SCIENTIFIC ABSTRACT GOLUBEV, A.A. (LENINGRAD) - GOLUBEV, A.I.

GOLUBAV, A.A..(Ieningred) , Peculiar relationship between concentrations of some vk6latile substances in the air and the development of emplqsema, Gig,truda I prof,,xab. no.4.-46-50 Jl-Ag '57, (KIRA 10;11) le Institut gigiyeny truda t rofzabolevaniy. (MWUKA, FUIXOUYI (AIR-POLLUTION)  GOLUBEV.A. A,; LYUBLINA, Ye. I. (Leningrad) Calculation method for establishing approximately the maximum permissible concentration of organic aubstances in the atmosphere of industrial premises. Gig. truds. i prof. zab. no-4:26-32 162. (MIRA 15:4) 1. Institut gigiyeny truda i profzabolovaniy. I (INDUSTRIAL TOXICOLOGY)  LrUBLINA, Ye.I.; GOLUBEV, A.A. Use of the method of correlative groups of isotopes for discavering'the relation between the physicochemical properties of substanceq and their toxicity. Prim. mat. metod. v biol. no.2:90-93 163. (MIRA 16:11)  T JU 1', T 'I IY- F. I. and COLP 'T,*'. A.A. 4,ew lati on thn pcssi b~l 15, ty of Calculatin , Ten im G's I'le cS c,:v~jc SuIrsUnces." .,.epc.rt ores nted at the 2nd All-Uni-on Scientific Conrcrcm~:c on the 11 r-ne aml oxicolovy of :.IiA_-ztry cf i!i~,Ath USST4 C(j:,lriJttee - 1~ u On thc --tud"Y' Ind c,flcwPlo.-,oncu.,3 Gberd.calz of the, .:ain St~~tc r ,Janitax~,,r ingrection U-"',JP and Kiev Institutc cif Lal~or lily.lelle and cccupa- tional Diseases, Kiev IY-19 C;ct. 1962. (riiglyena i Sanitariya, No. 32. 1963' P. 1014-105.) Kiev institute ef Labor Hygiene and 'l,ccupational Diseases.  ACC N" AR6035077 SOURCE CODE: UR/0169/66/0001008/GO06/GO06 AUTHOR: Zhdanov, V. V. - Golube A. A. - 8~ __ Yj___ - TITLE : Petrophysical investigations related to the deep-seated structure of the Earth's crust SOURCE: Ref. zh. Geofizika, Abs.. 8G37 REP SOURCE: Sb. Materialy k Soveshchaniyu Obshchiye z"Onomern. geol. yavleniy. 1966. Vyp. I. L. , 1965, 331-335 TOPIC TAGS: earth crust, parameter, magnetite, petrophysical research ABSTRACT: Petrophysical research includes study of physical properties of rocla and determination of a correlation dependency between physical parameters and the conditions of formation of magnetic and metamorphic rock. Direct dependences have been determined between the density and the basicity of igneous rocks, between the degree of magnetism and the magnetic content of the rock, and so on. This indicates great possibiEties for petrophysical investigations durif study of the deep-seated structure of the Earth's crust. [Translation of abstract] SUB CODE: 08, 20 rd  I I I Is It Q 11 $4 4 Is 11 Is It a it a 6 is a Ita a 4, u 41 a a r 0 it - so C - S -4--S A- a a 0 0 :1 , - W -00 t so so me'Md at dtft-twAg am humlank addity of CrUde nitro Products. I M -00 go 2' KARTARM AND J. Chm, Ind. (Russial 6, 1-,1) 11 l,,r2!1) The rMth',d -00 k haved an the "I t MS. FOrms with IIAO. a ~Ulfatr which.,m 1wing,li-4-ni in .44 1xiding water. can be titrated with ().1 V &IWi in prrmncr L4 phjullpht . it ~ ;.m h4h I ckmt aniline is rvWW with stiffing Into hemeove or Wwwr to Mcd all the :: then the ppt. Is filtm-d' washeil with C4114 or littO and transferred together with the fitter Into 4 beaker. when It Is di"Wvtd in boding 1110 and titrated after sthmt Imiding 0 a t0cemil"iPetrilt"CIMMOrMUO, Crude Is dilmilvird in C,114 and the mutily of andine Is introduced with rapid stirring, after which the ppt 0 nI "Anu"laye =ate is titraled as abnve. Nxilrobrazent and damilroMfuear are shritrtly 00 dimilvird In aniline on hehv bcatM cart a water both, and aniliur AuffAte. which plit,%. is filt"m and film". N'IKLN,.-4 49 0 zoo :'90 ~*Oog ago o10 see * 0 so j -00 60 so 0 a s S L -ITALLOGICAL LIMAIL'Al UAtSIFKA110k 1131, 111.0. ve* '1-41 ~" - .1 It 1 4-1 0-1 1,11jist tabs a 41 3 1 a I 43 o"'. it to of It is Ot in It m hito 11 t 11% .13 &;.Y" 0 0 0 0 0 0 0 0 0 0 0 0 C 0 a 0 to 0 0 0 0 0 * e 0 0 0 a 0 0 0 Wo 0 0 0 0 9 0 0 0 0 0 0 0 0  so I I AA-C 4 A, j 00 1:' sea. 00,1' oo~ 001 00 I a 1 0 1 0 ho 11 u W tj Is it Ill if a ill u a h is h 0 a it a q r- 9 a., L. I U A-D Jb CODINS *c #nIs ..Do.- Ou u it U M A Ill 1) a At a 41 a 6j a 4'e k. A -4-.r ..0 if. "et, -00 Red 01-ndoft IOMW bms. W V. J. (U.8.& R.) 10,30t-11011113).-A stuft;Wthe #"11. mbber sdvnu and the efect of the - pa. vubber =-reelstanive to gerening. w2u. contg. diffirmt Ingledlents wM Immersed In bilazine (For 24 h".) and to luixicating ous (fur 48 hri.); the extent fit sirttliffe was dotd. and rapiesm, an The I f'sin to wt. IU ingtvdirvis tee I.MMAW. ANCIL. "Maillop- black kiwis z"O C*O, Macmu sigo. Chalk. utbopow"tak. Ozid eAh' a. bw. that# 22", mpkits. animal glue, etc. -.10 mufti or tb- == In 48 diagmm; mW obvie, that to PIMP. M Illar Olixte. the a d"XIM %:7th.tb=II *101M, biwk Se t =0 Weirit.. OM r!OZ N elictuent latswifil cwth and bwo dtut am of no ]IIImell solvel -0: .00 '00 .00 11414111 "046 too WIF 0 of '00 tie* u a 1, '0 it T M W 1 it is 'j is a 2 1 v It 0 0 4 IS 0 0144 0 00 0 00 *0 0 40`1 0 0 0 o 0 0 0 0 0 0 0 0 0 o 0 q 0 4 0 0 0  00 ** 00 A 00 09 it 5 i d X A k K 0 w & N ""s " s an . 4*uaw . a p - of 4 Cbm. IML SOM0147. W ' oo at CA in VqWd ak w Oj is do* So spatmba" of 1 aw ak cw to ume a(viswuhle lubrkma(A in Uw 00,1 00 .3 rnmpmm'oa UAL H. T. 060 06 00 00 JUL "r tow %I. A. - -- -- -.T- V- rI-V'r- 1 v u 0 1, '0 4" 1 1 w 4 pw 0 i i ~j 0 a 0 0 t, a a 0 -*O-oo 0 00- s ~ 000 see* o*oo****6oll* 009000000 4006 * 0 0 0 0 *-*A-O 0 0 0 10 0 9-0-0 0 0 0 0 0 *a * 9 0 0 4 0 0 o 00000 .0-0 .40 -09 -00 goo too coo goo We 0 gas see to 0  1 -1 4 it a it M A 1 go 00 X Mamg* a wtion of 64 otalft "wt ad it tatak fWad" in tbQ--atbotr*Pk". A.A.41.1olsib",A.A.Tyatu. We. STO L It. 1,yukin. N#11-Owyo i Keram. 11tom, 19", No 7 'd Cerawo. Alweddis i4o, till (in J, j w. I oil, j -k-; - 39, NIL 6) - - 11w tim, of wrvk* 4 a lank I fwuam Is dwtd. nmtly by the wcw of the main vvull. go- fWInIjilY *two the vault requimtepair the furnacv #nLut 00 be -0 -EAed befoev it ma be repairril. At ilia R OTALLWGCAL WIN&TWIl CILAWWAY44 It 100'14~ "It a.. a" 4 -_ t--;l--1r 4-1.. 1-111-1 U IS At WD is o"11,111004 omits' '401" it$ 016 -6 0 0 0 0 0 0 0 0 0.0 0-0 0 0 0 4 Oteas, eass pkat, for the Aral thnc, a we 41 The vowU "as complettly verANced withOtit MOWS# tht 6RU00- so That It th of the furil4kv is 27 in. anti tho Width of 10 TIM .00 - 1. tKITd. fourlh~ and filth imirs -4 hW%M 0 tWVA4 00. .00 The tetup. 01 lite futlacr 411111590411 to 701' to NO*- TOO .00 aftlies at the fourth pair of boners wM Uthest dws. 4a air wav, suppil"t therethinugh into t1se fonows lis cad ths -11144. Meanwhile. the temp. Is the F"Wnak cbumw .046 the IIIIIIAM WAS V-01111, prop"S. wel Mfift Owc bomiW4 k W40 ADM l1 % h 4*y Wor e PvvtwLra t thruttyawtion. When ti as W the #i"% dcvrvowd to W, the da and the temp 40*0 . I Section *04 collap"ll dirwtly cato Ilit glaw At mo* time the 114" hot C'""l to Stick extent that the dr-PPIP4 4110411 briek &I not ittivic to it. Asbettiva Sheets w1re then W- wriod to fv"c* t4 the I hint armt fifth smikas. T - UICOMP. IV W 0#0 in the aff-A no ilia VWLAI)A%l wvSkwd"olied to I t i t t ft d I h . * bris "A o rvusi e wi on " n o t pmoltiM rojity clean it out. Mcbmkiing the new fourth wVA*m e w4vilinnilk 600 Xbro. Dusins this tint* the temp. at the &It and 9*0 pair 4 burners wws kept at M)' wO at The sixth wW iwvrnllv 1wir at MWP. The teInp. Its the rescoarstars twas 000 :ke furalraml."), fort", lbAillukimp"It" nuslQUIl In OW Wasift re was ass tlEr thmusbaut ark ~ %%m the rebuililitil of the 1wath 49e Section WAS finisw the ttmp~ underneath it was abmt k1railuitily the temp. of the f*bWlt Section was f th r 1 Ow fwlhw i I l li d h t t i h sr, at w o e. aw t a o es 4 ra tilwa t 1 The 01111ft fuln"V WAS thell rvhmtgd by "alliq the I , 7; to 1 .1) to IKW at a rate of IW per hr., am Iran Ow pt 201 W hr. Tim vvimmiting of the twusce am 00 plix)tcd in W by. The entive Work took 6 &P. 1110 details tit the work are dc"he& M. JP. R. ~ - 11111111 me" Ali - Ai to two 0 v 'tir"ji 0#3-0 vi- _ as 6 6 0 0 0 a 46 0 a a 0 a 0 0 0  A A 1 4, T 11 11 It to to 16 to 's 'I&' it is Pl-1 it it to u u is h L_X A _J_ IL 1. S, A Q '01. 1- I__1L_d v A a of 41 to a d to 00 A 0 L 0 E oe 00 .00 * 040 ir :: t 1"m I"* to In" brisces and rearedalt gualsels. _00 00 2i. At AA 1). 