SCIENTIFIC ABSTRACT SOKOLOV, A.D. - SOKOLOV, A.G.

3/046/60/006/01/26/033 BOOB/BO11 AUTHORS: Sokolov, A. D., -Shur, Ya. S. TITLE: On the Relationship Between Magnetic Properties and Sensitivity of Nickel - Zinc - Perrite Magnetostrictionll Receivers p PERIODICAL: Akusticheskiy zhurnal, 1960, Vol. 6, No. 1, pp. 131-133 'k TEXT: The relation e max '_'90 Is used for the'estimation of sensitivity 8 was experimentally checked on ferrite receivers. e max -peak value of the electromotive force which is induced in the receiver minding under a given sound pressure and with an optimum magnetization; IL - initial magnetic permeability of the receiver material; A 8 - saturatTon magnetostriction; Is - saturation magnetization. Measurements were made on samples in the form of ferrite rings and bars of various composition (Table). The measuTe- ment results are shown in the table and in the figure. The figure shows that the relation mention is almost linear. The deviations may have been Card 1/2  On the Relationship Between Magnetic Properties S/046J60/006/01/26/033 and Sensitivity of Nickel - Zinc - Ferrite B008/BO11 Magnetostriction Receivers partly caused by the fact that the receivers had not exactly the same geo- metrical dimensions. Moreover, measurements of the magnetic characteristics of the material were inaccurate. The results obtained confirm the accuracy of the relation for nickel- and nickel-zinc ferrites. Hence it is possible, on the strength of static magnetic characteristics, to undertake a compara- tive estimation of the sensitivity of nickel-zinc-ferrite receivers. There are 1 figure, 1 table, and 5 references: 4 Soviet and 1 English. ASSOCIATION: Institut fiziki metallov AN SSSR, Sverdlovsk (Institute of Metal Physics AS USSR,_Sverdlovsk) SUBMITTED: November 10, 1958 Card 2/2  S/126/6!/011/005/004/015 0 1 / itY E073/E535 AUTHORS.- Sokolcv~ A~ D. and Shur,, Ya,, S, TITLE,. Influence of Small Additinns of Cobalt on the Hysteresis Loop of' N1ckc-1L-Z-A.nc FerriTes PERIODICALt Fizika metallov 1 metallovedeniye~ 1961, Vol-I! No-5~ pp~68i-685 TEXT.* Various authors have observed that for some magnetically soft farrites the hysteresis loop is rectangular if remagnetization is by mean5 of weak fields. The physical nature of this phenomenon has so far not been clarified, The influence of slight addiiions of cobalt was investxgated~ Nickel-z-inc ferrite specimens of four differing zompositiow with and without cobalt additions were tested. The CoO additions were 0.5, 14 2 and 04 differences in the nickel and zinc contents were slaght. The spectmens were in the shape of rings 37 mm external., 30 mm internal diameter with a height of II Mm., From the same materials bar specimens 4.3 x 4.3 mm and 60 mm long were produced, On the ring specimens the magnetization curves and the hysteresis loops were determined by means of a ballistic Card 113  Influenca. of Small Additions of S/126/61/011/005/004/015 E073/E535 method and.In addition.the dynamic hysteresis loops at 50 c.p.s. were measured on some of the specimens by means of an electron- beam ferrometer, The saturation magnetization was determined on the bar specimens. The ob*,.-ained results indicate that specimens /B, which with slight additions of CoO showed maximum values of B r were higher than these obtained for specimens without CoO but otherwise of equal composit--ons, (B - residual -induction, B - maximum induction). The most reclangular hysteresis loop was obtained for nickel-zinc ferrites with I to 2% CoO; specimens of equal composition containing 0.5% CoO had somewhat lower B_/B values and specimens with 3% CoO additions had still lower- /B values (90 to 92%) were obtained /B values. The highest B B r r for nickel-zinc ferrites with 1 to 2% CoO-, the coercive force of = 1,1-1.3 Oe and for H = 5H , B the respective specimens was H ' . tfie NJLO was of the order of 3700-3800 gauss. Slight changes in and ZnO contents, without any change in the CoO content, led to a /B and the coercive force (B /B = 88.5%, drop in the ratio B . = 0.8 Oe). Some of the specimens were subjectred to thermo- H c magnetic treatment in longitudinal and transverse magnetic fields (at 6209C with slow cooling to room temperature.In the magnetic Card 2/3  Influence of Small Additions of S/126~~1~011/oo5/oo4/015 E073/E535 field,at a rate below 50"C/hcur)., The applied magne-tic field was of 20 Oe, This treatment did not bring about any change in the magnetic propcrties~ The results obtained in measuring the dynamic hysteresis leops were in full agreement with the results obtained under static conditions. Thus, the expertments show that as a result of additions of 1-2% CoO to some nickel-zinc ferrites, the hysteresis loops will become "spontaneously" rectangular, There are 5 figures, 1 table and 6 references? all non-Soviet. The references to English-language publications read as follows., Littmann, M,F,, Electronic Engineering, 1952, 71, 7921 Brown, O,R,., Allers-Schoenberg, E. Electron.ics, 1953.. 