012 Depolarization and overpolarization ... D444/D307 preferentially: as iron concentration rises *,he polarization curves first merge a-Lid then reverse their position. With increasing tem- perature the partial- DOlarization curves of nickel and iron move in the direction of clcctro-positive potential; at 25-400Cj the movement is about equal, but on i-icreasing temperature to 700C the nickel curve moves more and the alloy is enriched in nickel. '--'or iron, depolarization occurs on discharge into the alloy, and this increases with rising tem- ')crature. -'For nickel, overpolarization occurs, but this )ractically disappears as the temperature rises to 700C. These-effects are associated tAth the alioy crystal-lat- tice structure and when two crystal lattices exist the values of overpolarization for nickel and depolarization for iron are indepen- dent of alloy composition. However, the effects cannot be fully e~cAaincd solely by the chancre in crystal-lattice structure depend- ing on alloy composition. There are 10 figures and 3 tables. ASSOCIATION: Wafedra clektrolchimii LTI im. Lensoveta (Department of -lectrochemistry of the LTI im. Lensovet) SUB11ITTEID: January 8, 19,62 Card 2/2 1  SYSOYEVA, V.V.,,,_ROTINYAN, A.L. Calculation of depolarization and superpolarization effects in the formation of a galvanic alloy. Dokl. AN SSSR 144 no.5: 1098-1099 Je 162, (MIRA 15:6) 1. Leningradskiy tekhnologicheskiy institut imeni, Lenosbveta. Predstavlano akademikom A.A.Grinbergm. (Alloys) (Polarization (Electricity))  ROTINYAN, A. L.; SYSOYEVA, V. V.- Cathodic polarizatitm in iron alectrodepoaition. Izv- vyd. ucheb. zav.,- khim. i khim. tekh. 5 no.5:782-787 162, (MIU 16: 1) 1. laningradskiy tekhnologicheskiy institut imeni ImnsO"U, kafedra elektrokhimii. (Iron plating) (Polarization(Electricity))  AYNX-M,J~; ROTWAN, A.L. Effect of chlorine ions on the kinetics of cathodic deposition of an iron-nickel alloy. Zhur.priklAjdm. 35 no.11:2430-2435 N 162. (KIRA 15:12) 1. Kafedra elektrokhimii Leningradskogo tekhnologicheskogo instituta imeni Lensoveta. (Iron-nickel alloys) (Electroplating) (Chlorine)  SYSOYEVA, V.V.; ROTINYAN, A.L. Effects of depolarization and superpolarization in the formation of Fe-Ni galvanic alloys. Zhur.prikl.khim. 35 no.12.-2653-2661 D 162. (MIRA 16:5) 1. Kafedra elektrokhimii Leningrads4ogo tekhnologicheskogo instituta imeni Lensoveta. (Iron-nickel alloys--Electric properties) (Polarization (Electricity))  ROTINYAN, A.L.; OVCHINNIKOVA, T.M.; SIMONOVAY M.V.; SYSOYEVA, V.V. Dependence of the degree of alkalization of the cathode electro- lyte layer on the current density. Zhur. fiz. khim. 38 no.12: 2966 D 164. (MIFA , 18:2) 1. Leningradskiy tekhnologicheskiy institut imeni Lensoveta.  GMIMIES, M.S.;__gPqKEVAe_V.V* MTect of a chlarlm anion on the kineticis of a cimataneous dischargo of iron and niolml* Zbwe prikL khim* 38 noo4s823- M8 AP #65. (MIRA 18s6)  PHASE I BOOK EXPLOITATIM 30~'4563 Metody poluchtnlya I lzmareniva radLoskUvnykh prlep&rat*v; abornlk statey imthods for the Production and 10.&Az=rtment of Radio- active PriparatlGn3; Collection of Articles ) Moscow, AtomltdAt. 1960. 307 P. Errata slip Inserted. 6,coo copies printed. General Ed. t Valerly Viklorovich Boahkarev, 3d. t N.A. Saguro; Tech. &d.j N.A. Vlasova. TURPOSIt This collection of articles Is Intends md for akcientific and tochnIcal personnel working In tne production of radioactive Iso- topes. .___,C0V3RAG3t The collection contains original studies on methods or obtaIning and measuring radioactive preparations. According to the rorewordth* articles contain law data, And are or thecr~~IVLI or practical Interest 10 the extent that they discuss methods or I --vey articles give process Informat on. In addition to sevcr&l*au. the collection contains discussions an the Production or radio- ftotiva pmparstlons, Including active Isotopes and Inorganic red a number of carrier-free Isotope n4 severe.' colloidal and other Also discussed arv methods for prepax~ 106 R number of tagged organic compounds, PrOblemn In the anal7- bla or tagged organic Compounds, the Absolute arid relitive measure- sent Of UtIvIty, end the radlometrio anclyals of prep1racloms. New instruments and e:rAlpment are described and ln3tr-uct.-on3 cc-,- earning ROasurement methods and technique &r, Included. 