1. P(MIMMLOY. Mello i Nera m.. 3 I_M=ipold repair of tank Imam has been *00 .00 ~ 00 ate In befinvirt Vnion since i l b h k x== 100 00 A ca etween t T e wv * per Pr e0 culol mpairs can to raind to M) to 33 moriths, uIth two 100 winkolool and two w thm Lot repairs being toutile during - s the f tin i f ki M hi I k woo so ret r &a n ista v g o t ng om Irpa s P` Into I= a milon of Ow tank turimin &a d1iormlinued toy coo 00 arsted front the d thbeectim km thelo o i 00 com urmem o ng p undamaged wolo" by mftm of an "besilloo ah"s whirit k QVo erst re In the %ectloot The troto U "vered into thor furasce S 00 Ll 1 . . p to be ".1red drops rapidly to 30, to fit)*, which It talk. r-O 0 00. facturyfcirworking. MmkvM repAks art purlicuWlyad. d i h FO 0 00 a 0 Z, r t t gas an vantalms when it is mat necessary to repa stooks pawAges. air and gas valves, hottoon of the tank furnme. wood bridge striwtures In the Foutcault Channel goo too W With them It Is necessary to stop the gat Completely and Ze 0 2 , the fu7nace stood Fourcault channel for cold repaim vto p W=01 Ing Up after repairs with- out H Z.K. .00 too A W a I L A 1191AWACKAL tITERATUSI CLAIS&FKA1008o boo It: WOO U IS Al 10 At i 4 OR a 11 to OF it It Is 14 a It It it it 0 ka A 1 14 a, 0 0 0 0 04 0"6060 of ooooo:ooooooo*OOOOIOOooeogoooooo 0000001000000 000000000000100000000000090*69 of  GOLUBEVI Aq LEONOV., K. Methods ofspeedy repair of glass tank furnaces. Tr. from the Russian. p. 203 Vol. 6, no* 9, Sept, 1955 SZKLO I CMWLEKA Warszawa SO; Monthly List of East European Accessions (EUL), LC,Vol. 5, no. 3 March 1956  GOIUBbYO,A,A.; LHONOV. 1.7. There should be an impovement In the design of tank furnace throsts. Stek I ker. 12 no*11:10-.15 N 135- Oan 9: A) 1.89yuxoteklostroy, (Glass sianuf mature) (ftrnaaes)  o6214 50) SOY/64"*59-6-6/28 AUT1LQRSt Zabotin, K. P., Morozov, L. As,.Kryukov, I. Y., Frantinakiy, A. A., Golubev, A. A. TITLEs Continuous Method of the Copolymerization of Batyl larylate With Acrylonitrile in Emulsions PERIODICALt Khimicheskaya promyshlennost', 1959, Nr.6, PP 406 .- 487 (USSR) ABSTRJkCTs The product obtained by the copolymerizatio'n'..m'epticned in the title is used in the manufacture of artificial leather, in etc. Pablications mention a sewi-continuous leather dyein , method (Re- or this polymerization. Here, a continuous f 5 method is described, which ban already been proposed for the copolymerization 1~of divinyl with styrene (Ref 2). From the scheme given (?ig ) it'is seen that a tube reactor is used. The following composition in parts by weight is used as reaction mixture: butyl acrylate: 54, "sulfonol" (emulsifier)t 2,ammonium persulfate (as initiator)s 0.10 acrylonitrilei 16, water: 100. The reaction mixture was introduced into the reactor at a rate of 1.2 1/h and 1.8 1/h respectively, and the oopolymeriza- Card 1/2 tion was carried out at approximately 80 . In order to prevent  GOLUB j A.A*,L red.; OVOD~ M.Ye.9 red.; BORISOV, B.L.# tekhn. red. Nanual on the construction and repair of tank and pot glass Au-naces] Rukovodstvo po stroitel'stvu i remontam steklova- renrqkh, vannykh i gorshkovykh pechei. Pod red. A.A.Golubeva. Fioskvap 1zd. PKB GISteklal 1960. " p. (KIRA 15: 1) 1. Goeudarstvenrqy nauchno-iosledovatel'skiy institut stekla. (Glass furnaces)  ABM40VAP MI., kand. mad. nauk; GADASKINA, I.D., prof.; =Ma, _A F kand. med. nauk; DANISHEVSKIY, S.L.) prof.; ZILIBM, Yu.D., kand. med. nauk; LAZAREV, L.N.., kand. khim. nauk,- LEVINA, E.N., doktor med. nauk; IMT, A.O.; INUBLIVA) Ye.I.; doktor biol. nauk;~--LYKHINA, Ye.T., kand. biol. nauk; MINKINA, N.A.p kand. mad. nauk; RUSIN, V.Ya., kand. mad. nauk; SALMON, L.S.0 kand. med. nauk; SPERANSKIY, S.V.,, TRAKHTENBERG, I.M., dots.; FILM, V.A., kand. biol. nauk; TSIRKp K.G.j kand. mod. nauk; CHEKBOVA. M.P., kand. med. nauk; GRIVA, M., red.; LAZAREVp N.V.jzwl.deyat.naukijprof., red.; LEVINj, tokhn. red.; BASINA,.M.Z.., tekh,4.pVd,,- [Toxic industrial substances; handbook for chomicts, engineers and physicians] Vrednye veshchestva v prowyshlennosti; spra- vochnik dlia khimikov, inzhenerov i vrachei. Izd.4., perer.i dop. Leningradx Goskhimizdat. Pt.2.(Inorganic and metallo- organic compounds] Neorganicheskie i elemtntorganicheskie sor edineniia. 1963. 619 p. (MIAA 17:2)  ACC NR; AT7000309 UR/0000/65/000/000/0515/0526 AUTHOR: Golubev, A. A. 011G,: None TITLE; Experienceland prospect-ts for use of synthetic materials in marine structures, machinery and fishing uquipment tor ships of tho commercial fishing fleet SOURCE: Nauchno_t~lchnicheskaya konforentsiya po ra4vitiyu flota rybnoy promy- shlennosti stran-chlenov SEV. 2d, Leningrad, 1964. Ryboloynyy flot (Fishing fleet); sbornik trudov konterentaii, v. 1. Leningrad, Izd-vo Sudostroyeniye, 1965, 515'-526 TOPIC TAGS: shipbuilding engineering, fishing'ship, synthetic mat-zrial, economic organization ABSTRACT: Dissatisfaction with demonstrated performance characteristics of materials traditionally used in shipbuilding, such as steel and light alloys, has prompted the introduction of synthetic materials in the commercial fishing shipbuilding industry. The properties of certain of these synthetics are listed and their advantages are discussed. Specific examples are given of the proposed uses of synthetic materials. The scientific and industrial tasks facing the member nations of the Council of iMutual Economic Assistance in connection with the exploitation of synthetics in ship- building are given special attention. Orig. art. has: 9 figures and 3 tables. SUB CODE: 13,11/SUBM DATE: 15oct65 -Card 77=  GOIUB,~;V, i.A. Var"fatfon of the pbys�~mj propertleB cf ba-sic wid rc,c',.-3 wf.,h depth. Trudy VSEG2-.1 1()4:-,'152--15'1 164,, (MIRA -18,,!)  GOLUBEV, A.A., inzIn. Heat and fire resistance of plastics. Sudostroenie 30 no.803-36 Ag 64. (WRA 18s7) ~  GOLU~~.,,.A,tA.04 ZIVKMCI]p O.S.; MINCMKOVI YU,P, Develop a state standard for tubular springs. Standartizatsiia 29 no-lIt56-57 N 065 (MIRN 19d)  ZARINSKIYv V.A. I MLK3A p V.A. VGOLUBEY9~AaPt- Meaourement of the pH by meanff of slootroden made of lithium glaos, 74v,lab,' 27 uo,W~3-225 161. (MrRL 1413) 1. Inotitut gookbimii i waliticheskoy khimii izieni V, It Vernadekogo AN S&M. (Hydrogen-Lou concentration)  ,,GOLUBEV,_A~P~; SHATS, S.Ta. Regularities in the charactarlatids of tubes vith-secandary emission. Irv. vys. ucheb. 2av.1 prib. 6 no.5111-19 163. (MM 16: 11) 1. Rokomandovana IAningrUdfl*WixMwMo-U-zhenarnoy kraano- znamennoy akademipq imeni Mochayakogo. j,  GOLUBEV, A.D.; SHATS, S.Ya. Design of amplifiers using a secondary emission tube. Izv.vys. ucheb.zav.; prib. 6 no.6:3-9 163. (MIRA 17:3) 1. Rekomendovana Leningradskoy Krasnoznamennoy voyenno-vozdushnoy inzhenernoy akqtdemiyey imeni A.F.Mozhayskogo.  GOLUERY, A.F., inzh.; IOGINOV, I.G., traktoriBt. I I XUO-fiktic driving of the B-80 tractor. Mekh. i elek, vote** sallkhez.. 17 no.1:4,6-48 159. (MIRA 12:1) I.Pavlodprokeyd oblastneye upravleniye sellakego khozyaystva (for Goltbev) 2.3tvkhez"Irtyshakil," Pavlodarskoy oblasti (for Loginov). (Tractors)  GOLTJBEV, A.G.; STEPANOVAx V.N.; YURGENEVp L,S, Gas-heated,,.single-ratort gas generator. Avt. prom. 27 no. 4:42 AP 161. (MIRA 14:1+) 1. Nauchno-isoledovateltakiy tekhnologichookiy institut avtombbillnoy promyshlennosti. (Gas producers) wC P  GOLUMT., A. I. "New Method of Guiding Large Ships through Locks," Rech. tranap,s 12j No-4s 1952  o 1-0 (3 (-- V, 3-58-2-25/33 AUTHORS: Gorokhov, V.M., Professor, and Rozhdoetvenskiy, B.P. Dotsent TITLEs A Conference of Instructors in Fedagggles and Psychology (Soveshchaniye prepodavateley pedagogiki i paikhologii) PERIODICAL: Vestnik Vysshey Shkoly, 1958, # 2, page 78 (USSR) ABSTRACT: From 17 to 19 Ocotber 1957, a scientific-practical confer- ence of instructors of the chairs of pedagogics and psychology of the universities and pedagogical institutes in the Middle Volga and the Urals region was held in Kazan'. Representatives of 3 universities and 9 pedagogical institutes, directors and chiefs of the teaching sections of secondary schoolop colla- borators of the Tatarskiy institut usoverBhenstvovap'iya uchi- teley (Tatar Institute for the Development of Teachers), and others participated in the conference work. At the plenary sessions and meetings of the 3 sections - pedagogical, psychological and history of pedagogics - 25 reports on various questions of development of the Soviet school were heard. M.P. Shabayeva, Senior Scientific Collabo- rator of the APB RSFSR, submitted a report on the them* " The Soviet School and Pedagogics Over the 40 Years of Soviet Card 112 Power". Candidates of Pedagogical Sciences N.A. Polovnikova  A Conference of Instructors in Pedagogics and Psychology 3-58-2-25/33 and A.I. Golubev reported on the organization of polytechnical edu-ca-T1-on--Tn--tE-*Tatar and Mordvinian Autonomous Republics. Candidate of Pedagogical Sciences B.P. Rozhdestvenskiy and G.A. Petrova spoke of the organization of aesthetic education in the schools of the Tatar Autonomous Republic; Candidate of Pedagogical Soisno*s A.A. Vanshteyn discusaed the mutual relation, between theory and practice in teaching pedagogics. The Kazan' conference decided to establish a permanent organizational bureau for preparing and conducting conferences. ASSOCIATION; Nazanskiy pedagogichookiy institut (Kazan' Pedagogical Institiate)i Kazanskiy gosudarstvennyy univeraitet imeni V.I.U11yanova (Lenina (Kazan' State University im.V.I.Ullyanov (Lenin)) AVAILA13LE: Library of Congress Card 2/2  GOLIJBEV9 gakLey 4vanovich; uVIMEV, S.Sop kand, tekhn. naukq reteenzent)MGANOVO V-.O.,inzh.red.j DOBRITSnTAqR.I.q teklm.red.; GOPJ)EYKVAq L.P., tekhn.rod. (Labyrinth pumps for the chemical industry] Labirintriye laasooy dlia khimichookol promyshlonnosti. Koskvap Oos. nauchno-tekhn. izd-vo mashinostroit. lit-ryp 11961--- 72' & (MM 1428) (Pumping maebinew  GOVJUV, A. 1. Main trends for the development of public health in 1959-1965. Zdrav. Ros.Feder. 