26~ 146, ASSOCIATION, Institut fiziki metailov AN SSSR (Institute of Physics of Metals AS USSR) SUBMITTED? December 20, 1960 Card 3/3  T I o 1 k C .1 fw'il 6 ACC NR: AP-606-9-671 (A) SOURCE CODE: Uti/0413/66/oFo/-o64~6C-,,8~6o88-- INVENTOR: Petrov, K. D.; Sokolov A. D.; Kagucheva, Ye. S.; Timofeyev A. V.; Slozhenikina, If. M.; Soldatova, Ye. A. ORG: None TITLE: Preparation of molding material"with novolak resin. Class 39, No. 178978 SOURCE: Izobreteniya, prouVshlennyye obraztsy, tovarnyye znaki, no. 4, 1966, 68 TOPIC TAGS: molding material, a~rv ABSTRACT: An Author Certificate has been issued describing a method using dry roiling for making a molding material from novol k e in and a nitrogen-containing organic compound. To extend the variety of mo in F/masterials with high dielectric properties: ajilivdroformaldf-hyde aii[lino is suggested as the oxygen-containing organic compound. [LD1 SUB CODE: 1l/ SUBM DATE: 14jul62 Card 1/1  0 0 0 0 0 411 9 6 a 0 0 * : 9 0 0 0 1 a 0 0 & 0 " o 4 "o al [* e a a a 1 6 0 6 e 6 6 of a 0 0 03 , . 1 5 , , !I 'I . ti u ks tf A j 11 z? n N is 26 v a 79 N 11 w U I, D k I; if 4, Aj 41 A M A J-1 M 14 F Q I J_ I V T_- AA 10 (X SID (Cjj_A_ I J_ 1 6 00 00 00 00 Polentionietric control of the dtuee of mercerization of th* collWo" g . Ano A 1), S-mm,w~ Zhu,- Khs.111 46(lmul) else da'k J.TI" " " dTtd *0 Irolluirw (itratioll, li%lwtt la'"" -fill 114-11111119 -4 the -'-plipirnent are. ho.. 'Vet. fripured 11"At"I'll that the [at, --f eirculAtinit the &M 00 E liquors III of prlnl;rY itntuirtancr ill %howtvninX tile fractum tinu, The lirrwrit plAot 06 j, le-ixn Amild be improve.1 a% to ndc, if,, Ulkall- V. KALIVIINVSKIl role 00 - 00 j =00 00 00 00 500 00 00 j 00 09 09 '00 0 1 00 F z t: A j a L A -(IALLUPGKIL L.TIN.T49i CLASJIFICATICN 00 07 rl I Ilk L 1 MW .00 R 9 K if t( 9 0 0 0 0 0 . a o s 0 0 0 0 0 a 0 a 0 0 0 0 4 0 0 0 0 0 0 0 0 0 4 9 0 0 a s o 0 0  F7" 0 0 0 * * 0 04"', 1 6 0 0 a 41a 1 1 1 4 1 1 it 14 is 1, it if it a 11 n it M b 36 0 ~11 to It v u M 0 is W 0 IF al at u .1 1, r 0 41111110AA L 2 A_t ti a ~j L a It r v K I I v v -11__j 1 -1 AA 0 IX UP Elio k a t t" I.'& k. 1 1. 1. 0 a &is 0 "6000 1 1 It$ Condensation of fornuddehyde with the terpenes of the oil of Siberian dr. S N .00 USII.AKOV AM) A. 1). SoKoLov. Zkvr. Prilladnol Kkintii .1. 47 t17(l"?).---Horneol, j, earn phane and pinvue'wire'MAted from the oil of Siberian fir and condensed with 11CHO. 11ornyl and i%obornyl chlorides obtained from the friction 1). U51; 62' corldeme with 11CHO in prusence of FcC4 and form black resin-like products which are v-)I. in ~slls and alm(At o,mplctcly 3ol. in rtsO and gasoline. IlCl is evolvrd. Condctrution .09 *0 in p rsencr of lflSOs yields dark brown. rmin-like stitntancessal. in Cff, and practically 00 iMlAnl'*t,0211'1g-1int. Contlen-sation ofl-burnml with HCHO yields- (a) on heating with wrai adds or with small amts- of coned. acids --crm methvirneslycol di-1-txWnyl =00 '-*thcr; (b) on heating with largr amts. of coTcd. acids --oily Nubs-6ncri; (c) in presence zoo of large amts. olcuncd. IUS04 and in the cold-dark resin-like product%. Conden-Ation 0 of the oil or its fracti,avc in prrsl~nce of 11,SO, yields technically valuable pitch" (110% zoo )icld an the 2mt. of oil used) lihich are 3ol. in QH4 and might be utilized as lacquers. 00 v00 V. KALjcnxvsxY 2gee '000 ~000 Ke 0 `4 0 :J: ;Noe 00 fall 1; e00 S..SL~ .[T~LLUROK.L LOTIP.T"( CLAJSIFICATION C Z .010 .10 0 lid, 'J.0. woo *0 fill) a.( a., it, too 'd _3-1 --f-n An I S 0 ad 0 N - I w so I a 4 1 v KX 0 11 It Kit Rst Prffrt jrvjwL3n I x4 dna: 007N 44& 0 0 0 0 a 0 0 9 4 0 0 0 0 0 0 0 0 0 0 0 0 0 0.0 0 0 0 0 0 0 0 4 0 0 0 46 00 goo. 0 0 0 0 0 0 0 a 9 0 0 0 0 0 * 0 0 0 0 9 0 0 0 ail 0 0 4 0 0 0 0 6 0 0 0 0 0 0 0 0 0 W  W W OF W- 016 0 0 0 0 0 0 .9 IV At 11 /1 13 A A A T I 'A to Oc 00 R k 4 L 0 111 P p 00 -00 A new synthetic rosin. neoleikorite. A is, :0 )9j2, N-, 2 4.'34 -The manut. of a phriml aldchy& r,,,at tr-mlK a larKr ex'ct,% I,( C11-1) kdrctil-I If M LFICUSIFO X:: go =go 0, =as !'ZOO go* -lzoo :0 SOO 00 zi coo 41=9 goo 0 Igo 0 tee Igo* I L lT.LLu,.rIC.L LITER"T"t CL-IWIC.M. I It r_j -1r- j -V -a is rt It Is it IF Op 44 IN a Is IS K it oje 0 0 ffe a fig 0 0 0 0  OF o0 00 *4 60 000 0 0 :10 0 6 4 41 0-6w- -141; 0 a 0,Ww 1, JiV is Ps 11 a 21 A, ), V It 14 1 a n f" 0 . A It L L L I n L L 6 b 4 1 T L A' 04 tr M tl W , 11 0 '.. The littindardization of tbo tuAd&mtnt&l metho4s of stu4y Of resins 4nd prewd pZders. k - ., I%- - - 1141-i 1032 N 00 . ;,, ~. . I :;. . ,I '~ '11-nald .. th t atid A It If M . 