7.1. Levin, Candidate of Chazloal Sciences, V-P- Shishkov. Candidate of Tech- nical Scj*ncqX, 1.1j. Bukharc, Candidate of ajojor~j&l Sciences, and V.Z. Shostak, Candidate Of Chemical S121Ances, are mentioned - " having belppd directly in the 40140tiom and P-ePtratton of the Materlia ror publication; References accompany -Mch arzicle. TABIZ or CCXTEMS, -&W-qhat va,L.M., and 3.A. OroushIn. ProductIon or Iron Sulfide and Pjr;L_V-M'jd Vlth_T[i_dT&"tIv- Sulfur 43 "n' V.I., and N.O.'S-lebryakov. King PrOdu*tiOm Of C&rrier-Pree 53 Golutvina, N.M., or 3.di. chcoats aR_CT&btMZM-Chloride Swigged With Cr A_ 59 . , '7* 1., and M.X. Golutyina. Production of AST7 -dithout carrier Fr~ Neutron-Irradiated Germanium 64 *!Ayin. V-1., Ye.N. ?,jtrqjh- ai. ~Koi q1van and 0 7 K Production of Carrier-Frce p, . A 1101 "'Gv* 77 Senbrykor. and V?, parstlo~s Pjia_n:~ ProdJiticn ofCortain Pre- Bukh&mv. 1.11 1 *an I Methods ror Detecting Al=in= 1c=,L=Ies Tal-; a tu Sodium Phos;_Iiat. ti ted 95 !S9M2rXL_1--2~ Production of Carrier-Pree p32 100 *xorreva, L.s., and-jij, Morozova. Producticn of pe59 Ascorbina-e 107 and c ~uk. SY30yeva. Determination Of ?L Merauz-Z in TagZed With FgHfat nt Quslk*yp V.X. Preparation of S- &ndY - Radiation Sources 121 Vykhova, Z.1 Special Features of- the Production of Short-LIfe MadlOactlVo Isotope Preparations 127 L A Card 4/ 8  REVIS, I.A.; LEVINSON, A.M., MOROZIX, Ye.P.; Prinimali uchastiye: ZHUKOBDRSK--fY,, S,L.,, inzhq BAYEV, A.A.,, inzh.; SOLOMAKHIIJ, S.I., VESHCRV, Ye.V., tekhnik; SYSOYEVA, Ye.Ya., laborant Effec'u- of the technology of the manufacture of the disk knives for paper cutting on their strength. Bumagodel, mash. no.12: 17c';-;,-()6 164. (MIRA 17:11) 1. Leningradsk.-'~y tekhnologicheskiy institut tsellyulozno-bumazhnoy promyghlennostl- (for Zhukoborskly, Bayev, Solomakhin, Veshchev, Sysoyeva).  KOVALEVSKAYA, I.L.; EFSHTEYIT-LITVAK, R.V.; DMITRIYEVA-RAVIKOVIGH, Ye.M.; KURNOSOVA, N.A.; SHCHEGLOVA, Ye.S.; FERDINVID, Ya.14.; KHCMIK, S.R.; MAKHLINOVSKIY, L.P.; PETROVA, S.S.; GOLUBOVA, Ye.Ye.; GONCHAROVA, Z.I.; SAPd4AII=, A.P.; SIZINTSEVA, V.P.; Prinimali uchastiye: YIEDYUKHA, G.A.; OSOKINA, L.A.; RACHKOVSKAYA, Yu.K.; OSOVTSEVA, 0.1.; DEDUSENKO, A.I.; KOVALEVA., P.S.; KARASHEVICH, V.P.; CHEBOTAREVICII, N.D.; CHIGIRI, T.R.; SKULISKAYA, S.D.; KECHETZHIYEV, B.A.; DEMINA, A.S.; ZUSIMAN, R.T.; YESAKOV, P.I.; -~j~M,.Z.,A.,,-,,,ZINOVIYEVA, I.S.; FALICHEVSKAYA, A.A.; DENISOVA, B.D.; TDIOFE-LEVA, R.G.; SYRKASOVA, A.V.; LYMITSMAN, S. G. Reactivity and immunological and epidemiological effectiveness of alcoholic typhoid and paratyphoid fever vaccines in school children. Zhur. mikrobiol., epid. i immun. 33 no.7:72-77 Jl 162. (MIRA 17: 1) 1. Iz Moskovskogo, Rostovskogo, Omskogo institutov epidemio- logii i mikrobiologii, Stavropollskogo instituts. vaktsin i syvorotok i Ministerstva zdravookhraneniya RSFSR. 2. Rostovskiy institut epidemiologii i mikrobiologii (for Kovaleva). 3. Stavropollskiy institut vaktsin i syvorotok (for Sysoyeva). 4. Kuybyshevskiy institut epidemiologii i mikrobiologii (for Zinov'Yeva). 5. Saratovskaya gorodskays, sanitarno-epidemiolo- gicheskaya stantsiya (for Iyantsman).  1. SYSTAR, i. F. 2. Usf;R (600) 4. Poultry - Estonia 7. Practice of leading poultry raisers on collective farms of the Estonian S. S. R. Ptitsevodstvo no. 6, 1952. 9. Monthly List of Russian Accessions, Library of Congress, February 1953. Unclassified.  SYSTTEVAY A.F. [Sysuieva, A.?. iUrocc-r,-fLdTl,;, rucroor,--.--Lniq.,-to iri the wat.4-jr and "bottom .-cilii of during the fir.-,t, ye,.a- after iti fillirij,'. obiol. zhur. 25 no.2:10-35 '63. (1-1:111A 17: 10) 1. Institut -idrobioloi?ii ;V: UlcrS,3~-,'.  FAVORIN, N.N., kand. tekhn. nauk; POPOVA, K.L., kand. takhn.nauk; GONCHAROVA, N.Ya.; SYSUYEV. G.B.: ZVONKOV, V.V.I, otV. red.; GORSHKOV, G.B., red. izT--3i; NOVICHKOVA, N.D., tekhn. red.; MATYUKHINA, L.I., tekhn. red. (Brief survey of the research on the water resources of the U.S.S.R. performed in 1959 and 1960] Kratkii, obzor nauchnykh issledovanii Po vadnomu khozialstvu SSSR 1959-1960 gg. Mo- skva, 1963. 125 p. ~ (MIRA 16:7) 1. Akademiya nauk SSSR. Sovet po problemam. vodnogo khozyaystva. 2. Predsedatell Soveta po, problemam vodnogo khozyaystva AN SSSR chlen-korrespondetn AN SSSR (for Zvonkov). 3. Nauchnyye sotrud- niki Soveta po probemam vodnogo khozyaystya AN SSSR (for Favorin, Popova, Gonchar**,Sysuyev). (Water supply)  ISHCHUK., Yu,L,; SYSUYEV,, I.A,; LEONTOYEVA., L.S. Improvement of the technologi?al process for preparing lead stearate. Trudy BONMZ no.1:16~19 '63. (MMA 16:6) (Lead salts) (Stearic acid)  17 SOV/177-58-4-20/32 MaJor of the Medical Corps, Ivurin. If, T, AUTHORS: __�yqjjy I j Lieutenant-Colonel of the Medical Corps, and Osipov, S.S. TITLE: Some Problems of Protecting Divers From Radiant Tempera- ture Losses (Nekotoryye voprosy zashchity vodolazov ot luchistykh teplopoter2) PERIODICAL: Voyenno-meditsinskiy zhurnal, 1958, Nr 4, pp 67-71 (USSR) ABSTRACT: Based on tI)Edr own tests and those of N.K Wtt-e, A.Ye. Malysheva (1954), Letavet, Slonim, Margolina, Brandt (1949) and Professor Kondratlyev, the autho-sconcluded that: 1) the temperature losses during diving depend on the temperature difference of the skin surface and the surface of the diving suit and mostly result from radiation; 2) the usual diving underwear is permeable for human radiation in intensive temperature losses; 3) the aluminum-coated outer coats and overalls serve Card 112  SOV/177-58-11-20/32 Some Problems of Protecting Divers From Radiant Temperature Losses as reflecting screens, thus reducing the diver's temperature loss and preserving the temperature of the body and the skin on a higher level. There are 4 tables. Card 2/2  Snum, H. - ,-, :. ,.