2 no.2:3-9 F 158. -, '\ (MIRA 11:3) 1. Machallnik Planovo-financovogo upravleniya HinisterBtva zdravo- okhraneniya SSSR. (PUBLIC HUNT)  Vassar ney* konferen-31ya pO trenlyu I Inusu v rinhInakh. -kd, 19.x 014rodIxamIch ya tooriya weazicl. Opory skol'zhenlya. SrArka "a maIerlmly (Hydrodynamic Theor7 of Lubrication. I smazoeb.T. Slip bearings. 1~brl;lktion and Lubricant Materials) Moscow, s 0 l 8 e Xzd-va AX 335R. 422 . Errata slip Inserted. 3, 0 cop printed. (3ories. Its: Tr-4dy. v. 3) Sponsoring Agency: AARdemlys nauk SSSR. Institut mashinovedonlya. Reap. Zds. for the Section 'Hydrodynamic Theory of Lwbr I"ti -- and Slip Bearings': Is. M. Gutlyar,- Professor, Doctor of Tech- Ical Sciences. and A. K. Dlyachicov. Professor. Doctor or Tech- a * Reap. n1cal 'clonces. Ed. for the Sectlon,*LubrleatlOn and Lubricant Materlslah 0. V. Vinogrsdov. Professor, Doctor 0f - M. Ya. Llaban v Chemical Sciences; Ed. of Publishing House. vch. Ed.: 0. X. Gus'wova. T MP=t This collectlom of articles In Intended for practicing engineers and research scientists. COVERAGE: The collection. publjs~~ *iy titi Ted*nlya AN S= (Institute of Science of Machines, Academy or Sciences =R) contalza vabors Presented at -he III Towmayoxnays konrorentstya po trartlyu I IXnosu v mashlnAkh (Third All-UnIon Conference an Friction and We&, In Machine$ iftich was held AprIl 9-15, 1958. Problems discussed were In ~5 smIn &roast 2) Hydrodynamic Theory of Lubrication and PrIctlon Bearings (Chairman: U. 14. Out'yar, Doctor of Tech- n1cal Sciences, and A. L. D-yachkov. Doctor of Technical Sciences). 2) Lubrication and Lubricant Materla2a (Chair%=.- G. T. VLnogradov, Doctor of Chemical Sciences); 3) Dry and Souridary Priction (Chairman- 15. V. Deryagin. Correspond !" Xomber of the Acadozy or Sciences USSR,and I. V. Kragell U', DamtOr Of Technical Sciences); 4) Wear and Wear Resistance (ChaLr"ant M. X. Krushebov, Doctor or Technical Sciences; and 5) Priction and Antirrictionn Materials (Chair-on. I- Y. Kragollxkly, Doctor or Technical Sciences, and N. K. KrujibchovlDoctor or Technical Sciences). Chairman of the "moral assembly (on the first and last day or the con- fqx4nace) was AcadomIclogn A. A. SLagonrevov. L. Yu. Pruzhanckly, 'd The tMm9aCt1Qn8 Of the conference were published In 3 volumes of wWcb the Present is the third- This volume Contains artLtlea 4Mcermed with the hydrodynamic theory or lubrication, sliding betsuringS. and lubrication u3t*rials. A41IOng the topics covered am. modern development& in the hydrodynamic theory or lub- rl"tlon. experimental methods for investigating the performance Or b*ArIng0 under various conditions, the Mechanics Of lubrlca- t1an under varicuts conditions, the design of bearings for dif- forent epplIcattorts, the theory and practical applications of -lubrleatlng materials. LnelvdIng T1$COUa-pl&3tIC lubricants, calculation methods used In the design or bearings for turbo- electric generators and other heavy machinery, experimental data on t2w lubricating characteristics or many different lubricant ~tcri*20, the effects Or additives, operating and environmental cOodItIODs, corrosion, and accelerated weer testing. Many per- BOrAlItles are mentioned In the test. References SCCOMp8ny cost *r the articles. Investigation of Friction Processes in 11wavIly Loaded 5ndirg Bearings of Rolling Kill* 17 1=,r,_ *_ 'IIu I the Instead, Nation 0e . Viscous Incom- .I. Id Between cLos*iy Located Moving Surfaces 25 On the Motion af a Viscous Incompressible Bearing Gaps In the IA=Inar and Turbulent P1 OW Rogimes 30  0 -4 at, OA A, -4 V 0 0. "0' U "a as .5 0 C E V t00 10 11 0. V. 41 00 U .4 A. .9 U 98 4 -it i , -, - " , -0 , ~ t. ~v . : i, -. z .9 C ~2' at ~ -0 v 59A, g E , a 0 9 -a P. C. v r... 12, U. A S U" U. 11 t 0 Cos.,- S 8 U a vd 8 1 k I C v A E P &U t -~MWRZ" v v vro A ~,4,djs - a - s-. . . .5 1! 2 .0 Ir, 40 a .0 .9 -0 v Or -0 -0 .0 0-- .5 X", ij *s a! tn 0;! C 0 I.V 11 4 r r 11 "N U C- U 0 Ow a .6 V4 a Is: i -0 Wmr A. "R "t S.,j~j3V..'a ~t 04 0. .5. A". C C6 ~O 0 r. -0". 01.1 A 0 9 -9 :- --- , 8 0 9` oce."O" . ,a Z 2 0 :1" v 5 o V "a 'a ."a as S~qoj C A 0* 0 ~~o 0 900 0 a! 4 0 a 19p,0. 14 NU d" ivfl , 3i 19 A.I, Iffacrt of the heat on the lubricated friction in unloaded annular lubricant layers. Tren. i isn. mash. no. 121181-2(Y+ 158.(KIRA 1l-.8) (lubrication and lubricants--Testing)  GOLUBEV Plane steady flow in bearings of viscous noncompressible fluids havicg variable coefficient of viscosity. Tran.'i isn. mash. no. 121205-223 158- (MIRA 11:8) (Bea ringe(He chino ry)) (Lubrication and lubricants)  KOROVGHINSKIY, Mikhail Viktorovich; EWSHOROV, K.K., prof., doktor tekhn.nauk, ratoensent; 00 nd.takhn.nauk, redo; TAIROVA, A.L,, redoizd-v ; SUCLOVA, T.F., takhn.red. LTheoratigal basis of sliding bearing performance] Teoreti- chaskie oanovy raboty podshipnikov skollzhaniia. Hoskys, Gas. nauchno-tekJ2n.izd-vo mashinostroit.lit-rye 1959. 402 p. (MIRA 12:12) (Bearings (Machinery))  GOLUEEV, A.I.; PAVLOV, B.V., inzh., retsenzent; KARGAROV, V.G., sh., red.; MAKAROVA, L.A., tekhn. red. (Modern seals for rotating shafts) Sovremennye uplotne- niia vrashchaiushchikhsia valov. Moskva, Mashgiz, 1963. 214 p. (MIRA 37:2)  GOLUBEV, A. 1. "Development of Flow and Thermal Effect During Liquid Mriction." Cand Phys- Math Sci, Moscow State U, Moscow, 1954. (KL, No 1, Jan 55) Survey of Scientific and Technical Dissertations Defended at USSR Higher Educational Institutions (12) SO: Sum, No. 556, 2.4 Jun 55  3Z(3) SOVI I IZ-59 -3-5115 Translation from: Referativnyy zhurnal. Elektrotekhnika, 1959, Nr 3, p 117 (USSR) AUTHOR:.' Golubev, A. 1. TITLE: Mo~ltltlft-67TAi-2-2000130 (Moderytizatsiya VAB-2-2000/30) PERIODICAL: Elektr. i teplovozn. tyaga, 1957. Nr 12, pp 7-10 ABSTRACT: A new construction, a supply schemeand a control scheme of the VAB-2-2000/30 high-speed circuit breaker were developed at the "Uralelektroapparat" plant. The time of current drop from full load to zero is 0.003-0.007 sec for railroad-type converter installations. The minimum time from the moment of tripping pulse to opening of the VAB-2-2000/30 contacts was 0.002 sec for the new construction. K. V.A. card I /I  GOLUB.EV, A.I., kanMls.-nat.pauk Butt aealing. Trudy VIGH n0,24:-102-124 159, (sealing (Technology)) 04IRh 12;8) o p  S/lWl/000/002/001/008 A11O/AO33 AUTHORS: -Golubev, A.-I!,.Candidate of Physics and Mathematics; Freydisman, G. M., Engineer TITLE: Labyrinth pumps.for corrosives PERIODICAL: Khimicheskoye maschinostroyeniye, no. 2, 1961, 9 - 12 TEXT: The article deals with low capacity and high pressure labyrinth pumps designed and tested at the VIGM (All-Union Institute of Hydraulic Machinery), by A. I. Golubev (author's certificate No.126748, June 16, 1958). The pumps are based on a multiple thread screw which rotates inside a bush with reversed mul- tiple threading. Labyrinth pumps are similar to pumps working on the spiral self- lubricant endless screws principle, the only difference being that screw and bush are multiple threaded. Their operation is analogous to vortex and labyrinth pack- ing and they operate in low viscosity fluids. Experiments proved that the threaded bush operating in water increases the pressure 7 - 10 times. The efficiency of labyrinth pumps is similar to that of vortex pumps and superior to single stage centrifugal pumps operating in underload conditions. A flirther common feature between labyrinth and vortex pumps is the marked dependence of their performance Card 1/8  23146 s/184/61/000/002/001/008 Labyrinth pumps for corrosives A11O/AO33 on their radial and end clearances repectively. The adVantages of labyrinth pumps are: simple shape of all metal and non-metal components; absence of mechanical friction between screw and bushing; flexibility of construction apparent in the proportionality between pressure and the length of flow-area, and higher suction power. Labyrinth pumps were included in the nomenclature of "Wing Pumps for the Chemical Industry. Standard Series". In accordance with this nomenclature the Tsentral'noye konstruktorskoye byuro gidromashinostroyeniya, TsXB GM(Central De- signs Office of Hydraulic Machinery) developed about ten labyrinth pump models for test purposes. Some of these have already passed tests and were sent to pro- duction plants. Beside the TsKB GM, the following organizations have participated in the project: Shchelkovskiy nasosnyy zavod (Shchelkov Pump Plant); UkrNID~hIMMASh and the VIGM. Figure I shows a 