0a I zoo 0-0 so* OWu see ~ i L A ETALLUVGKAL LM11411,91 CLIIWICITIC- I z boo 1 too .100 0 u TL L. W3 00 000 -0 .0 1*1 ell 0 0 so q o 0 o 0 *jO 0 0 0 0 0 0 0 0 0 4 * 0 0 0 0 00 goo 1. a"., a W* 00 0 004 0 0 0 0 0 e 00 0 0 6 0 0 0 0 9  - - - - - - - - - - I I ;i 1) 11 if 11 14 1? is it i is n a it a is V is 29 ic it U U J4 is 14 It is 39 @a at 12 it As J: 0 AA L D L__1 I l__A ; v A 06 .(X CV_ U4-&- It- iI __L_ _Lalo. , , 0, A I , 00 go Pdl(~Crssts A -t-cl(OlIts ~.(A. The jamiplam of dw cosdilim of coadestalsticat up- the pardeli of soopoestiocal plossitell-aldlehyde resists. A. 1). ra i p anti 0. F. Hold. PiditicAtillikis .1141flei 193J. 1:1 - Sikohiv W,-Clim. zerelf. IOU, 11, :17152; cf. C. J. Is. '090. ;-eq (1379I.-Four puts of 25% sq. Nil, to I(JU ports PhOlf 00 wm used for cood"Imition. With Increasing teltip. W Icondett-Atitm (tk)-wl) the d. and visecisity of tile relisis _00 00 dccrsm~cd. as did the amt. of free MOIL Likewise tile -00 00 Jr, resin yield and the velocity of polymerization increased .00 with the temp.. the drying time dc;~rcased. A Iow con- 0 denwilin twip. is recommended for the production of 0 resin, sit low viscolifity, The Rome effect is obtained by ;I 111 70W 111111 bV 1111, 111 IN) V. of W. A. Slome off ,IV 00 go roe 1 so , g 000 l 00 9 o ~ 0 00 9 o 0 g 0 life* 00 :J: No 00 A It S L A .1TALLURGICAL LITERATURE CLAISIFKITPC. tic% S~, .14, tic'. so-Ow 7_ I't 411131 OPIC, CA - - or W a it R 4 n Y 11 if &1 9 a 0 #A I I V ad 0 so 14 1 Is Is 3 0 1 it rl l 0 0 0 0 0 0 0 0 0 0 0*0 0 0 0 0,0 go 0 0 00 0 0 0 o 0 o 0 41 o ! 0 If o 0 4 0 0 Or 0 0 0 0 0 Ce 0 0 00 0 0 0 foe Off 0 0 0 0 0 41 0  - w 0 i 0 0 0 a q 0 ie lies$ is o mlluliu 1$14 1?18 "AR 1111Didis M17A)# oil Jill Wis MU lips At G A) Ad Org R I L 11 a S_1 A A, M A W U A_ t_t ii-.1 b A k a -D '-, C-Ot-s -t-% ..7 f, Resistaince of phonoll-Willek)kU resitati 41liskoUtes) to Cbes" ageaft. A. 1). NAOkly. MallitAirlille Afalima IM. No. 3. 1 -6; CUMO & lisidisitrie 31, 07. S.--Thr propiertics of synthetic resins depend to a considerable extent an the conditions of Pretim. And suh-equent treat- ; client. Time and temp. of con(fensittion have but little .4111111111 effect on'the chm. r"iqtancr of plicnig-likkhyde resin%. -00 but the choice of condertAnC *Vnt is of great inirwitiance. When an acid condrusint; agrut is ucil. even it it i% mil,~- quently ticutralised with alkali, mninn having is rr[Atively $1, Will, reoivitumv to chrin. nVuls are obtoinvil; their re%i%t. &4o jence Is SlVo ullf4vtWably induclivril by tilt- lifest-tu'r (If air. When the prutiortion tit cutitle-rining iternt dtw% titit ri,md 1 10 ;~. it has but a "lit" Influence on The Chem. rMistance of the resin; above this pruportion, increaw in the anit. of comkilisinjg spot increases the bygToscopicity and dc- so j creases the resistance of the resins to dil. acids. Crrsot 040 rrains have a k)wer rritistance to acids. Dcrtea%r in the 0 Inutioction of CI1,O in thr reaction mixt. c%mitidirtably a** 1 decreases tilt general mLlance of the rrAinz to chrm. 0 1 asents. It is Pelf"fly j-..mlbk to obtain ticid-resuning so linlirble rrsinq. but alm. rrm,ran- to alkalies is y~t to, tw- 0 obtained. A.. Papmelill-Cmiturr 0o z so 0 0 go A%. st A lT.1k V.1K.1 + ~n L r 't Q n i x. 00 00 0 a 0 0 0-0 0 0 0 90 000 0 00 0 0 0 90 0 0 0 0 0 0-0 0 0 *0000*,Ogoooooooooeoooor.0:1:009*00 00000000 0  t w es** 0 * f j " 0 0 s 0 @ o Icil wt) MIS A # V a 41 *Z 'I r A.A A I Al 00 00 9 0 X Pit The Ylicasity J'Wd and N, GTI if 0 A. 11 N 3 -Vj .7.-Ttl ' but uu-t 0 the md"Us 0, ' vOm- roo ' thiN VA ivkr~ high t1jol. wt. -I%Ch M""" rnpds. lit . -dit, h, utd toir m 1w lit I i%'~ c" Atshotl IIIK jwt hill, raph l lc g r 1 40 IV- 01 ill'Ist 111W. OOA bee 41 ago Ues ASS,%LA WAttl1ruKAL LIT91RA14,49 (L&JUOK ATIOll ImIll.. .39,11 aw cw- Lit age I v I 'w 0 11 6 1 If Ill 10 u it A- 93 Ls 1~ ~ 1 patr aw *a 0191 Platt tIMMID 00 o 0 000064 0 00 00 0 'o 0 * * , o * I 0 0 0 0 0 * 0 0 0 0 0 0 a st 0 o st 0 0 0 N 4 0 0 00 0 0  ve" COU-0 0 0 0 0 0 0 0 v $I II tj L. I? I# X zi A 11 11 J, is u v IN P0 a .1 W j 440 A a I r 0 a _W u I !,o coo(.$ P Ilts A%~D (I f, 00 io S S L A 00 U 9 AT 10 W 0 0 i 1 0 0 0 *;* OT 0 0 a 0 0 0 0 04 The effect of the method at PTe"' On sQmcjrOP"~"` 1 1). . Suichrv Monotite, press powder. A. D. So 20v, of plailicheskie ijii 1934. NO. .1 Lml L. 1. AVItICvA- restilts are obtain,-lf if m(Acrule Mr-slate is Unigur livating il"PrOv" the thermal ,,I at 1(u) I t,iWlity of the tesin- .17ALLURCKAL LITERA%RE CL AWFICAT tCh V L S a CW 0 1 IF 4~ 41 VP tv it it CR K It it R SE K a x ri3 n 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 a 4 0 0 0 0 0 0 a 0 0 0 0 0 0 0 0 0 0 0 0 0 4 0 0 0 0 0 0 0 0 0 0 0 0 a see =0 a .00 too 0 0 *"*"a. * 0 0 G~  Is is 11 0 A L a x r 11 A A I A A Ps"J"f6l A 1, V 1 4 1 A I- L AA 0 LL M E 00 00 00 06 Oolite, a new chemically stable ma kajv und jN1. %I. linkliartiev, Main so C so 5, 7 -ld.