- ,I Let's take an active part in preparations for the sports tourna- menta of the peoples of the U.S.S.R. From.koop. no.12:52-55 D '55. (MLBA 9:5) (Athletics)  sysuy-zv, M. After the Spartakiada. Prom.koop. n0-10:34-35 0 156. (mTaA 9:11) 1. Starshiy inspektor Vsesoyuznogp Soveta obahchestva %"partak.w (Sports)  SYSUYEVI.,~ In the struggle for gold medals. Prom. koop. no. 11: 35 N '56. (Moscow--soccer) (MLEA 9:12)  SYSUYEV tL~ - -- ... Members of the Spartak Society at the sixteenth Olympic games. Prom. koop. no.1:36 Ja '5?. (nu loM (Melbourne--Olumpic games)  , -- - -, --- - -- ; ~ J - I . /I SYSUYEV, I.I. Gold medal of the champion. Prom.koop. no-11:38-39 N 157. (KIRA 10: 12) (Sports)  --- 3%DQM,-M- 4y " , ? Improve the work of physical culture groups. Prom. koop. w.5: 36-37 MY 158. (KM 11:4) 1. Starshiy inspektor V83soyuznogo soveta obshchestva "Spartak." (Fhyeical education and training)  SYSUYEV, M. n anticipation of the Second Spartaklad of the Peoples of the U-8964-44 Prom.koop. 12 no.11:38 N 158. (MIRA 11:11) 1. Starshiy inspektor Vseaoyuznogo soveta obahcheatva "Spartak." (sports)  - SYSUYNV ,---.-2 On all continents. Prom.koop. 14 no-708 Jl 160. (MIRA 1338) (Sports)  SYSUYEV ~. - DLUGACH, A. They lave sports. 14est.pran.i khud. promys. 2 no.1:38 Ja 161. (Physical education and Ivraining) (MIRA 14:4)  DLUGACH . A. ; S Y.1 U.'r.",, , 1 L'. Basis of good health. I-lest. prorr. i Ichud. promys. 2 no.6!39 je 61. (11RA 14:7) O'hysical c-.1,acaticn ard trairing)  SYSUYEV, V,, inzh. (Penzenskaya obl.); MIMITKO, V., inzh. po ratsionali- i izobretatellstvu (Zaporozhlye)j KRIVOSHEYEV, V.s, inzh. (Rharikov); KOSAREV, S.; SIDORKIN, G., mekhanik (Ashkhabad) Conceived and realized. Izobr. i rate. no.12:24-25 163. (MIRA 17:2) 1. Upravlyayushchiy trestom "GrazhdanstroT" Udmurtskogo soveta narodnogo khozyaystva (for Kosarev).  SYSUYEVO V.A.; PAVLOVICII, G.A.; GEliTSE14, P.P., kard.tokhn.nauk Preventing dust and poison gases by using water stemming in blasting operationa. Bor'ba, s Bil. 5:14.7-150 162. (MIRA 1675) l. Fermskiy nauchno-issledovatellskiy ugolInyy institut, (Blasting-Equipment and supplies) (Mine dusts-Prevention) (mine gases)  O'S IPOV ~Yu.A.--SYS-U---V-EV V.A.- KOLEVATOV, P.A.; MWIL',AROV, 0,';.; ENOK, V.P. DoBaymfW~. ~i Mining a seam subject to bumps using the method of water injection Into the seam. Ugol' 39 no.8:65-67 Ag 164. (HIRAI 17:10) 1. Permskiy nauchno-issledovatellskily ugollnyy insi-Itut (for Osipov, Sysuyev, Kolevatov). 2. Shaklita im. Kalinina kombinata Kizelugoll (for Zhandarov, Dobryrlin,. nitenok).  AUTHORS: Apayev, B. A., Sysuyev, Yu. A.. SOV/163 -58-2-38/46 TITLE: The Changes in:Ce..ntite Cau.-e-d-by Cold Pl..ti. Deformation (Izmeneniya v tsementite pod deystviyem kholodnoy plasticheskoy deformataii) PERIODICAL: Nauchnyye doklady vysshey shkoly. Metallurgiya, 1958, Nr 2, pp. 2o9 - 213 (USSR) ABSTRACT: The increase of magnetization in iron-carbon alloys at temperatures above 270*C as a result of the deformation and the increase of the a-solid solution quantity. The investigations were carried out with steel samples of the type 45 in hardened and annealed state. The increase of the magnetism may also be caused by the phase-~-Fe IC. The change of the magnetism in the steel samples 45 and U-10 was investigated as dependent an the degree of deformation. When comparing the curves plotted with one another a quantitative relation between the carbon of the steel and the amount of the-~ -Fe xC-phase formed was found. The course of the phase transformation in cementite Card 1/2 under the effect of cold deformation shows that it is  The Changes in Cementite Caused by Cold Plastic De- SOV/163-58-2-36/46 f ormat ion necessary to take into account this phenomenon when investigating the mechanical properties as well as the mechanism of the plastic deformation in hetero- geneous systems. There are 4 figures and 12 references, 6 of which are Soviet. ASSOCIATION: Issledovatellskiy fiziko-tekhnicheskiy institut Gorskovskogo gos.universiteta(Physico-Technica1 Research InstiTute of Gorlkiy State University) SUBMITTED: October 1, 1957 Card 2/2  67672 SOV/126-8-6-20/24 AUTHORS: Apayev, B.A. and Sysu_yev Yu TITLE: Influence of the Original Structure and Temperature of Deformation on Phase Transformations During Plastic Deformation U PERIODICAL:Fizika metallov i metallovedeniye, 1959, Vol 8, Nr 6, PP 915-921 (USSR) ABSTRACT: This paper is devoted to questions similar to those published earlier (Ref 11 and 12) and also to the study of the influence of the deformation temperature and original structure on the nature of phase transformations and harde ing dur ng deformation. The production types of steel U129and U101tere used as materials for investigation. Prior To-defor=ation,specimens of 4 x 40 mm cross section were subjected to a series of heat treatments, the conditions of which are indicated in Fig l,in order to obtain structures with different shapes of cementite. Deformation was carried out by universal non-uniform compression in