1.5',1-2n (1.5Kh-2P) labyrinth pump made of faolite "A" plastics and intended for the handling of corrosives, the pump works at a pres- sure of 65 m liquid column and 1.8 I/sea. capacity. Screw (2) and bush (3) have two symmetric threadings which results in a dual suction and relieves the rotor from the axial force, apart from ensuring satisfactory performance of the gland under the suction pressure. Figure 2 shows the performance of such a pump with a screw diameter of 100 mm. The W-3-6 (lKhP-3-B) labyrinth type immersion pump Card 2/8  23146 s/184/61/ooo/oo2/001/008 Labyrinth pumps for corrosives A1IO/AO33 used for hydrofluoric acids works at a pressure of 10m of liquid column and 1 .3/h cap. and iv shown in Figure 3. Suction pipe (1), screw (2) and bushing (3) are made of Monel metal. The pump has graphite bearing bushings (5) operating on acid lubrication and stuffing box (7) for the sealing liquid. Figure 4 shows a 1.5%-2A-2 (1.5Kh-2A-2) labyrinth pump used for hydrocarbons with resin admixt- ures at 180 - 2000C operating at a pressure of 65 m liquid column and 1.8 1/sec. capacity. The screw has two symmetrical threads and relieves the rotor from axial stresdes. The male and female threads of the screw operate jointly with static threads of suction pipe (1), gland body (7) and bushings (3 and 5). The inain parts are made of carbon steel. As the pumped liquid -tends to crystallize at normal temperature, the pump casing is equipped with pre-heating jacket (4). The escape of poisonous gases is prevented by stuffing boxes (8 and 11) and her- metical connector (9). All three pumps have been designed by the Central Design- ing Office of Hydraulic Machinery. Figure 5 shows a 1-5X-20 (1.5Kh-2I) labyrinth pump made of acidproof 9W629 (E1629) steel and designed at the Shchelkov Pump Plant for operation with corrosive hydrocarbons. The pump operates at a pressure of 100 m liquid column and a capacity of 3 0/h. Contrary to pumps above des- cribed bearing bush (2) relieves the rotor from axial stresses. The intake is radial, the pressure axial and the pressure pipe is near the outlet. Due to the Card 3/6  23146 s/184/61/000/002/001/008' Labyrinth pumps for corrosives A110/A033 described layout of suction and pressure pockets the gland takes up the intake pressure only. 1.5Kh-2I labyrinth pump replaces three-stage centrifugal pumps. Its characteristics are the following: the maximum efficiency is 26% while the reference point efficiency is 22 %. In view of the low delivery, these tro types of pumps are similar in efficiency, but labyrinth pumps have a higher efficiency. Besides, vortex pumps cannot be made entirely of E1629 steel, whose toughness during friction in the face clearances leads to galling and breaking of the oper- ating organs. Experimental testson I.5Kh-2I pumps are nearly completed after which the pump will be sent to a plant. Several pilot models of IKhP-3B and 1.5Kh-2A-2 pumps are still under construction; one passed tests and is now used in the phenolacetone production. The 1.5Kh-2P pump is undergoing service tests with 20 % hydrochloric aoid. The above mentioned designs do not exhaust all possibilities; analogous operating principles crn be applied in the design of dynamic rotary shaft packings, e.g., for pumps del ivering butadiene rubber. These so-called labyrinth impellers would prove particularly efficient at high veloci- ties of the rotainj shaft, as the pressure drop transmitted to them is proportional to the circumferential velceity square. There are5 figures. Card 4/8  GOLUEV, AleRsandr Ignatlyovich; *~J]K, I.V., red. (Iligh-speod automatic uwitcheal ayst-odo-Istvulushchle avtor.atichosk-le vykliuchatell. 2., perev. izd. Moskva, I~erglja, 11)(-/,. 23') P. F 17: 10)  OOLUBV, Aleksandr Tgnat Ilevich; ZHDAMV, G.B., radaktor; UMONOV, radaktor. (High-speed autowtic switches] Bystrodelatiuiushchie avtomati- cheakis, vykliuabstali. gookya, Goo.onarg.izd-yo. 1955. 191 P. (Blectric ovitcbgoar) (MLRA 8:9)  ASTAKHOV > j. A.G.; V"SOVp V..V,.; YEDCRUISM, N.V. A system for the autcmatic, control of Nel proportioning processes In sintering plants. Met. i gormorud. prom. n0.4: 12-13 J3,Ag 165, (MIRA 18:10)  41114 6 * Z 90 t 00 'd Off of 21 a I L A ATALLUMOKSIL 1,1114411tolit CkASSIFKATICH vQ-T J4( G-u 1; 7v - i to 0 It it a III Kiln liffmall 0 0 e 0 0 * 0 a 6 6 4 0 0 ::.:-o 010 0 0 0 o o *. 0 0 6 0 00 04 11 4717-P . "'k, - L 7, -tv Idaud" tho Chou" PAWO Of OWIN by IFUgivation In 11olutims of Omul&W. 0. 1. Ahimor and A. 1. A p 14 " CA 19 3 9, 1 & 10 1 a 2 9 (1 n I u Wam a n/) ; Th HAP -b sj," i it 410"IL KK h6i -Ni ).I J-- Jill Humimi.] 11w best immilvating wAutlow are: (i) il-v.K.L~r,o, rximmum I hr., tind (H) N'-K,Vr,Ol + lHoIN-CrO, clip-mitre Ire I hr, I'll(, flnP366 I,( 4161,1wr aflor Auvit imaivillitto oh, rt-am* shalily III 4ir 4411AM111 Sill dittr 11illidt" suld Its kulutillus t'fX"" \*.(,I -f '11flis- N41111i " .. (I-14N.110. Anti 01N-11,14(j, Tht, dit-mical i-tability '-f G~ it sLit.-r the abilve treateurnt, jarticutarly after 1frALlatill Als 'Afth N." OIN-Cro, dij r t mim-nt 14 fit) fA I 1 4 04 0 A 4 IN 0 it 4 3~ a IF I~ Ac 0 # 0 61164 0 0 0 0 0 6 0 0 0 0 * 6 0 0 4 0 4 0000104 4 0 0 0000 0600 es 0 0 0 41~ goo rive 'Fes, goo gee moo tjoo:'  GOLUDEV, A. I. i .Lab. corrosion an] Electroc~;emlstrYp 1-joscow Inst. lion-ferrous Metals an(I G01( ) "A StUdY o'L' the Corrosion llroces~ics on a 110clel Local Liement. I." Zhur. Fiz. Khim.j 11o. 31 1946.  IN ip it It V W U Z AA R X a 1- a . II A , , - - tit AND t"0 "Yg~* -*-*-o 4t. 04 a s;j ptactilci Oka "Opefillis t.44. cog' moilaola 0 TM rAld W_ 00 Xb**bU Ali*" 1bW.OtVWW4 XW#I$ &IUW in a" 1946 3 Fi KAi 811 V M ) k l A 1 ~ 00 or. j. law mu m., . flaw. ( . . A , ). to , ( , vftr ( 303 di ti f th i " 40 i al d h ib l R A 00 a . -W-( e o Ar on o n us . t t u mil. e equ rtential surtaom 4M liftes of fafm above mhort-eircult.4 dectmics situated d l l 00 1 n Electro zJno wrrv itivi-stigstiml in a so ution es of Ocipper am 't' 01-1 ~ 01,I)ON 1- It' IS of ;r 'kvtnA" ' i I 1 %i 110 AM f " II 049 41 ! . - i 1 r wi- t * n um I . 40 . I i Nati itattlim. As a rule 1bo firld (if Oki 4xwl 4,imcit wpAtUtuortad. liin't 1 9 displatvd In dw dLft44(m of the imvide or *Omido itt im~,,wdmsuo wid, Wit I : A 0 1 1 0 %" 'lot UAWOWbOUndATYPYtOntillt ItW"Ck'dn)jKWiti1OtOtMI4ttOr l f l f d = 0 0 ~ 11 eouti. the fir d *&a In the direetIm o the Anule an Ow. Wnt o f 'rho prater thQdIeplaortmank argativo when In tho d1eq-tillon of tlx# mthociv. 66 a of Uw thid. the gmter wam Q. diffi-mnw the Xoneral " Niundan- potentials. The krightofthutield wrArqualtoRpi,ml. b4irtho MA111% Urthe l Itingths of the anodo and cathtxIt-. -,X. A. -"C:z ANTALLUROKAL LITINAMAt MAMPICATION .00 .00 -00 -00 600 200 use a** too 00 :00 *go MOO woo 10 1 a tw 0 1 x 0 0 0 1 2 9 v Is . . 01 Of 160-:0, 00 4 0 0 * a 0 * 0 0 0  1: 13 m tj little A a A V _?_,2 I - b Alf tioucol .,.. *XjK4,wf pagmusk at that'llilkw.-ftapamb of an Awy (zi-IM0. ftpw-LWA, &W A. 1. (;Wu1jevpu1 G. V. Akimov 11f,impt, r(Nd. (1kk jjlW."'&k (2). ~=Idd) Arod. 8cf, I'* *",, I Flev potratillId 1A.1w1*11 I)b",A r1iting In t1l,w mischniect"Al, tin fAr.") wrr" .00 "Itive #q. 1-d 21 o. .00 alloys (Njnc IM-7, Irtm 1,W6 - odcroscol* eop"4'itilly nwam]r", bv uxing at, ,I,p&mtjj# whic-h Included 6.r,,s fw llbe linc-irm .06 modified for such rAc*Au1v"w"t" Tho 'Rit"ti'll ~ ,mvnt, and tbu *0 alh)). xhow that thts comimund FcZnj is tho mthA'c '"I 04D - I tine cutmic tb,- wk4c conlInment of spinicri-ot-11 bortned in a -tit. hydro. go ehkwic acid mOuthwil. TIw I*JtrlltiAl vaet* front thr mArt. towarall the .00 00 .09 nDvfu&ItMsw'aetj4vI OtbhWt'tmw4x Awntlit) rue"ured in thim tAw twing Zth the utber alloys.-V. K. J, 00 4r j.4o 0 _00 100 0 It goo r Ile it It it 4 It of rl 1 $4  GOLUBIW, Aw 1. USSR/Chemistry - Zinc, Corrosion of Cftemistry - k;lectric Charges May 1947 I'Microgalvanic Elements on the Surface of Corroding Zinc," G. V. Akimov, Corr Mem, Inst Phys Chem, Acad Sci USSR;-A. I. Golubev, All-Union Sci Res Inst Aviation Materials, 3 pp I'Dok Akad Nauk SSSR, Nova Ser" Vol LVI, No 6 Describes experiments which give full corifirmation of hypothesis made by Do La Rive in V30 on action of microolements. PA 5n5  GCLUEEV, A. I.  981-1 1-1-01 A 111-L. IL 4 0 too 60 00 AiSM-SLA *I-,AktU 461 CAL LITCRATWR CLA $13P KA1100 u is if PO is it- L AL t I-A- 2. AlWyo of the S som OUAS. (in RUSSIAll A. U UMATI RddftVk0i KNITUt (JOWtUl Of Ono- L --a m ). v. M, Sept. 1949, p. I I I& 1126. L mg; cuffootion falstAnce of (he Iffletnictallic voililloolki Mating akMir PlAill thV IMMIMiCS ill d6we system was Invejapied. Off the w a themy conualun CTArking of tilcu, j&II4j)% is developM. zoo too so* age too 7-r.-Zz 41  GOWEN, A. 1. "Investi,gation of Galvanic I-Ilicrocells on the Surface of Corrodin.- Alloys," Thesi3 for degrE--e of Dr. Technical Sci. Sub 5 Jun 50, Voscow Inst of Lonferrous 'Meta13 and Gold imeni 1-11. 