-Faolilc is vCry %itutur ilaveg, and is prepd. from a PhOll-OW 00 09 06 90 00 06 go o 0 0 0 0 s 11 )1 Aj Is 14 M k I/ is to AD is 41 of 02 f. 0 4 f -00 xial. A. L). ieAse .11tisjut -00 1'rolIctli" 11, 00 .00 -W W WO I L A .11ALLURGIC.1 LITth"TkolsE Cl.iSIP!C11110. t.0 o R t K n K a Is ff it x O~T IV D. d 0 0 0 0 0 0 0 0 0 0 0 0 0 IS, 0 0 0 a * 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 a 0 0 * 00 00 Is 0 0 0 0 0 0 0 0 0 0 IS 0 IS 4 0 1400 0" *' 6" 49 0 0 6 0 0 0 0 of 0 0 * 0 49 40 0 * g  0 0 '1 0 0 0 0 a 0 0 : : : * 6 0 a 0 0 0 0 0 0 0 0 0 & -7 9 0 6 q * * 0 0 0 0 4 0 0000000000000 0 11 U I] U is Is 17 Is id Is is v a 10 J1 12 33 id is ism joy,, of Q4j od's-00 A a L jo'-X-J- L-L--A-A - 1- 9 a IJ- k- I Cc " i . -A a I A 4 71 rwicclit A _0110 jjU.v1- A- -A--.L --- 1--, .'-, 4T. *01 .2% 4.0 -o" Somm q1sipittione In the production of P116001 A. L). Sokoloy, 0. F. Not and N. V. Grigur'C'M 1Ga',,-d: 8 7 Pro.. S. S. ~. R'. Nduch.- .06 so -tr' Ill Mass.. Plujitchesk. -00 0 Massy. Sb(,rmik 2. 179 wt 1937).-The pllewn- Of Mcoll 0 LJOWS tile tvildrnAa Wit 'it 111soll and Cilio with Rlk- -00 stalysts. As IrM1ltvl'l%'ICllVAtillU WAX-Mil" tilt 'I" Sr' of tile tealn layer alld tile 14's W Its vilwmity incteaw Ill- -00 rectl)r with timc. j,he 141ttrr is the be.,bt plupertY 14tr 600 following the rvaction. It. M. Leicester 800 Zoo 00z 0 2 .0.# 'coo zoo aroo too �r A S S L -11ALLURGICAL LITERAtIARE CLASUPKATION tug 0 S..0.0 0 U N AT 10 IT tv rl' Is or 4 Is It it N K CE it It x n I To Aa 3 1 1 dn io o 0 0 o 0 o o o 0 6 o a 0 0 049, 41 * o o 0 o 0i i4*6400000009009 0 0 Of 0 0 0 0 0 0 o o o o &I  4-9-0-41-6 41106-6 0 00 0 0 0 *so Oro it 1-&--L A_H. r U M CLI CE OSA a** see 00 000000 "a IV 4 A ___lL_j A, 00 .00 Ti -00 .00 Di- and tri-s"tion ospilialva. Ya. M. ShinclikI,ir Awl J ! . A. 1). SkAtilov. Russ. M,=. Nuv. 30. 103R. Sujwt. zoo Willi N&wS4)4. The Nalf.PO4 (tionini Ifeat"I Willi Ca(011), and filtered. Na.P0. 00 j it,,. IIse filtrate. Thi, trAiltic Imatcd With Nalf'ro. And 111tel"I yidda N1411lkh, 7Lee SO, see nee fee tse "ZI nee SETALLUNGICAL 1.111MAN-41 CLAISIFKA11ION it a - .1# C~v l( 411131(ml QmV All Z U AV 00 is V ZA ~ 0 ns An A I it fid 0 0 a I w a 0 a 3 a V 1*1 414 In AS S, a, f't III i o C n I  1W W- IF as W W W-W-4V 104 to a' 0 0 * ;; ;4: : W a & 0 A 11, " " " J4 i D .3 26 37 N J% X, 11 V at U D 1, L C L_ I Q ZI ~ _X L M r QR I _L. V AA Pit Cc W it d The stability of phenolic plastics. U. The Water. .qW Carl, hUMkitty ib"r it an equil. at which no vilanst-I 00, resistance of Articles made from nitImbig Pe do - 44~jatbc size or wt. take PLWe. The higher the Initial tTw6t%lrc .1). Fnikoh,V. A V. Kim AM N. S. Zarubina. PlailizZlist ,njnt of the r~wdej, the greater the humidity of the air t4rTy. Mkwaji .51alef 1939. 141 ity selecting the initial mt . lure content of -5; cf. C. A. 33, 3rJ48, at the equil. -A% All itnixrted sa nplm of phenolk resins reached the powder it is posqJI)le to prolluce articles that do MA their liallit *If "WrIling in water after 15-24 roonth% after change ill wt. aml size at humidities to which the object which their wt. and size remained unchanged. The in. i, SVbiected. The sutf4ce resistance is Rix ohms I or goo rease in wt. was from ".5% and the ckagation 1-2%. %aulple in air said. with water vapor. and 1011-ppi ohms The wini-Iry and dry methods cannot be used for the pro. fivaaiiipleinaltsoltitelyifrypir. IV. TbadketakW92- 001" fluct i"ll 14 tile article"- I'(Vwdrr"Pl`ePd-bYI4c(lUvf bility of resites prepared with diffenst proporLI-a of 0 0 still eutul,ion surthods were nuKt mistant to water. 1i%- ph aal and fonxitiddthyde. A. D. !46kcAov anti N. S. C11,111 tcllili% weir obtained Ili tuillhig noviAlte still r"il Z~qj jjljijj~ . 11-jJ. 167 83-Reshis prejul. Inim 4. '1. M. resins (tile limit of swelling and the elongation wcfc 6.5 it) And 12 no-6. 'If 11010 1., .5 111,4S. If I'lloll It cr"4 Smonth..). Anningnitrocellulti..c and I. It" re'll , after it were t"ted [or resista"ce at rCX)l1l lCulp. to IAW~ 00 FI) tn.m- and ru,t F. I 111A, ICI lo7~ xa,Col. 5% Naoll, ;ater anti 00 J. Wil. ~Wrlls lite lca-l (O~M%J. Ill. The be. :,()If. -1,11, 1,11,ilitv .[ it,, IVSile, I, different ill dlff'r~lvt haviof ol articles from molding powders (phenolic pUa. Rr%ilr,,Aj~ lit4olv t-i-tant I-) Acill (11411 Ale 11-Ml- tics I In air of various humidities. I'llclk,jj., 1_11_ Al.. ll'.Hr Acjj j-j,IAjtj II.All 00 ZarullinA. 1kid. 15:1 07-71lie samples swOlrd faster tit tile cFe.j.- -st- Ci-ltn- t-41- are M '101.1c water titan in -nci6t air. The limit if swelling was approx. it) the action of water and Xa,CO. ~An,. )0- in 1-(h vasr~. The increase in site was 1.0-1.5%. wish c%cr,-. ItCHO (ill S%Llticular tile novotac mass with -ni~ccr I, a.14nite limit rdsvic1ling still drying for each 110- :!o% utotrolsine) hall In.