rings (Ref 18). During deformation in a medium of liquid nitrogen, the specimens, compressed in the ring, were preliminarily cooled in nitrogen in a Dewar Card 1/5 flask. As soon as the nitrogen was off the boil, they were  67672 SOV/126-8-6-20/24 Influence of the Orij-jnal Structure and Temperature of Deformation on Phase Transformations During Plastic Deformation placed in a die accommodated in a retort which was also filled with nitrogen. The retort size was selected so that the specimei: should be covered by liquid nitrogen during deformation. Upsetting was carried out in a 60 ton Gagarin press. The degree of deformation %) was determined according to the change in length the specimen and was between 25 and 27%. The magnetic phase analysis method was chosen as the method of investigation. Determination of the phase composition was carried out according to magnetographs (curves Js(t) ), which were constructed with a ballistic magnetometer in a field of 10,000 oersted. The phase composition of the specimens after the above lip-at treatments is represented by magnetographs in Fig 1. In Fig 2 magnetographs of the same specimen after deformation at room temperature are illustrated. In order to prevent heating of the specimens in the second series of experiments, the deformation was carried out in liquid nitrogen. It has been found that the nature of the mechanism of deformation is preserved at a Card 2/5 temperature of -196*C (Fig 3). In Fig 4, magnetographs mv--~  67672 SOV/126-8-6-20/24 Influence of the Original Structure and Temperature of Deformation on Phase Transforma t ions During Plastic Deformation are shown of the original specimett and of specimesis which had been compressed by 46.6 and 86.85~"' (curves 2, 3 and 4). The magnotograph of the original normalized specimen is represetited by curve 1. The incroase in the total magnetization of the specimen and in the magnetization in the ferrite portion of the curve J,(t) (Fig 5) with increase in degree of deformation sho%%,s that an ever- increasing quantity of the cementite phase is taken into solution during transformation and that this transformation leads to an increase in the quantity of the a-phase. The curves 1, 2 and 3 in Fig 6 characterize the volume change of ferrite, cementite and '4-carbide, respectively, in relation to degree of deformation. In Fig 7 the change in hardness in relation to degree of deformation is illustrated for steel with granular and plate-like cementite. The work carried out shows that the more distinctly the plate-like shape of cementite is outlined, the more rapidly does its decomposition proceed with formation of X -carbide and a-iron. As the plate-like Card 3/5 form decreases, this process becomes less distinct and  67672 sov/126-8-6-20/24 Influenco of the Original Structure and Temperature of Deformation on F'hase Transformations During Plastic Deformation when the cementite acquires a granular shape, this process does not take place at all. In the light of these facts, 3-t must be assumed that steel which has been annealed so as to exhibit granular cementite is more stable than that annealed to give plate-like cementite. Lowering the deformation temperature does not change the general nature of transformation and the relationship with the structure. As long as the carbide phase 'XFe5cC forming differs in carbon content from cementite, there is a possibility of diffusion processes as the result of deformation at low temperatures. The mechanism of formation of this carbide is not understood. It originates either from austenite formed due to local heating or as the result of a crystallographic rearrangement of cementite under the action of stress. Gratitude is expressed to S.V.Vonsovskiy for his interest in the discussion of preliminary experimental results and for his offer to study the nature of phase transformations during deformation in liquid nitrogen. There are Card 4/5 7 figures and 21 references, 18 of which are Soviet,  67672 SOV/126-8-6-20/24 Influence of the Original Structure and Temperature of Deformation on Phase Transformations During Plastic Deformation 2 English and 1 Japanese. ASSOCIATION:Gorlkovskiy issledovatel'skiy fiziko-tekhnicheskiy institut (Gorlkiy Physico-Technical Research Institute) SUBMITTED: January 1, 1959 4--"- Card 5/5  82341 S/139/60/000/03/038/045 0 EO?g~f~32nd AUTHORS: Syquyev, Yu.A., Vasil'yevaj- Krasillnikova, M.A. - i for TITLE: Influence of lastic~Dgformatt~on Phase Transformations 7 JL I in Silicon aVdlNickel St=els I I I e1 _j V6 PERIODICAL: Izvestiya vysshikh uchebnykh zavedeniy, Fizika, 1960, No 3, pp 218 - $22 (USSR) ABSTRACT: In earlier work of one of the authors and his team (Refs 1-3) it was shown that in simple carbon steels the cementite decomposes during plastic deformation and a metastable carbide Y.Fe xC forms on the basis of the reaction: Fe3IP X Fe,C + m Fe It is obvious that in steel in which a new phase forms the change in the mechanical properties as a function of the degree of deformation