1. Kalinin. fjp Sumary 71, h Ser) 52, Dissertati2ns Preaented for Degrees in Science and Engineerin? IN Moscow in 1950. From Vechernywja FLoskva, Jan-Dee 1950-  -SoaFon Cracking of Aluminum Alloys. "Research in Coroasion of Metals (Isrledov,~niya Po Kor-rosii Metallov)" * L,hemistry, (USSR Academy of Scie:-.ces, Moscow-1951. Publishcd by--Inst. of Physical - Translation --- ATIC-79062-D F-TS-bO3O.-A/V-  7 MLTI'331,77, A. 1. RUSSDI. iST7:R!,770 AVLAMPONNOY :~.'OjL'Z()ZjC,'T7= PT:CTSFI~qy ,T ,A 3 W C, ON !i.-,AL 0 3 . 'op! 121 P. ILUJ3. DDI'31PS. T.ABU-!,S "LTMIZA-732,11". P. 121 - (122) 615.8 .R91  USSR/Solid State Pbysics - Phase Transformstions in Solids.. F-5 Abst Jo=al: Referat Zhur - Mika, No 12$ 1956, 34744 Author: Golubevp A. I. Bstitutiont None Title: luterci7stallite Corrosion and Corrosive Cracking of Aluminum Alloys O-rigimal Periodical., Korroziya metallov i metody bor'by a ney., Moscovj, Oborongiz, 1955, 257-270 Abstract: None /,O.p / - 1 -  A I.: TUMANOV, A. N.: FILIPPOVA, A. P.) "Behavior of Structural Components of Aluminum Alloys in the Process of Chemical Oxidation and Ancdizing in Sulfuric Acid," and with MAKAROV, N. A., SAMIU01AW-1, L. N. : "Filling the Pores of Oxide Film Obtained by Anodic Oxidation of Aluminum and Its Alloysy " Korroziya i azshchita metallov (Corrosion and Protection of Metals), Moscow, Oborongiz, 1957- 3~6 p. FURPOSE: This book is intended for engineering, technical, and Scientific personnel, at industrial plants, research inotituteo) and design offices working in the field of corrosion-protection of stainless steel, high-streng-th structural steel, and light-alloys.  j A. I.; CIEBOTAREVA, 1. 1.; to "Investigation of the Processes of Anodizing Aluminum Alloys in Oxalic Acid, Korroziya i azshch1ta metallov (Corrosion and Protection of Metals), Moscow, Oborongiz, 1957, 366 P- PURPOSE: This book is intended for engineering, technical, and scientific personnel, at industrial plants, research institutes, and design offices working in the field of corrosion-protection of stainless steel, high-strength structural steel, and light alloys.  SOV/137-58-11-21151 Translation from: Referativnyy zhurnal. Metallurgiya, 1958, Nr 11, p 188 (USSR) AUTHORS: Golubev, A. 1. , Tumanov, A: N. , Filippova, A. P. TITLE: Behavior of the Structural Components of Aluminum Alloys During the Process of Chemical and Anodic Staining in Sulfuric Acid (Povedeniye strukturnykh sostavlyayushchikh alyuminiyevykh splavov v protsesse khimicheskogo oksidirovaniya i anodiro-'aniya v sernoy kislote) PERIODICAL: V sb. : Korroziya i zashchita metallov. Moscow, Oborongiz, 1957, pp 328-341 ABSTRACT: The behavior of various structural components of cast At alloys during anodic (A) and chemical (C). stairdng was investigated. A was continued for 40 min in H2S04 Of 200 g/liter concentration at 180C and a cathode cd of 0.6-1 amp/dm2. It was found that alloys cast under pressure are anodized at a higher voltage than chill-cast alloys. C was conducted in a solution containing (in g/liter): Cr03 3 and NaZSiF6 3 at 18-200 during 10 min. Before the C and A a part of the surface of the alloy was etched in a 0.50/o HF solution. Card 1/2 Successive metallographic analysis of the specimens after etching,  SOV/137-58-11-23151 Behavior of the Structural Components of Aluminum Alloys (cont. ) C, and A made it possible to establish that in case of a greater Cu content (4,15~6) the alloy consists of a solid solution and the chemical compound GuAIZ. During A a film forms only on the surface of the solid solution. The chemical compound is etched away. Upon investigation of alloys containing an appreciable amount of Si it was established that the anodic film is then also formed on the surface of the solid solution only. The surface of Si crystals remains unchanged. Upon either chemical or electrochemical treatment of alloys no discernible oxide film could be discovered on the surface of the Si crystals. Addition of up to 10.46 Zn to Si alloys shows no appreciable effect on the behavior of the alloy during A and C. Alloys containing Mg have, along with the solid solution, an Mg2Si component which is completely dis-- solved during the A of the alloy. Y u. P. Card 2/2  SOV/1 37-58-10-21376 Translation from: Referativnyy zhurnal, Metallurgiya, 1958, Nr 10, p 132 (USSR) AUTHORS: Cbebotareva, 1. 1. , Golubev, A. 1, TITLE: Investigation of the Processes of Anodizing of Aluminum Alloys in Oxalic Acid (Issledovaniye protsessov anodirovaniya alyuminiyevykh splavov v shchavelevoy kislote) PERIODICAL: V sb. : Korroziya i zashchita metallov. Moscow, Oborongiz, 1957, pp 342-353 ABSTRACT: In the process of anodizing of Al and its alloys (AMg, AMts, and D16) in 30/0 oxalic acid a decrease in anode cd is observed. For example, during the anodizing of Al and AlMg for 2one hour, the cathode cd decreases from 5 to 1.4 amp/dm ; in the course of anodizing of D16, it decreases from 5 to 2. 8 amp/dm2; the thinnest films (F) form on the D16 alloy, and the thickest ones on the AMg alloy. The porosity of the anodic films was determined by the gravimetric method, i. e. , by filling of the pores with oil. The greatest porosity was observed on D16 alloy and the least on Al. The rate of dissolution was estab- lished for the dissolution of oxide F in 370 oxtlic acid proceed- Card 1/2 in8 simultaneously with its growth. The highest rate of  SOV11 37-58-10-21376 Investigation of the Procf!sses of Anodizing of Aluminum (cont. ) dissolution of anodic F was observed for D16, ...e lowest for Al; this is explained by the different porosity and development of the surface of the F. The electrical insulating properties of the F can be considerably improved by filling the pores with 1154-grade (TUMKhP IQ 13-43) glyphthalic-oil lacquer. L. A. 1. Aluminum alloys--Processing 2. Oxide films--Decomposition 3. Thin films--Porosity 4. Oxalic acid--Performance Card 2/2  SOV/ 137-58-9- 19601 Translation from: Referativnyy zhurnal, Metallurgiya, 1958, Nr 9, p 210 (USSR) AUTHORS: Golubev, A.I., Makarov, N.A., Samokhvalov, L.N. TITLE- -T-.he-BqTMff"g009~,o_f Oxide Films Obtained by the Anodic Oxida- tion of Aluminum and its Alloys (Napolneniye okisnykh plenok, poluchayemykh anodnym oksidirovaniyern alyuminiya i yego splavov) PERIODICAL: V sb.: Korroziya i zashchita metallov. Moscow, Oborongiz, 1957, pp 354-367 ABSTRACT: The causes of the appearance of "white spots", which form upon the building up of an anode oxide film (F) in tap water at 90-950 were investigated. It is assumed that the process of building up of F in water acidulated with HZS04 should be re- garded as the chemical reaction of the solution with the oxide F. The "whiteness" (W) may appear as a result of insufficient time for building up the F or as a result of its treatment in water at low pH (2.8-3.9). In the latter case, probably, the oxide F reacts not only with water but also with the S042- forming on the walls of the pores of the AlZ(S04)3 and other S- Card 1/2 containing compounds which contribute to a stronger  SOV/ 137-58-9-19601 The Building Up of Oxide Films (cont.) adsorption of water or lacquer solvent during the building up and subsequent coloring. This causes the appearance of W. The local distribution of W might be the result of an unevenness in the thickness and porosity of F. W does not appear upon the building up in water at pH 4. W appearing earlier disappears upon the second building up at pH 4.5. A new method for color- less building up anode F on plated material in a solution containing 10 g/I NH4N03 and 0.05 g/I (NH4)ZHP04 was developed. V. G. 1. Aluminum--Oxidation 2. Oxide films--Development 3. Electrolytes--Properties 4. Sulfuric acid--Applications , 5. Water--Perforrrance Card Z/Z  PHASE I BOOK EaWITATION SOV/4535 Vaesoyuznyy sovet neucbno-tekbnicheakikh obshchestv Mezhkristallitnaya korroziya. I korroziya metallov v napryazhennom sostoyanii (Intercrystalline and Stress Corrosion of Metals) Moscow., Mashgiz., 1960. 358 P- 3.,000 copies prii3ted, Ed.: I.A. levin ciencee* Ed. of Publishing House*. ., Candidate of Technical 8 1 1.1. Leenichenko, Engineer; Tech. Ed.: V.D. Elfkind; Managing Ed. for Literature on Metalworking and Inatrument Naldng (Mashgiz): V.V. RzhavinSkiy, Engineer; Editor~al Board: I.A. Levin, Candldaie~ of Technical Sciences (Chair=).. V.P. Batrakov, Candidate of Technical Sciences., V.M. Nikiforova, Candidate of Technical Sciences, and A.V. Turkovskaya., Candidate of Technicel Sciences. PURPOSE: This collection of articles Is intended for technical personnel concerned with problems of corrosion of metals. COVERAGE* The collection contains discussions of intercrystalline corrosion of SQ;iess steels and stress corrosion of carbon steels, lov-alloy and stainless steels, and light-weight and nonferrous alloys. The tendency of steels of Cardr~  Interc:Mtalline and Stress Corrosion of Metals SOV/4535 various composition and systems to corrode under certain conditions is discussed and the nature of corrosion and corrosion cracking Is analyzed. No personalities are mentioned. Most of the articles are accompanied by bibliographic referencesj, the majority of which are Soviet. TABLE OF CONTENTSs I. GENERAL PROBLEMS Arkharov., V.I., Doctor of Technica'1 Sciencesp Professor, Intercrystalline Internal Adsorption of Dissolved Admixtures and Its Significance for Intercrystalline Corrosion Problems 3 GoLqbff-'.