&%. r"ixtAuce to alkali And Ak,. Iir~ (if buttildity. At 0 FA)% humidities the mail. swelling 64 If ~ije,, anti JUIVOJAC m4.11" Prctd- with an instiffiLient 1,1 0 W,71 t 11' X4.6). -hrrv It' i, the rrlatiV~ lmmiditv. uudcr the action of it. 11 IICIIO 1100109*4101 t&l)i'IIY fee ikk-, The ratio of tile col"Pouclit. ILA. no carct oil tile Ie. ~istatwe of erc-slic r-itm to ale. Acid. bad -cry littic el- feet on pbenWic reites (foil, APProx. equitn(A. Bea': of tile componclit~. rhrough Kkim. Rtferal. FAV liz. 046 No. 3, 105-7. W .R. Henn 0 1 -00 -09 - 0 0 ~-oo i 1,; Of 00 !:1=00 -1 ;;Oo ~Jo zoo S 00 It -T r it' Ill A 1 41 %A Q I W 9. ZV It a Is K It qq Vt Itats uCq Lon IX. 'no o 0 09010 o 000 o00 00 0 0 0 0 00 0i 49 41 000 0000000 00 00 0 0 0!  WE WIN! W-W W-6-W 0 W-VF-6-4vV--_- 09 go 1. RM-11"W11-11.11TI I, I I I 0u ou on .0 o" 0u 4~) 0!!o A it I T V 1 1-1-1 1 4A 64 M UP tt t 0 Chemkny Wablo re" Tarnigheg -00 Agntileva and V. A. Anan- ~'[' 1039. KA rva. 1 2 010 Im. Rfe,,j Z aj ftjjly' fxl" iu -Achin. 01.30~, of k&GUn ( .- 1%0- 4 -00 ces %-arni-sh., that a", I., . 0 iqllld re I 'p V4 00 Al Toule e tic And ~o rc3j P - reswi, in well W nd 00 (diethy ill( be added, beld, .,in, a,;: Is. of :to,y ,Italy, plj~phllje 1" -06 e of file t" ty Of tl, If The ch,ill. ' unlitt'ra'.1'r Vxmist Y. (.tkkl chrilli- 'I'led Ir% resol or lichyll 'r" tolm phellul d llltrrx ' . r napbtb,h,n,,_ "", he adhesive r r rmi,: And 1114j," A the ""Ill Of 14 le-litallf jw)"~ 1. l"erl. by Illisille . . 11' (3 -5 09 NX) part., of m! Cl and W'. Wit 3o ka. 11. of iffloll 00 v fill And is ^00 ""Ved ill blIlen,. naphillid.n. lle.n ij ASSI-SLA ETALLURGKAL Lill NATURE CLASIIFKATION :*0 100 s o Al 10 11 N o I ill im .3 Aj a b u C, 1, 1, op a K n I[ U C it rg It X to n I .T.4  -I _R i 11 1-0 of- i- i gv A L A L I ~-f. r 4 VP I. to V a,, A. T -01. a, the Previeffin ani Cr idifions for Oro 00-1 dW rings". A, I)_bk*Wvj-. S, I Knillova and A. V. Knitter. Pkiff'40"Alf" .11,111Y. N&,Pxtk %4-ski oo~ 13 1939, 191 -INA3. Khem. okfjttraf. 1hoor. 1940. N.,. :1. Its-- I1CII0 &R%I 141011 Ill the fstitv~ 2.1 tilll,!% I(Niandbi IIIII WrIc colldclord, with if.:;% IICI tit. 1.19).4 file *I. ut 00 PhOllascatalym. 'the 1W(alucts were dried in a Cu kettle 00 4, with a mixrr ond it# a I &%k with A mixer. (tit an itil loath liesird to 171) No'. Water ma, rvnkj%,,d at 99- 14W. and 0 file lemp, of life t,~ni flock kk-tea-l gradually to, (he oe 1. I*Isr "lint4i tifitiPping It fill)." InCreWA-1 go.- %1111 Ilk frjj~W lot IICII0 V011it-111. fly %1011414111 lityllid. A Jorge j " ndard torlooluct vall IC .14.41fortl without all.tIvAills ant. = 00 p1tarift Ilk- rmin. but (only by contretiling the Irsup. during 00 96"' efir drying lprtwv%,. ()Jx-it drying rribur% the unit. of frev 1`96 plivind W ll.*-":,. Ily dryinj ,~ in I he IIA,k I h, virld 41 he 00 -ill call be I'l'ought 1.1 111101". Vol I.,oor-1114.1. rc,in, (with 1~ aitt,, 24 Ilk) aml '-'ti 101) ilivre i, A dirt% I Imcar rulAtion goo twe formn lhr 9 tol I hv!ii1% 21e. wAn. and the dropping temp. 4 file 1-181, fliefrossing file unit. ( IICIiO iintra". 400 00 1 Dectess~votilteperevnisar 290o ill lice Phe"(11 111111119 (40CH 'flying 14 flirleflY rlr(Pmtilxlvl to the increlf,,or of the dropping temp. At equal dropping temps. a larger content of phenol is found in resins pgvpd. With large Am,%. of 11C110. IL he dropping letilp. incream, during the drying in the iUA, but life content of firer See pherkol remains unchanged. For ficig. thrmiltruing fenip. goo tit r"in, optimum oresults in ~pred. conolvenictice and ar- curacy are obtained by a unodified Ubbirlohdo: method. too W. R. 11cull ties S L a at TALLURCICAL LITINATIONE CLASSWICATION M04P Ate. too .1, .3", 13-1 1114111a"t 431131 ow Clot" Ill 0 IV IP or a IN a It 2 Kan 11:141an I 00 00  ij U IS is If is If JO I It 22 D 24 IS 1, H A .1 JU 11 11 D M b k 11 a .1 Q 4. 1$ L a 1 U Y M Of CC M it L- -A 00 00 -00 00 N e. transparent intIlding nmte,rW. A. V. I 06 N ~ S. Zaruhina - I Pq. Chrm. Imid. (U. S. S. R. ~ 7. =S ;I I 00 W40~. -11hem,14minablobvilt- r-irr, withom fill,r, -ill% 1-- 11-1 G- PrcIIK. 'ICA' ITI-1111illi: RIMIrtIA!, 14 %Ill- III"- r-tic lytx-. It wa, "tabh,hed that rt-I Immict, 14 00 hiKh llow prilmdutv art"v% with low mech pr%,Iwtih~ -00 SAti,factory mech. jlrojlvrti,~ are obtainC,I liv pre,stig A 0 9o ir alwmt 3 min. For each mm. thickrims. IA)WCT pre-mic 0 111.. rt-,1311, it, tetiticeri itim, sircrixth. ~rh, tis-h. 1 0 migill c.111 L11.1 Ile 111111lovell 11Y 4111.1111. 1I.-alilig dill ; 00 j l". -ill,; ,, I-V f-1.1villit the I ... ~Ioulv lit Ow J-d" W1111 ii.