differs from that of steel where there is no such transformation. In this paper, the authors attempt to elucidate the influence of plastic Cardl/3 deformation on the changes in the cementite of steels V  82341 S/139/60/000/03/038/045 Influence of Plastic Deformation on PRONAMsformations in Silicon and Nickel Steels alloyed with Si and Ni. The specimens studied were Ni and Si steels quenched from 1 150 0C and temp8red for two hours at 600 0C (silicon steel) and 650 C (nickel steel), respectively. The chemical analyses of the sevenEteels used in the experiments re given in a table, p 218. The phase transformationsfelunder the effect of plastic deformation were studied by means of a magnetic method. It was found that during plastic deformation steels alloyed with Si and Ni with an initial structure consisting of a + Fe3C phase transformations may take place. As a result of the deformation, the cementite betomes transformed into an intermediate carbide XFexC (the Curie point being 260-265 OC), which becomes unstable on heating above 400 OC and ceases to exist at 600 0C. Comparison of the processes of oA the exAmple of a Si steel after t1K deformation and queiA%A~W.g OMiAWW~ kh4 thtrs is Card '2/7~  APATIT, B.A.; STSMY, TU.A. Phase transformations during the necha-Mical testiAG Of ordinary carbon steel. Izv.vys.ucheb.ZBT.; Che=.Wt. n0-5:91-92 160. ()(IW 13:6) 1. Gorikovskiy issledovatellskiy fisiko-takhnicheskiy institut. (Steel-Meta-llography) (Phasee rale and eqailibrium)  AUTHORS: Sysulyev, TITLE: investi-gaUli-oh-af-the Crystal Structur PERIODICAL; Izvestiya 1960, No. S /l39/6o/ooo/oo5/O2VO3l E /073/E135 Yu.A., Apayev, B.A., and Balakina, L.M. Phase Composition and of the Fine of a Plastically Deformed Steel N vysshik uchebnykh zavedeniy, Fizika, 5, pp 148-152 TEXT: Since the nature of the transformations in the cementite phase depends on the shape of its particles, it was interesting to elucidate the character of the changes of the fine structure of the a-phase during plastic deformation of steel with cementite particles U " t of various shapes and to what extent the changes in the clmenui e affect the process of strengthening. Steel Y-10 (U 10), was chosen for the investigations after normalisation annealing-a-T 1000 00 and annealing to obtain granular cementite. Specimens of 12 mm dia.7 20 mm. in length, were deformed to various extents by means of a hydraulic press. To determine the phase composition of the steel after plastic deformation7 magnetometric investigations were carried out. From deformed templates specimens were cut (along the diameter) with a length to eross-section ratio equal or larger than 4. From the specimens magneto-rams Is,(t) were plotted by Card 1/4  S/139/60/000/005/025/031 E073/E135 Investigation of the Phase Composition and of the Fine Crystal Structure of a Plastically Deformed Steel circuit means of a ballistic magnetometer in fields of 10 000 Oe. For determining tho quan itative ratio of the phases the sections of the magnetograms of the phase components were extra olated to room temperature, using the approximation of Heisenberg Nef. 12). To detect the nature of the dependence of the stressed state and the crystal structure on the degree of deformation, X-ray measurements were made by means of iron radiation with an ion tube .~..fter removing the surface layer by etching. For the investigaticns the lines (220) of the a-phase and (222) of copper were used. Photometering of all the X-ray diffraction patterns was effected by means of a microphotometer with an amplification of 9 X. The results show that plastic deformation of steels with lamellar and granular cementite leads to differing results. The basic difference consists in the fact that phage transformations are caused in steel with_lamQll_a-r---c~emen�j-t-e)3whilst in the case of granular (:Fe_menti`~e this has not been observed, The character of the changes of the fine structure as a result of plastic deformation of steel U 10 in both states is qualitatively equal. Card 2/4  3/139/60/000/005/025/031 EO73/El35 Investigation of the Phase Composition and of the Fine Crystal Structure of a Plastically Deformed Steel A high level of type II distortions and the smaller size of blocks in the normalized steel can probably be explained by a change in the coherent bond between the a-phase and the cementite as a result of phase reconstruction in the latter. In a number of papers, the change in strength is attributed to changes in the fine structure of the phase components. On the example of single phase systems and satisfactorily annealed multiphase alloys, changes in type II stresses and in the size of blocks have indeed been found to determine the strengthening during plastic deformation (Refs 4, 16, 17). The experimental data given in the present paper indicate that this analogy also applies to steel with granular cementite. Since during deformation of such structures. the cementite phase is not subjected to any changes, the changes in hardness can