-A.I, The Role of rntermetallic Compounds in Selective Corrosion Processes 15 II. UMOTALLINE COMOSION OF STAINLESS STEELS Cheskis,. Kh. I.., Candidate of Technical Sciences.. 3.I. Vollfson., and Yu. S. Medvedev., Engineer. Effect of Slow Heating on the Tendency of lKh18Nqr Steel Toward Intercrystalline Corrosion 27 C ard, 2A.9-  DID, Iosif Lovovich; Qjg~~IA ~I~oktor takhn.naUkt otvoredep retsenzent; IOPA, L.A., prof., doktor khim.nauk, reteenzent; VEMKIff. S.G., prof., reteenzent; BAMITMM, A.L., red.izd-va; KAKOI, Te.T., takhn.red. [Atmospheric corrosion of metals] Atmoofernaia korroziia matellov. Koskva, Izd-vo A)wd.nauk SSM, 1960. 371 p. NmA 14:1) (Corrosion and anticorrosives)  PHASE I BOOK EXPLOITATION SOV/5749 Golubev, Andrey Iovich -- ---------- Anodnoye okisleniye alyuminiyevykhoplavov (Anodic Oxidation of Aluminum Alloys) Moscow, Izd-vo AN SSSR$.1961. 198 p. Errata slip inserted. 2800 copies printed, Sponsoring Agency: Akademiya nauk SSSR. Institut fizicheskoy khimii. ReBp. Ed.; I. L. Rozfnfelld, Doctor of Chemical Sciences; Ed. of Publishing House: A. L. Bankvitser; Tech. Ed.: G. N. Romanov. PUB-POSE : This book is intended for electrochemists and metal- lurgists, and for technicians and specialists concerned with anodic treatment of parts made from aluminum and its alloys. COVERAGE: q-%e book has been designed to fill the need for a aystematized survey and summing up of the voluminous literature r  Anodic Oxidation of Aluminum (cont.) SOV/5749 on the various ohemical and electrochemical methods for tree-'-,- ing and finishing the surfaces of aluminum and its alloys. It zerveB also to report on the laboratory investigations of the author and his colleagues who, throughout their experiments, i,sed the same alloys under rigidly determined experimental con- 4itlons (volume of solution, electrolyte temperalure, mixing r-1-ficieney, etc.). Particular attention is given to the process of anodizing aluminum alloys and to the physicochemioal properties of anodic films. Problems of the corrosion of aluminum alloys and methods of preparing a surface for anodizing are also con- sidered. The present work is based for the most part on studies made by the author In collaboration with A. N. Tumanov, N. A. Makarov, and workers at (unidentified] factory laborat,-.ries 1. 1. Chebotareva and A. I. U anskaya. A. N. Tumanol. and N. A. Mak-arov assisted In Mr.. 2 8 and 9; 1. 1. Chebotareva, in , 7, t~ Ch. 6; and A. I. Utyanskaya, in Ch. 4, The author thanks I. L. Rozenfelld, Doctor of Chemical Sciences, P. A. Akoll.zin, Doctor of Technical Sciencesj A. V. BelobzheBkiy, Candidate of Chemical Seiencea, A. P. Filippova, A." N. Samokhvalov, P. IT. Strekalov, Card 2/6  Anodic Oxidation of Aluminum (Cont.) SOV/5749 and M. N. Roa?ldn. There are 112 references: 48 Soviet, 41 ~nglish,22 German, and 1 French. TABLE OF CONTENTS: Introduction 3 Ch. 1. Corrosion of Aluminum Alloys 5 Aluminum alloys 1 5 General corrosion of aluminum alloys % 5 Theory of intererystallite corrosion and of corrosion cracking of aluminum alloys 17 Ch. 2. Preparation of the Surface of Aluminum Alloys Before Anodizing 27 Degreasing and pickling of the surfaces o4V alloys 27 Theory of the electrolytic and chemical processes for polishing metals 30 0 a", 3/b  GOLUBEV, A,..I j_BEWBZIfESKIY, AN,; IlIKILLULOVSKIY, YuJI "Theory of corrosion and metal protection" t7 N.D. Tomashov. Reviewed by A.I. Golubev, A,V. Be-Lobzheskii, 1U.N. Mikhailovskii. Zhur.fiz.khim, 35 n'o.12:2825-2826 D 361. (MIRA 14:12) (Metals-,Corrosion) (Tomashov~ 14D.) ~7,  TOMASHOV, N.D.,, doktor khim. nauk, prof., otv. red.; GOLUBEV* A I --0' iU doktor tekhn. nauk, otv. red.; PALEOLOG, Ye.T.-,-sn-a~.- nauk, red.; ALITOVSKIY, R.M., kand. khim. nauk, red.; MIROLYUBOVp U.N., kand. khim. nauk, red.; ARKHANGELISKAYA, M.S., red.; ISLENTIYEVA, P.G.,, tekhn. red. (Corrosion of metals and alloys] Korroziia metallov i aplavov; sbornik. Moskva, Metallurgizdat, 1963. 382 p. (MIRA 16:5) (Corrosion and anticorrosives)  ACCESSION NR: AT4013988 S/3070/63/0001000/0193/0195 AUTHOR: Golubev, A. 1. Strokalov, P.V. TITLE: Semiautomatic Installation for measurement of potential on the surface of alloy microcomponents SOURCE: Novy*yc mashiny*1 pribory* dlya ispy*tanlya motallov. Sbornik statey. Moscow, Metallurgizdat, 1963, 193-195 D TOPIC TAGS: alloy surface, potential distribution, surface potential measurement, microgalvanic couple, corrosion, aluminum alloy, aluminum corrosion, nickel aluminuni alloy, nickel alloy ABSTRACT: The corrosion rate of alloys frequently depends on the presence an(I ci~cctive- ness of microgalvanic couples on the metal surface. An installation has i,cen coil: ~ ..-~ leted by the authors which is capable of determining and recording potential dUrnrci,:cs between alloy-structure components several decades of microns large, with a precisiua up to fractions of a millivolt. The Installation is illustrated in Fig. 1 of the Enclosure. Electrogalvaaic Card 1/4~,- t2  ACCESSION NR: AT4013988 potentials between the structure components of an alloy are measured, using the compensation method, bya cathode voltmeter having an input resistance of appro)dmately 150 megobins and provided with a high-resistance potentiometer PPTV-1. The cathode voltmeter repre- sents a simple electrometric amplifier, fed from a battery. The test specimen, having a smoothly ground surface, Is mounted In abath filled with electrolyte, une3rneath a microscope on a micromanipulation table, permitting observation of a desired region on the specimen surface. A,capillary is fastened to a micromanipulation column and is filled with electrolyte. The tip of this capillary can be located at a close distance over the spot investigated on the surface of the specimen. For electrochemical measurementB, the internal diameter of the capillary must be several times smaller than the dimension across the crystallite investigated. At its other end the capillary is enlarged and is connected to a calomel half- cell. The body of the specimen is connected to the negative pole of the input side of the cathode voltmeter by an insWated conductor. The positive polo of the cathode voltnieter input side is connected to the negative pole of the ~otontiometer PPTV-1, the positive pole of which is connected to the calomel half-coll, closing the galvanic chain. The high- resistance potentiometer, together with the cathode voltmeter, permits compensating the Card 21W,-  ACCESSION NR: AT4013988 major part of the potential difference between the calomel half-cell and the metallic electrode on the specimen surface. 7be remaining smaller part of the potential difference Is ampli- fied in the cathodo voltmeter and can be measured on its output side by a microammeter or galvanometer with a luminescent scale. When used together with the microammeter M-95, the obtainable sensitivity of the cathode voltmeter Is from 100 mV to 0. 2 mV per division. The potential of each investigated point of the specimen i~ determined by reading the decade0i off the potentiometer, and the units on the scale of e microammeter. A photographic device is focused on the luminescent scale of the Oroarnmeter and records the uncompensaW(l potential changes on the surface of the specimen, while the specimen is moved horizontally underneath the stationary capillary tip by operating, at certain Intervals, a sclsyn coupl'cd to the micromanipulation table. At the same time, the selsyn actuates a drive in the photo- graphic recorder, causing a movement of the recording roll-film, synchronous with the horizontal dislocation of the specimen underneath the gapillary tip. For example, Fig. 2 of the Enclosur'8 shows curves of potential distributton of the surface of a specimen of aluminum-base alloy with 8% nickel In. 0. 