-IoLic t-irr, it i~ I-ildr ill twbtam high im, h, lit eimili 0 .1111 fk,wdvf~ hAvillic a Ru~hix flow If ,v,-r IS11 mm 0 *0 j i little 41"Illd be ", mill. bor rich ti]ill. ,f Illicklic" 00 i,I 4,1min gimmi mcch. strength and I -I..! min. prr mm. I,v 4114'4111 0 Kim"I MIFUCC, MCCII, %IrvIl9th III- I'll' Valtv %*0 00 %ith ixwrc;&,vtI lit-mirs little vr with aildni. licalitik alict ; 00 I'll-ing. Specivitens pfrixi. with lit", turuiropine %howrd It, tx-,t I rch. progwrtim. I'hc rxpt~. are ill Ile v%irtul"I 1 .0 0 00 mi ;kit indu%trial cale. K211lich 0 0 4~ 00 1 Z All. SL METALLURGICAL LIT14ATLAE CLAVIAPICAUCH et as - 00 to., ad 13.y Lt. UISAVIO l r OW69 an R91 I a 11 0l Od 0 1 ill 0 so #14 7 it ,Pit 0 0 0 0 0 0 0 0 0 0 0 4 0 0 0 6 0 0 0 0 0 0 0 0 0 0 0 0 0 ~0 0 0 0 0 0 a 0 0 0 * 0 0 * 0 0 0 40 0 0 0 0 0 0 0 0 0 0 0-0 , 0 0 0 41 0 0 0;  006 I I I it it 61 w is 16 it 111 19 I t n 1, 36 Is ft 11 11 u 11 M Is is I/ Is it 49 u it 64 46 A, A -L-fL-L X 9 A I I It V-A Pp u 1A g J.- I V j$Stj A.0 .31 f A 1- 00 0 Chemical stability of phenolic plastics. t. 1). 00 ati-I N. S. zarxibina. Ort, Chr., /NJ I V - S. -00 tow); cf. r. A. 35. 37311.--Tr,t~ wrte mAde mi -00 00 a the t2bility ol trxioble in watri and Avarn. in Tc%t- -00 00 lice jwcrml. frwu PhOll dcriwd ft,mt Iva( %a, i-ted &it t,%)m triul). utdv. The rvAtill-W nof agrVe With Im-1311111- go .3 ;, in. The TrNult, '111)w that the i, completely :11 i r ,tmyrd n Oon"I. IICI at or-litury witip. wbilr at .41" it i, un.ible to r"i,l even dilil. 0 9 mas Iv 11-d with %ullicierit reliability for definite "C411 15 in dif acidi at rrx)tn temp. It niav A- 1w tiwd in watrt gou arid ~traiin at rmim fernp. and at NJ'. It. Z. K. 2 goo 10 is* 0 so* jL,,s.ILA 11TALLUMMAL LITERAILFRE CLASSWKATION is] , . . - - j - A* to ks , , ; 11 rD u 10 Pr - - I, - - . . . J . a - It I 0 0 0 000 40 00 0 00 o .0 0 A9 0 4 10 0 g 0 q 0 0 0 0 0 0 4 0 0 0 0 0 0 0 0 0 0 JS 0 0 0 0 0 0 0 4 0 13400 moo are* goo  10 it t: I) w 16 17 is it 'v ]a ZI zi 24 n 26 z? a m ij It m Ii is b At v A &I u &I a a A A C A L -1 f. F It I I Ij 1 -1 u 00 4Z 90 El 3 1 . lisastics research. A. 11 S'Ll'It"'. 1)tc ltlvlel~ W161 ~c-'OIIIINII 1, witt m III, fl'O lit Ill"Ilt-NI41~11441, lit 1411-14. : :0 J! zoo A 0 04 11 1 1 1 Zt 'N. it. i jjb u 1 a (W 0 it 9 1 N l KX -3 All 4 3 It hit %6( fAit %91 Ktttt jtfq i4j3A 1-%% sna 0 0 0 0 0 0 0 0 0 * & 0 * * 0 0 * * 0 # 0 0 0 0 0 4 * 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 a 0 0 0 0 0 a 0 0 0 0 0 0 9 0,0 4 * 0 0 0 0 0 0 0 0 0 * 0 0 0 0 q 0  SOKOLOV, A. D. The chemical stabilityof Y. d.ff ere n t be ha vior of rrsi 5-~ -M acLuTTnvi --, tl; D Sokolov N -9. Af Itra )Life"-. 109 940 .-Resuis prepd. from .1 111ol'. of 1,114M and 10 moN. and (3 vuok.. OURIM ;~ui, 75 and gtll,,' 11'',0 10, 11C1. Af Q'I oF conclas. an, wa;v',".-'-The vAns "A -"- nango I'll -~' ;. III 2()--307a 11C1, in 2-5-50c,", In 70' 'e 'No change in wt. %vaq obierved it, with :30 CaCl qoln nor expo~cd to air c~ntg. 621-70("' n1a !. lese equii. poinu Could b( 511;f1c'! i,'- treatuient to the rrFi0TI ~f MOI-C CO-Ird. aCi. a:1 addn. of watcr to more dil. acils. treatment of resins decreazed the r,,, phCil jo reshis and iocreaseii the water content. formation of resiris wa5 iccompanied with !z(Tri. of %-,It" (polycondensation). The behavior of "sins in acidi and 'CaC12 was conditioned by the watu vapor 1-~rc~;snrv wer '.these solns. Thus, resins in solans. r,,- high v:-,,,-Ic,-. pr~~V'I!r" :Swelled; in soltis. of low vapor presmc, they lost. i~ f~  SOKOLOV.A.D.; SIIAPIRO,L.Ya. Use of infrared rays in the plastics industry. Khim.D-rom.no.1:21- 23 Jat47. (MLR.A 8:12) 1. Nachallnik nauchno-isBledovatellakoy laboratorii Zavod "Karbolito (for Sokolov). 2. Rukovoditel' grupp ,y laboratorii Zavod "Karbolit" (for Shapiro) (Plastics) (Infrared rays--Industrial applications)  o q-m,, jo A=4v=qvj 'Pu'9 RO-19"ea QR~ -:p -po%on-puoo oxoA squmnwdxa * somT,.~ 0?,-QT- -agagRo o,&T,4du.n;-p oqq. ooovoxouT 9uT-r-Eoa-Lrp A uoT,4*avd*Jd% *.wq.emTTITm jed A3( -C cx~ du sew eo-49oq9--a eVCqaplv -'EOUoqd eTcLvm-p ;o aglauqo ojLTqdru9Tp Gql.~ GOWAGUT OTAI-OWEI %OT-14vrnsul J-16T doS 0!:~ elqTogod mT 4T v4sq!~ 90,41ng eolsoqov 9wT jo 0m M-Aq IW64Z40 OPM 'A4TTTqv,=P MOT Z"A VW .pmVojd,ftT.4rw*.x 'oq'4 4VR'4- PQAO'EES ffMastpa so"aqov~ jo quTgg9jj laq 4j 41M a aEvTfeq~w V0990-TI -rLJPLq=-TOuQqd UT suft 00"eqOv tMTA POTWOOMIX; oTqsvrd jo eon pz;j: ejU 6 obi uT-,4sottaaj*q9AwAE O-ZINQ-rq 39U'490A. Ov if dd r, gvuT.IqW oc, 92 sAOTo STUT"14.1K sopoqoV possaia elqvuq jo sQTj-wdo-7Z ftT' OT 4.vrnsu .1pola sqq. SuT.