only be due to the state of the a-phase. The higher hardness of the normalised steel both in the initial state and after plastic deformation can also be attributed to the difference in the fine structure. The change in the fine structure is similar for both states of the steel; Card 3/4  S11391601000100510251031 E073/El35 Investigation of the Phase Composition and of the Fine Crystal Structure of a Plastically Deformed Steel however, the character of the strengthening differs. This indicates that the changes in the fine structure of the a-phase do not reflect the law of strengthening during plastic deformation of steel with lamellar cementite. There are 5 figures and 17 references: 11 Soviets 5 English and 1 Japanese. ~'3SOCIATION: Issledovatel'skiy fiziko-tekhnicheskiy institut Gorlkovskogo gosuniversiteta imeni N.I. Lobachevskogo (Physics and Engineering Research Institute, ty Imeni- A.I. LobacRevsx1y) SUBMITTED: December 19, 1959 Card LF/4  s/148/6o/ooo/m/oli/M A161/AO30 AUTHORS: Sysuyev, Yu.A.; Myasnikov, V.G. TITLE: Stability of Austenite in Steel Which Has Been Heated After Deforma- tion PERIODICAL: Izvestiya vysshikh uchebnykh zavedeniy. Chernaya metallurgiya, 1960, No. 10, pp. 122 - 125 TEXT: The purpose of the subject investigation was to find the decomposi- tion temperature of residual austenite in Cr and Mn containing steel after defor- mation. Two steel grades were studied: Y8 (Kh8), with 0.98% C and 7.26% Cr, and r5 (05) with 0.86% C and 4.73% Mn. Billets of 4 mm diameter were worked in 100% austenite, ground to powder, and screened, , portions of 3-5 g powder were pressed into a pipe from molybdenum glass; titanium was put into the tube to prevent oxidation, and an asbestos plug between titanium and the steel sample. Air was evacuated from the pipe, and the end sealed. Decomposition of initial austenite in both grades started at 5600C. Magnetic measurements proved that the quantity of residual austenite was about 50%. The behavior of the initial and deformed austenite in heating was different: non-deformed and hardened austenite Card 1/5  s/148/6o/ooO/olo/oll/oi8 A161/A03O Stability of Austenite in Steel Which Has Been Heated After Deformation decomposed at tP-5500, and the deformed austenite transformed in two separate temperature ranges, 175 - 2800C and at '>5000C. Decreased heat resistance of residual austenite after deformation appears to be caused by redistribution of the alloying elements in the metal under the effect of applied and residual stresses with the formation of austenite with varying composition. The redistri-V bution in chromium and manganese steel was different despite identizal deforma- tion. Chromium steel contained two austenite kinds: high-alloyed austenite Sim- ilar to austenite before deformation, and low-alloyed of the type forming in plain carbon steel and decomposing at the 200 - 2800C range. Austenite in man- ganese steel seems to have a gradually changing composition and decomposes in a wide temperature range between 200 and 6500. There are 4 figures and 6 Soviet references. ASSOCIATION: Gortkovskiy issledovatel'skiy fiziko-tekhnicheskiy institut (Gor'- kiy Physics and Technics Research Institute) SUBMITTED: November 5, 1959 Card 2,/5  Card~ 3/5 S/148/60/000/010/011/018 A161Ao3o Stability of Austenite in Steel Which Has Been Heated After Deformation Figure 1: Curves of austenite decomposition in hardened samplebeing heated. I.- Kh8 steel; 2 G5 steel. 2  S/148/6o/ooo/o1o/b1i/o18 A16i/Ao3o Stability of Austenite 6b in Steel Which Has Been AV, .20 Heated After Deformation Me 170 :Figure 3: Curves illus- t t it d NO --7 ecom- rating sus en e position In deformed Z70 .2.V Kh8; b samples. a G5 steel. 1 the sam- ple; 2 - the reference.: specimen Zia . k lev 2w 300 wo M f ix 2w m 4 w wo we r - Card 4/5  - --- --- S/148/60/000/016/011/018 A161/AO30 Xo Stability of Austenite in Steel Which Has Been Heated After Deformation 2. v Figure 4: Variations of - magnetization in heating and cooling. a. - Kh8; 275 b 05. 240 t 220 - 230 220 - 255 210 - 145 - 0 o 235 - 205 195 Z15 195 /go ZOL7 309 t. 9 too-, 2w _jao mot: Card 5/5  S/126/60/010/005/021/030 EnVE452 AUTHORS: Apayev. B.A. and SysuYev, Yu.A. TITLE: Influence of Pla;_t_i_c-D-eYF`r_mation on Changes in the Phase Composition of Steels Alloyed with Cr and Mn 196o, V01.109 .5, PERIODICAL: Fizika metallov i metallovedeniye, No pp-767-?71 TEXT: The authors have previously shown (Ref.1,2) that plastic deformation of carbon steels produces transformation of the cementite phase. The object of the present work was to find the results of plastic deformat on of alloyed cementite. Types W X15 (ShKhl5)\gand lOrl2 UOG12)~f'(1.01% C and 1.11% Mn) steel were used. After suitable heat treatment to give the required alloying of cementite, blanks were rolled on a laboratory mill and made into test pieces 2.4 ~~ 0.01 mm in diameter and 36 :~ 0.1 mm long. Saturation magnetization was measured in a field of 10000 Oersted at temperatures up to 3500C: results for SbKhl5 and