1N NaOft at room temperature, obtained with ~ho above described Installation. The structure of the alloy consisted of the eutecLic AI+NiAI3- Card 3/0~  ACCESSION NR: AT4013988 Different size crystals of the intermetallic NiAl. were scattered on the background of the eutectic, In the investigated alloy, the intormethIlic phase represents the cathode, and a potential difference of 12 mV has been measured between the anodic background and the intermet.dlic phase. It has been found that this potential difference decreased with time (see Fig. 2 of the E nclosure). Orig. art. has: 3 figures. ASSOCIATION: Institut fizicheskoy kh1mU AN SSSR (Institute of Physical Chemistry,' AN SSSR) SUBMITTED: 00 DATE ACQ: 2OFeb64 ENCL: 02 SUB CODE: MM NO REF SOV: 000 OTHER- 000  ACCESSION NR: AT4043074 8/0000/64/000/000/0204/0221 -A I 19inberg, A. M. AUTHOR: Grachava, M. P., Golubev, TrrLE: structure of opaque oxide films on aluminum as indicated by electron micro- scope studies "SOURCE: Mezhvuzovskaya konferentaiya po'anodnoy zashchite metallov ot korrozii. let, Kazan, 1961. Anodnaya. zashchita metallov (Anodic protection of metals); doldady* koderentaii. Moscow, Izd-vo Mashinostroyonlye, 1964, 204-221 TOPIC TAGS: anodized aluminum, anodized aluminum alloy, anodic oxide film, anodic film structure, electron microscope structural analysis, carbon collold'replica method, metal hydroxide penetration, film filling effect, current density, anodic film pore, film pore dimension. aluminum "ooo, aluminum AOO, aluminum AD-1, aluminum alloy g, aluminum alloy D-1, aluminum alloy D-16, aluminum AMts. aluminum alloy AM oxide film, aluminum corrosion ABSTRACT: The mechanism of formation and structure of opaque oxide films was attkiled 6n samples of aluminum "000, AOO, ADI and aluminum alloys Dle DIG, -1/3  V: ACCESSION NR- AT4043074 AMto and AMg (compositlons given). Samples were prepared by chemical degreasing and bleaching (30% KNO *), then anodized in various baths under different conditions of J temperature, voltage, Aration and pit'. Structural analyses of the films obtained -colloid replica method and a magnification of 22000:1 on an electron utilized the carbon microscope EM-3. It was established that opacity is not governed by sample composition, 'nor can it result from penetration of metal hydroxides into the film pores or t6a fitting of films, but probably depends on film structure and the corresponding quantity and dimensions -of -the pores. Stepwise modification of the current density facilitiates formatign Of an opaque film. The presence of pores and a cellular structure was confirmed. The latter Is rearranged as the current density Increases by stages; the oxide cell dimensions increase in the cell formation area and the number of 6ella per unit of surface decreases J corr~apondlngly. Pore diameters In the surface layers of films vary little durhg oxidation. A sharp discrepancy develops between the number of cello on the metal surface and the number of pores on the external surface of films. Ile number of pores becomes greater than the number of cells when the currAnt density is Increased by stages.! 2/3 Card   lip 0 ALI - lip r L '2005-66 -WTwi~tMt) -A AZZ NR, XT6013788 tA) SOURCE CODE: ua/0060/65/000/0007/0059/0079- AUTHOR: Golubev, A. I.; Ronthin, M. N. J/ ORG: none TITLE: Electrochemical and corrosion behavior of aluminum-base binary alloys and intermetallic compound 9 SOURCE: Korroziya metallov i splavov (Corrosion of metals and alloyo)o no. 2. Moscow, Izd-vo Metallurgiya, 1965, 59-79 TOPIC TAGS, 'Aluminum base alloy, binary alloy, electrochemistry, corrosion, intermetallic compound ABSUACT: The binary Al-base alloys investigated contain components which are alloy additives (Fe, Nis Ti. Cr, Mn, Sb) and their principal phases are Al-base solid solutions and the corresponding intermetallic compounds (IMC) (FeA13, NiA13, CuA120 Mg2A13, TIA13, AlSb). Special experiments established that the potential-time dependence for isolated DIC crystals in a real binary Al alloy virtually coincides with the potential-time dependence for the corresponding synthesized homogeneous IMC. Standard electrochemical and corrosion tests along with the plotting of polarization curves showed that IKC (except Mg2A'3) are cathodic phases while Al is the anodic phase. The Al-IMC Al B Y pairs in the alkali medium are more active than Al in pair with the B component Uf the corresponding 114C (B is the cathodic component). 1KC COM 1/4  potentials occupy intermediate values with respect to the potentials of the compo- nents of binary Al-base alloys. The corrosion behavior of IMC may be markedly affected by the component remaining at the surface in the process of the selective dissolution of the compound. E.g. during the dissolution of FeA13 in O.lN Naoll during the first 40-50 min its potential becomes somewhat displaced in the positive direction while the corrosion rate increases at the same time. This is a consequence,. of the increase in the cathodic surface area of Fe in the process of the selective dissolution of the DIC. After the potential E = -0.890-0.920 v is reached -- whi~ch corresponds to the passivation potential of FeAl on polarization curve 2 in Fig. I -- there occurs a sharp increase in the potential and decrease in the corrosion rate of this IMC. The anodic reaction with the most negative potential in these condi- tions is the magnetite-formation reaction: Me + $OR- Fe304 + 4H20 + 80; 0 Ecalc. , -0.847 v. Hence it may be assumed that the passivity of FeAl 3 is due to the formation of Fe303 at the surface of the fine-disperse iron remaining after the selective dissolution of Al from this IHC. Hydrog6a overvoltage for L14C of the Al B type in alkali (Naoia) and neutral (NaCl) media is lower than for the cathodic cL;Onent Gf the corces- ponding compounds when b b in the rexion of Tafel curves, An analysia of the -AIXBy-- 4--l-, ------ ---- Card 2/4  -[-'ACd-NRi-- -AT601378a-- - ej 4i .1.0- - 0 ! curveli to altminmi-- 2 Fe-Al q 3 in OAN solution of at 25"C Na& CIO. log i (ma/CM2) Card 3/4  ACC NRi AT6013788 anodic behavior of INC shows that, from the electrochemical standpoint, the diasolu- tion of such compounds as CuAl or KA12 in the presence of their self-dissolution 2 potentials cannot involve the simultaneous passage of both components into the solution. These findings should contribute to the formulation of a unified theory of the corrosion of alloys which 4akes into account the special features of the corrosioj-- .of solid solutions.146eutecticsiand IKC -and their combinations which enterin the structure of any alloy. Orig. art. hast 12 figures and 6 tables. SUB CODE-- 020/ 013 SUBM DATE: 19Jul65/ ORIG REF: OTH REF: V. Card 4/4 _Xc_  AMOR:-.-Golubev, A. L ORG: none Ul K2rovi~j Y~L- _H. TITLE: Corrosion 9f aluminum and titanium in clearance gaps SOURCE: Korrozlypnuetallov i splavoV (Corrosion of metals and alloys), no. 2. Moscow, 1zd-V0 Metallurgiya, 1965, 351-358 :TOPIC TAGS-. aluminum alloy, titanium base alloy, copper containing alloy, sea water corrosion,.oxygen, shipbuilding engineering/AVOO aluminum, AMg-5 Al alloy, DItp Al alloy, VT-lD Ti-Cu alloy ABSTRACT: The article deals with the processes of the decrease in 02 concentration i clearance gaps, the effect of 02 and pH value on electrode potentials, and the work o macro-corrosion pairs, as investigated by a previously described method (Vlanovskiy, 1. B., Korovin, Yu. M. ZhM, 1962, 35, 8, 1753). On Al and Ti alloys exposed to Be water the 02 concentration in the clearance gaps sharply decreases to an insignifican level owing to the intense rate of con3umption Of 02 for passivation processes in narrovi gaps; in the case of Al, if this level falls below 0'5 mg 0 per liter, the potential gets displaced by 500 mv in the negative direction, and ths leads to the formation of differential-aeration pairs; the attendant hydrolysis of the anodic 1/2  .products of corrosion causes the pH value in the clearance gaps to diminish from 8.0 (normal value) to 3.2-3.4. This, in its turn, leads to an increase in current in- tensity owing to the decrease in anodic polarizability. Thus, for pure aluminum AVOO, in the presence of an:.02 concentration cf 0.1 mg/liter the current intensity of the ,;differential-aeration"Spair-..is 10 0a; if, however, given the same 02 concentration, the pH value decrease6 to 4.0;-the current intensity o increases to 18 pa. ,~ the pa A similar pattern is observed'for the Al alloys ARg-5tand D16.t As for Ti, it was found that, while it did corrode to a slight ex-tent in narrow clearance gaps, it re- --mainvas-highl c a sistant-An-sea wa-t#-r as~-it--is- -under other conditions; thif -durrin Lifiddi-c--p-o-la-ri-z-a-t-i-o-n- pH -.;value- does-- -n-o--t-----d-e-c--r-e--a-se---i-n --the-- thereasow is t C16a'rance gaps of Ti. Cu~treated Ti is somewhat more corrosion resistant, specimens of a Ti-Cu alloy.'(VT-lD)\Were tested for 18 months in sea water and it was found that, while some chara6t_e_r_f_s_ETc- corrosion &rose an the barnacle-encrusted areas, the depth of this corrosion was insignificant -- of the order of 0.01 mm; even this slight corrosion, howeverp can:be eliminated if the use of Ti to protect the underwater part of-ship's hulls against barnacles is combined 4ith the application of ultrasonic vibrations, Orig. am-hasa 5 figures.and I table. na 7 Z _jA, -1.1;' 4 ? T~ 2/2 16 N S  ________L-28543_66---'EWT(mjM- EWA(d-)/EVP(U roC!, i-An-IGD---- j 78 S~4 ACC NRt AT6013810 (N) SOURCE CODE: UR/0000/65/000/000/0366 03 S4.