&ojdml,p 91ft, 00,4.QKOV L*61 droS 6uDj;,4vrnquj 0 to  NOVIKOV, D.P.; SOKOLOV, A.D. - Scientific and technical conference on plastic materials held in Stockholm. Klaim.nauka i prom. 2 no.5:642-643 '57. (MIRA 10:12) (Stockholm-Plastics--Congresses)  S11911601000100310131013 B016/3054 AUTHORS: Militskova, Ye. A., Grinevich, K. P., Sokolov, A..D., Zyabkin. A. P. TITLE: Liquid Organosilicon Polymers Used as Lubricants for Molds in Casting and Molding of Thermoplastics PERIODICAL: Plasticheskiye massy, 1960, No. 3, PP. 72 - 73 TEXT: The authors report on their experiments concerning the use of liquid organosilicon polymers to lubricate molds for thermoplastics. They used liquids No-3, No-5,fi (5L), and rKX -94 (GKZh-94) (poly-thyl siloxane), as well as three po*lymethyl-siloxane liquids (No~t -3) of different viscosities. These liquids were used as lubricants in proc- essing colorless and filled polystyreney caproney polymethyl etrols, methacrylate, and copolymers of methyl methacrylate with styrene. No-5 and GKZh were manually applied to the molds. The latter liquid yielded better results: After a single treatment, it was possible to cast 25-60 pieces of different materials in the mold. No.3 and the polymethyl- siloxane liquids were sprayed onto the molds. An admixture of easily Card 1/2  s/igi/60/000/004/009/015 B016/13058 AUTHORS: Yezhkova, V. S., Militskova, Ye. A., Sokolov, A. D_._ ----------- TITLE: Application of organic Glass in Illumination Engineering and of Other Materials for the Production of Illumination Devices PERIODICAL.- Plasticheskiye massy, 1960, No- 4, PP. 42-45 TEXT: The authors describe plastic light diffusers of various designs and shapes, as well as colored signal glasses and lamps. They mention the production processes used and discuss in detail the application of organic glass in illumination engineerings Addition of low-.molecular polystyrene (molecular weight: 10,000 - 18,000) is recommended for obtaining a uniformly semitransparent opal glass. The manufacturing method of this polystyrene was elaborated at the central laboratory of the Kuskovskiy khimicheskiy zavod (Kuskovo Chemical Plant). A glass of this type with cross-linked structure and increased heat resistance was developed at the "Karbolit" Plant. The thermosetting paste for its manufacture was develop- ed at the HVI"FlTr (Scientific Research Institute of Plastic Products) from Card 1/2  87878 I t)'r 9/191/60/000/10,05/003/020 BOOA/B064 AUTHORS: Militskova, Ye. A., Sokolov, A, D, TITLE: A New Heat-resistant Casting Material on the Basis rf Acetobutyrate Cellulose and Polymethyl Acrylate PERTODTCAL: Plasticheskiye massy, 1960, No~~ 5, pp. 6 - 9 TEXT: The authors aimed at producing casting material from acet-%bu~yrate cellulose and acryl polymers of increased heat resistance. In the int--c-- duction, papers are mentioned on the copolymerization of sellullosE- esters with other polymers. In 1958, the Leningradski-y NIIPP (Leningrad Scientific Research Institute of Plastic Products) produced a new material of aceto- butyrate cellulose and nitrile rubber which was nontransparent. Z.A.Rogovin and A. A. Berlin worked in the same direction, Thin-walled acetyl cellullose etherol products of the 2AT-43 (2-DT-45) type were heat -resis tant only up to 70 - 800C. The authors used acetobutyrate cellulose of the Vladimirskiy khimicheskiy zavod (Vladimir Chemical Plant) esterified to 58 - 44 % by butyric acid, and combined it by means of extrusion with 6, 12~ 20, 30, 40 % by weight of acryl polymers- The combination with polybutyl metha~ry- Card 1/2  87878 A New Heat-resistant Casting Material on the S/191/60/000/005/0031/0"O' Basis of Acetobutyrate Cellulose and Poly- B004/BO64 methyl Acrylate late did not meet the demands so that further studies were restricted to the vitreous product from acetobutyrate cellulose and polymethyl acrylate The resulting materials )~-12A (ETs-.!2A), )~-2oA (Ks-20A), and ),A-50A (ETs-30A) were of high strength, high heat resistanop, and high stabd'P-y 4-c gasoline and other substances. Automobile parts (headlamp glasse3. t steering wheels) produced from ETs-20A were stable at IAO _ -1700C_ Combined polymers MMA (mmA), MA (,,AA), and 15M (BM) with worse properties were produced by means of suspension polymerization in the presence cf isobutyric acid dinitrile from acetobutyrate ~~ellulose and copolymers from acrylic acid esters and methyl methacrylate. There are 3 figi-I-res" 2 tables, and 2 Soviet references. Card 2/2  S/1 91/60/00o B004/B064 AUTHORS: Tsipes, L. Ya., Sokolov, A. D., Kochanova, M. KLyakina, Z..N. TITLE: Molding of Products From Novolak Mold-inE Material PERIODICAL: Plasticheskiye massy, 1960, No, 5, pp~ 67-69 TEXT: It is the aim of the present paper to raise the efficiency of Dres- ses by increasing the molding temperature for the production of materials from novolak molding powders of the K-15-2 (K-115-2), K-17-2 (K-117-2), K-20-2 (K-20-2), K-119-2 (K-119-2), and K-118-2 (K-118-2) types. The labo-- ratory of the zavod "Karbolit" ("Karbolit" Plant) developed JIr 1938-1939 a procedure to render molding possible at 175 - 1850C with the molding material being preheated. Experiments with material preheated in a high- frequency field to 100 - 1100C showed that the product No. 3388/1 (safety cartridge), 46 mm high, wall thickness 6 mm, can be molded at 20c5 - 2150C, and the product No. 3388/2 (incandescent lamp socket) 28 mm high, wall thickness 4 mm, can be molded at 21r, - 2300C. Thus, the time of molding was reduced without any change in strength, heat resistance, and water ad- sorption. M. G. Gurariy is mentioned. There are c,; tables and 6 reference5: 5 Soviet and 1 British. Card 1/1  FEDOROV, S. V. ; SOKOLOV, A. D. ; SHCIMM3AKOV, N - S. Instrument for determining the content of magnetic inclusions in nonmagnetic materials. (Magnetic analyzer of the U-1 type). Plast. massy no.8:63-64 160. (MML 13:10) (Mat er ials--Analys is) OWgnetic materials)  PANOVA, N.M.;,_ SOKOWV, A.D.; TIMOFEM, A.V.; FEDOROV, S.V. Effect of the quality of mummy on the dielectric strength of molding powders. Plast. masay no.12:62-64 160. (KIRA 13:12) (Plastics--XLectric properties) (Pigments)  SOFOIN, A.D.; 14ILHAYLOVA, T.N.; TIMOHYEV, A.V.; YAKOBSONI, B.V. Factors affecting the hardening of novolac molding powders. Plast, massy no.10:22-24 '61. (MIRA 15:1) (Plastics--Molding)  Z'llect of die casting pressure between 100 the amorphous phase in rate of the melt; this There are 1 fi.-ure and S/1 91 /62/000/0C,7/01 0/011 oonditions ... B124/B144 2 and 200 k-/'cm is recommended. The fraction of 0 polyethylene increases with increasing cooling raises also the frost resistance of the pr~oduct. 1 table. Card 2/2  S/1 91 /62/000/011 /004/019 Bloi/3186 AUTHORS: 11.1ilitskova, Ye. A., Sokolov, A. D., Yezhko,~a, Ye. S. TITLE: IMolding materials based on polyester acrylates PERIODICAL: Plasticheskiye massy, no. 11, 1962, 10-12 TEXT: Mloldin- materials TMVI-11 (T11GF-11),.Mr_1-9 (11AGF-9), and MO-2 (?ADP-2) polyester acrylates and powder fillers (quartz powder, tale, chalk, wood dust, etc.) are reported upon. Glass fiber used as a filler (diameter 7.3 v, tensile strength 262 g, length 1-5-2 cm) was made water- repellent with Velan or with the preparation 246H (246 N). A paste of benzoyl peroxide and dibutyl Dhthalate 1:1 (2 parts by weight per 100 parts of polyester) was used as catalyst. The rate of curing and the mechanical, thermal, and electrical properties wer6 tested. 1. Results: (1) Molding materials containing quartz powder, talc, or fluorite as fillers needed to be worked at once, whereas materials filled with wood dust or glass fiber remained workable for 6 months. (2) materials based on TNIGF-11 with a powder filler were heat-resistant to 200 OC but had an impact strength of only 4.2-4.4 kg-cm1cm2. Materials based on MCF-9 or Card 1/2  S/191/62/000/011/004/019 Molding materials based on B101/Bla6 MDF-2 with a powder filler showed an impact0strength of 10.3-14.5 kg*cm/cm2 but a Martens heat resistance of Only 44-54 C. (3) Molding material based on V4GF-11 and filled with ~la-s fiber was heat-resistant to 2000C and its hardness was 24-5 kg/mM2; but it was not as strong, as the other two molding materials. IIAGF-9 or 31ADF-2 filled with glass fiber gave a heat resistance of 45-800C and their impact strength was increased to 100 kg.cm/CM2 by using hydrophobic glass fiber. (4) For TIAGF-11 materials, the rate of curing an& the shear strength were slightly higher than for 'AGF-9 and IADF-2 materials. Vlood dust reduced the shear strength, glass fiber raised it. (5) Increase of the molding temperature from 150 to 1700C, and of the benzoyl peroxide admixture from 0.1 to 1.0. accelerated hardening, which was virtually finished within 1.5-2 min for IADF-2 material. (6) Only glass-fiber filled products withstood the break volta-e shock test at -500C for 3 hrs, at room temperature for 2 hra, and at 1300C for 2 hrs. (7) The breakdown voltage was 20-25 kv/mm for all products investigated. The most suitable of these materials was pressed into parts for use in the automazive industry (distributor caps) at 130-1350C, a pressure of 60 kg/CM2 and a molding time Of 4-5 min. There are 2 figures. Card 2/2  q/ 1 9716XI,666/00 31019102 2 1; , of ~ AUTHORS: Taipes, L. Ya., Sokolov, A. D., Mellnikovs Yu.- 1. TITLE't Efrect of pressure on the strength properties of standard samples made of phenol molding powders PEI?1OVICAL: Plastlc4skiye masey, no. 3, 19639 65 - 60 T -V~'X T :The problem of transmitting pressure to the molded material and itf influencE on the strength properties are discussed. The effective pressure measured by wire strain gages and its influence was studied. A test series in a plunger mold using pressed K-15-2 (K-15-2)9 K-17-2(K-17-2)t K-10-2 (K-18-2), and )