IOG12 are plotted in the left hand graphs in Fig.1 and 2 respectively for the landeformed, heat treated state; the corresponding plots for the deformed steels being shown in the right-hand graphs. The work shows that plastic deformation of tempered steel alloyed with Card 1/3  S/126/60/010/005/021/030 Elll/E452 Influence of Plastic Deformation on Changes in the Phase Composition of Steels Alloyed with Cr and Mn chromium and manganese leads to phase-composition changes depending on the initial structure. If this consists of unalloyed cementite and alpha phase the phase change is similar to that in carbon steels (Ref.2): deformation produces redistribution of iron and carbon, giving a new iron carbide. Deformation of alloyed cementite leads to redistribution of chromium and manganese within the cementite phase. Deformation of structures formed by tempering in the narrow temperature range corresponding to initial stages of alloying, or after prolonged tempering at 650*C, does not produce phase composition changes. From Apayev's previous work (Ref.8) the authors conclude that the alloying- element redistribution phase takes place in two stages, this providing an explanation for the different deformation effects obtained. Cementite grain shape can not be a factor. There are 2 figures and 8 references: 7 Soviet and I Non-Soviet. Card 2/3  S/126/60/010/005/021/030 E11l/E452 Influence of Plastic Deformation on Changes in the Phase Composition of Steels Alloyed with Cr and Mn ASSOCIATION: Gorlkovskiy issledovatellskiy fiziko-tekhnicheskiy institut (Gor9kiy Physical-Technical Research Institute)- SIBMITTED: December 17, 1959 Card 3/3  S/l26/6o/olo/oo6/oi8/o22 E111/E452 AUTHOR: -&ys.qy,#v Yu.A. TITLE: Tempering Deformed Steels Alloyed With Cr and Mn PERIODICAL: Fizika metallov i metallovedeniye, 1960, Vol,10, No.6, pp-907-911 TEXT: This is a continuation of the author's previous work (with B.A.Apayev, Ref.1) which showed that deformation of steels alloyed with Cr and Mn can produce changes in the cementite phase. The object of the present work was to find how such deformed structures change on heating;24% deformed specimens of type 10 r12 (10G12) steel (1.01% C, 1.11% Mn) and WX15 (ShKhl5) steel were tempered at 300 to 650- 700"C at 25 to 50"C intervals, After each tempering, curves of saturation magnetization vs temperatures were taken in a field of 10000 oerstedi on some specimens coercive force and hardness measurements were also made, Fig.1, 2 and 3 show the magnetic curves, the left hand graphs relating to type 10G12 and the right hand to type ShKhl5 steels (Fig.2 relates only to the former), Curves 1 and 2 relate to hardened and tempered specimens before and after deformation respectively, the others to specimens tempered for 30 min after deformation (increasing curve numbers relate to Card 1/3  s/126/6o/olo/006/018/022 Elll/E452 Tempering Deformed Steels Alloyed With Cr and Mn increasing tempering temperatures). In Fig.4, coercive force is shown as a function of tempering temperature for IOG12 steel for, a struc ture def ormed af ter hardening and temper ing at 420 OC f or 1 hour (Curve 1) and for that obtained by deformation after hardening and tempering at 650'C for 7 hours (curve 2), Curve I has a minimum at about 400 and a maximum at about 5500C; Curve 2 falls continuously with increasing temperature. In Fig.5. giving hardness as a function of tempering temperature, Curves I to 4 relate to deformation after hardening and tempering for 1 hour at 420, 475, 575 and 6500C (7 hours) respectively~ The author concludes that deformation produces several pe~:uliaritiea in the behaviour of the cementite phase when the steels studied are heated. Changes in cementite depend to a considerable extent on the initial structure of the steel and sometimes on the nature of the alloying element. In the temperature range of these changes breakdown of blocks of the alpha-phase mosaic oLcurs, reducing loss of hardness up to about 550 to 600*C. There are 5 figures and 8 references: 7 Soviet and I non-Soviet, Card 2/3  S/126/6o/olo/006/oi8/022 EIII/E452 Tempering Deformed Steals Alloyed With Cr and ?,fn ASSOCIATION: Gorlkovskly issledovatel~skiy fiziko-tekhnichoskly inntitut (Gor'kiy Physicotechnical Research Institute) SUBMITTED.~ March 23, 1960 Card 3/3  S/148/61/000/012/007/009 E193/E383 AUTHORS Apaye-, B.A., Sysuyev.--Yu~J~ and Balakina. L.Mf, TITLE,, The effect of carbide transformations on the variation of structure and properties of cold-worked and hardened carbon stools during tempering PERIODICAL: Izvostiya vysshikh uchebnykh zavedeniy, Clhernaya metallurgiya,. no. 12, 1961, 117 - 124 TEXT~ Other workers (Ref. 1: V.K. Babich, K~F.Starodubov - IVUZ, Chernaya metallurgiya, 1958, no-2; Ref. 2- A.P.Gulyayev,. -N.-T.. Burova - MetallovederAye i obrabotha metallov, no. 1. 