- AUTHORt-.Golubev, A. L; U Korovin, Yu. H.; Se V. F. ORG: none TITLE: Effect of hydrogIn sulfide on the corrosion of stainless and carbon steels SOURCE: Korroziya. metallov L splavoV (Corrosion of metals and alloys), no. 2, Moscow, Izd-vo Hetallurgiya,-- 19651 366-378---- TOVIC TAGS: stainless steel, carbon steel, seek water corrosion, hydrogen sulfide, hydrogen ion / IKhl8N9T stainless steel, lKhl3 steel, St. 3 carbon steel ABSTRACT: H2S in the sea is produced by sulfate-reducing bacteria which proliferate on barnacle-encrusted ship hulls and subsurface structures. In this connection, for stainless steel the effect of H2S on electrode potential was investigated as a cri- terion of corrosion resistance of the steel. For carbon steel, the effect of H2S on. both the electrode potential and the self-dissolution processes was investigated. The experiments were performed in the presence of 02 concentrations of < 0.1 and 9.0 Mg/ /liter, variation in pil value from 8 to 2 and variation in H S. concentration from 0 to 100 mg/liter, 02 was removed by blowdown with N2 extractei from air. The air, flowing via flow meter I (Fig. 1) and safety flask 2, entered cylinders 3-5 contain- ling an alkali solution of pyragallol in which it was relieved of most of its 02. The, Card 1/4  ACC NRi AT6013810. io Fig. 1. Diagram of setup for investigating the effect of hydrogen sulfide on the electrode potential in the a:bsence of oxygen: -1- flow meter; flask-, 3, 4, 5 absorption. :cylinders;,'_k_-: tubular furnace; LVLLf _~hsie_'Way Y4~j~.. 8_-.t_es_t...vessel; ..9-magneticstirrer; - 10 !!._samp1er;_ 12, 13 - safety flasks; 14 - vessel for producing H 2S; 15 - separatory funnel; 16 - two-way valve; 17 teat specimen; 18 --,electrolyte; 19 calomel electrode 20 - potentiometer C,rd 2/411,  NR-j____A T6013810 I" remaining 02 was absorbed in tubular furnace 6 containing copper chips heated to 6000 C. The passage of air was facilitated by rarefaction produced with the aid of a fore- -pump, with the rate of air inflow- being determined by flow meter lo Pure N entered vessel 8 via ~'thre-e way.valve 7.To accelerate the process of 02 removal, the2solution wa stirred with magnetic stirrer 9, The samples were collected via tube 10. H2 S was pro- duced by reacting HC1 with a titrated Na 2S solutiono The electrode potentials were . measured by means of the P-4 potentiometer and anodic polarization curves we5e plot- ted by the potentiostatic method on using cylindrical specimens of IKhIBN9TPlKhl3 4 and St. 3 steels. The experiments were performed in Black Sea watei--(pil. ~B.ZT.-f Findings: H2S and the intermediate products of its oxidation definitely affect the electrode potentials and corrosion of stainless and carbon steels. Thus ' as the 112s concentration of sea water increases the electrode potential is displaced in the minus direction owing to the sharp decrease in 02 concentration stemming from the con sumption of 02 for the oxidation of H 2S. When the PH of sea water is S; 3 - 35 mg/lRer control t. H 2 H2S; 4 wo 04 experiment without H S 2 d ~Q -,4 current density 1, pa/cm2 tration of-sea water is.-- in the absente of 0 the faster the corrosion rate of steel,becomes. If 0 is present In the solutioq~ ~.Ithe corrosion of carbon steel with increasing R2S concintrationinitially deer-e'a's"es*owing to the decrease in 02 content, but-later it increasesi Orig. art. has: 7 figures$ I table. SUB COM, 'I%-ILWIOTI;I. S=.: DATE: 19ju165/ ORIG RM 018/ OM REP.- 001 Card_4/ 7-1  BYUYRINP A.I.;,OLUBEV, A.I.; NEKRASOV, V.Po; CULCY, V.M.; OLIKHOV, I.N.; -,- ...... . . I v XGLKHODZHAYT,, A. . Making boreholea with. smaller diameter at the -i:keli Mine. Gor.zhur. no.8:27-30 Ag 165. (MTRA 18z10)  L'2623-66 94T(m)/EPF(c)/ETC/F-iG(M)/T/i7ill)(t)/UrIP(z) /0',W(b) IJP(c) V3/JDAW/WB 1ACCESSION NR: APS011364 UR/0365/65/001/002/0199/0206 620.196 C .AUTHOR: Golubev. A. I.; Ronzhin, M. N.__ !TITLE., Electrochemical and corrosigR 2perties of intermetallic compounds based _yE ;on aluminum 5) 14 ';SOURCE: Zashchita metallov, v. 1, no. 2, 1965, 199-206 JOPIC TAGSZ corrosion resistance, electrochemistry, electrode potential, inter- :metallic compound, aluminum, nickel, 5~pprj titanium, magnesium, chromium, man- ,!ABSTRACT: Electrochemical d corrosion properties of intermetallic compounds ViA13, CUA12, TiAl3p AlSb, M92Sb3, CrA17, MnA16) and pure metals were stud- led in two solutionst 3% NaCl and 0.1-normal NaOH. The ratio of electrolyte ~Volume to sample surface area In a cell varied within 200-250 ml/cmZ. A saturated Icalomel half-cell served as a reference electrode. Generally, in alkaline and neu-, itral solutions, the hydrogen overvoltage on intermetallic electrodes is lower than o n the corresponding Rqre metal ectrodes. In 0.1-normal NaOH solution, the maxi- ;mum potential difference betvee~ the pure components of the intermetallic compounds, Card 1/4  L 2623-66 1ACCESSION NR: AP5011364 'was 1-15 mV. The electrode potentials of intermetallic compoundad have values in- between the electrode potentials of the pure metals. The kinetics of dissolution of the intermetallic compounds is a function of the electrochemical propertie3 (anodic and cathodic behavior) of the pure metal constituents. In the region betweed the self-dissolving potential of the intermetallic compound and the steady-state potential of the cathode component, the anode behavior of the inter- metallic compound is a function of the properties of the anodic component. The cathodic properties of the anodic component show up first at very high potential values. As a result of selective dissolving, the corrosion of the intermetallic compound is largeJ-r determined by that component which concentratep on the elec- trode surface. The hydrogen overvoltage, (-E in reference to a nomal hydrogen electrode) on the intermetallic compounds and pure metals vs. logarithm of current density, i, is shown in fig. I of t -he Enclosure. The dependence of the eleletrode potential and the rate of corrosion of FeA13 in 0.1-noimal NaOH at 250C upot time is shown in fig. 2 oi the Enclosure. Orig. art. has: 4 tables, 3 figures, ASSOCIATION: Akademiya nauk SSSR, Institut fizicheskoy khimii (Academy of Sciences, SSSR, Institute of Physical Chemi!Lt ~)Ix,-:~, SUBMITTED: 06Oct64 --F.HL% t02 SUB CODE: KH, GC NO REF SOV: 003 OTHERt .007 Card.2/-4---  L 2623-66 'AtCESSION MR.- AP5011364 ENCLOSURE: 01 4* C3 0.- % cc 44 ir tv CArd 3/4 ag  ACCESSION NR: APS011364 ENCLOSURE,', 02 -4 rA4 44 Q cp 0 0 V 0 c: 0.0 en Ij 0 dA -c ILI c" F-4 cl 0 1 04 Card 4A     GOLUBEVI IGITATOV, N.N. Studyling the rrf~-es-3 Of arf)- -st ZuL Sulfuric and o-yall- 47- R A TrIstitu+, fizicheskoy khlr 1. .  L~14443-66. EWT,(l)/EPF.(U)-2/T-?/ETC 60-6 WW/Dj NR: AP6002970 SOURCE CODE: UR/0286/65/,100/024/0144/0144 INMITOR: Golubev, A. I. 7-5 ORG: none TITLE: A lab)Mi:nth Rump. Class 59, No. 177284 SOURCE, Byulleten' izobreteniy i tovarnykh znakov, no. 24, 1965, 144 TOPIC TAGS: vacuum pump, pump .ABSTRACT: This Author's Certificate introduces a labyrinth pump based on Author's Certificate No. 126748. The device is designed for use as a vacuum pump. Expansion tanks are mounted in the space to be exhausted at the inlet and outlet of the pump. A recirculation tube connects the expansion tank at the outlet with the working cav.  m I 1 and 2 - expansion tanks; 3 - recirculation tube.  -8227 6 JD 7-6 P AC-CNR, --'AT6013,796 Mum CODZ: UR70000/65/000foo f WNW AUTHOR: Ronzhin, H. No., Golubev, A. L ORG: none TITLE: Studies of the passivity of iron, nickel and copper n an alkali medium SOURCE: Korroziy& metallov.i splavov (Corroslon of metals and alloys), no. 2, Moscow, Izd-vo Hetallurgiya, 19650 166-179 TOPIC TAGS: corr 9-ion, Plectrochemistry, iron, nickel, copper, electric potential, sodium hydroxide ABSTRACT: This investigation, performed with the aid of potentiostatic and galvanostatic methods, deals with the anodic behavior of Fe, Ni and Cu in 0-1N and 1N NaOH at 250C, and was carried out with the aim of elucidating the mechanism of dissolution of the intermetellic compounds FeA13, HiAll and CuA'2 (cf. p 59 of this issue). The change in the potential with time was rec6rded by means of an 31-19 o6cillograph. Findingst Three potential delays were observed on the 3-T (potential- time) curve of the reduc the thin, ,lion of the oxidation products of Fe forming under drying film of 1N NaOH)Sblutions The values of thezz delay potentials are in satisfactory agreement with the values of the equilibrium potentials of the reactions: the firlt delay El - -0.790 to -0.810 v --, Fe(OH)3 + 3ezt Fe + 30H ; thesecond delay H - -0.890 v -- Pe(OR)2 + 2ej= Fe + 20C; and the third delay EJ --0.950 to Card 1/2