1955) i-.Fho have studied changes occurr-ing during tempering of steel at temperatures above 300 OC have found that similar c'langes take place in both cold-worked and hardened specimens, Starting from the assumption that pl7stic deformation does not bring about any phase transformations, ~'-hese workers concluded that the changes observed during tempering could not be caused by transformation of the carbide phases, Results of more recent studies of this Problem (Ref. 3: B.A. Apayev, F101, v.4, no.2, 1957; Ref. 4: B.A. Apayev, Yu.A. Sysuyev - Nauchnyye doklady vysshey slik-oly, Card 111(d - ----- i  T;10 of roc t of El 9--/E A 383 Metallurgiya: no. 2, 1958: Ref. 5~ B.A~ Apavey, M1, v.8, rio.6, 1959) indicate, however, that this conclusion as not quite correct. It has been found that plastic deformation of steel with lamellar 'cementite is accompanied by the formation of carbide Fe C and by an increase in the proportion of the X 2 a-phase; as the proportion of lamellar cementite decreases, the plastic deformation-induced transformation diminishes and ceases cod-ripletely when granular cementite only is present in a given steel- The behaviour of cold-worked steel during tempering should therefore depend on the form of cementite it contains and the object of the present investigation was to check the validity of this postulate. The experiments were carried out on specimens of Steol 'Y1O (U10). annealed under conditions which ensured the formation of granular cementite, normalized (i.e. containing lamellar cementite) and hardened. The annealed and normalized specimens were cold-w-orked (by forging and dra;-,ring) after which both the cold-worked and hardened (quenched) specimens were t;e:.i,,)ered for 30 i-An at Progressively higher temperatures in the C,ard 2/d V  The effect of .... E193/E383 300 - 700 OC ranged After each tempering operation, the constitution of the specimen was determined by a =a.-neto=etric was measured to provide method. its coercive force H c j.jjf'(jr-jjjjjt, i oil on tlin changes in the state of stress, the size of klocl-i in Llio a--pliaijo gr;%iwi waa determined and the Rocki.;-ell 'lardness I f.AWl-t ;OtICJ~MVK~d- TIo ro-r-sulAil C;wn be :iu;,1,aarjzed as 0 tie a.5 follows. No change in tjj~j, dtir.Lng- tomp i-i , w observed in cold-worked specimens of steel g_ c em Cut i t e. In contrast , the cons(itution of cold-worked z;tud. containing laniellar cementite clianged during tempering in a manlar -,r simi3w to that observed in hardened specimens,. This is dei-,ionstrated by the results presented in Fig. 1, wheve the Proportioii (pv, of the a-phase (Curves 1), cementite (Curves 2) and )Ccarbide (Curves 3) is plotted against the teinpering temperature ( 0C), Curves a and 9 relating, respectively. to plastically-deformed (500,") reduction) and hardened steel The temperature range at which the transformation 0 of the V carbide took place during temperin,- of cold-wor-I:ed Ca r d 3  s/148/61/000/012/007/009 T: i e efL"ce t of E193/E383 steel (wit'i lamellar cenentite) depended on tile degree of preliaiinary deformation, being shifted towards the lower temperatures in heavily deformed material. The -variation of other properties is illustrated in Fig. 3, where the coercive force (if cl erg - graph a) and hardness (R A- graph G') are I-lotted a.-aiiist the tempering temreratire ( 0C). Curves 1-3 0 IL relatiliml., respectively, to hardened specimens, cold-worked steel i.-ith laic iellar cemezitite a-rid cold--worked specimens of steel with ~~rziliular ce!-,Ientite~ The results described above confirmed t1ie finding's reported in Ref. I on the similar nature of changes occur~-in,- durin. azri-nealin- in the properties of hardened and k o ~-tr;f-l -,--r)tIi lamellar ce"entize and that t-is irhj~ji tie cold-rorkc-d specimens contai-ned I I a ? C f:~z t e:- 31-anuivr cem,011tite !n th,!! zirilli~ IfAyi affected the changes in the wIdtli 13 j f ij,afractic.,zi of the a-phase. as illustrated in Fig. 4, wliere W=0 12~ plotted against the tempering temperaTure (OC)~ Curves I and rospectively, to deforried specimens of steel cemolltite~ On t1he Liand neit.-ier the Card 4/f  /007/0~~q S/i48/61/000/012 The effect of .... E193/E383 Variation ill the X-ray diffraction-lines width of t'.,ie nor the 11C curve (Fig. 3a) obtained for z',e cold, specimens of steel with granular cementite resembled those obtained for hardened specimens. The cause of these differences and similarities becomes clear if the ter-,iperinZ-induced changes in the constitution of cold-%-.-orked and hardened specimens are compared. As can be seen in Figs 1, 3a and 4, anomalous variation in the coercive force and the X-ray diffraction-lines -i%ridth takes place in th6 same temperature range in which the 4-carbide undergoes a transformation. In cold-worked steel with granular cementite in which no pliase-transformatioii occurs. no anomalies in the variation of these two prop ert i es is-ere observed. Consequently, the changes in the fine structure which GCcur during tempering at temperatures above 3 0 0 and which cause anomalous variation of H and B in hardened and cold-worked 0 steel with lamellar ce,~-.ientite are associated with the Card 5/f