SCIENTIFIC ABSTRACT SHORIN, K.N. - SHORIN, V.A.

SHORINY K.N. Method of controlled motion of a particle beam in an accelerator. Prib. i tuekh. eksp. 9 no.4:25-27 J1-Ag 164. (MIRA 17:12) 1. Fizicheskiy institut AN SSSR.   L 382o6_66 EWT(m) IJP(c) ACC NR, AP6022029 SOURCE CODE: UR/0120/66/000/003/0190/0192* AUTHOR: Artemlyeva, Z. L.; Shorin, K. N. A ORG: Institute of Physics, All SSSR, Moscow (Fizicheskiy institut AN SSSR) TITLE: Method for enhancing the efficiency of magnetic shielding SOURCE: Pribory i tekhnika eksperimenta, no. 3, 1966, 190-192 P TOPIC TkGS:.-magnetic shiQldi-T ig hyWteresisTbnn electron accelerator ABSTRACT: The results 'e reported of an investigation of shielding the accelerator tube from the Earth magnetic field by hYsteresisless soft-steel torus-rings. In a model study, 10 rings of 260 mm diameter had a shielding .Lactor of 1.65-2.0 when the constant field was held within 0.4-3.5 oe; when a strong damping-amplitude a-c field was added (the hysteresisless magnetization), the shielding factor increased to 20-14. In the experiment; a 2.2-m long accelerating tube with an initial electron energy of 5-8 kev and final energy of 600 kev was shielded by the steel rings which reduced the transverse Earth- magnetism component of 0.45 oe down to 0.02 0e (except for the edges where the field was 0.1 oe). Orig. art. has: 3 figures. (031 0 9 SUB CODE: 09 SUB11 DATE: 10Xar65 / ORIG REF: OOY ATED PRESS:L5' 0 1  2 5,'~ ') - - I. ~ T7' 7' a - ..-* ~no I i er-, -, -affel Inaya sv-~-rka st-d ln-,,r~---h provodov Voen. sv:jazi st, 19,18, 1 T .;o. 7, s. 4?-45. S) : I otlo.rdst Zhurnal Stuntey, No. .10, '-Loscour, l-,)48  BREYTBART, A.Ya., redaktor; SHORIN, N.A., redaktor; URAWVA, A.N., tekhnicheskiy redaktor"'---' [Electronic time measurements. Translation for the Nnglish] Lampovye ekhemy dlia 12mereniia vremeni. Perevod a angliisko- go. Fbd red. A.IA.Breitbarta. Xoskva, lzd-vo *Sovetskoe radio.0 Vol. 1. 1951. 287 P. (MIRA 8:2) 1. Massachusetts Institute of Technology.. -Radiation Laboratory. (Time measurements) (Electronic apparatus and appliances)  IBUNIMOVICH, Y.I.; SUORIN, N.A., redaktor; URAZOVA, A.N., tekhnicheskiy Teiaktor. --- - [Fluctuation processes in radio receivers] Fliuktuatsionnye protsessy v radlopriemnykh ustroistvakh. Moskva, Izd-vo "Sovetskoe radlo,f 1951. 360 p. [Microfilml (MUM 7 - 12 ) (Radio--Receivers and reception) (Electron tube circuits)  VAYNSHTEYN, L.A.; SHORIN, N.A., reduktor; URAZOVA, A.K., tekhnicheskiy redaktor [Diffraction of electromagnetic and sound waves at the open and of a wave guide] Diffraktaiia elektromagnitrqkh i zvukov7kh voln na otkrytom kontse volnovoda. Moskva, Izd-vo "Sovetskoe radio," 1953. 203 p. [Microfilm] (MLRA 7:10) (Electric waves) (Sound waves)  SIVERS, A.P.; MIORIN. N.A., redaktor; URAZOVA, A.N., tekhnicheskiy red,aktor. -- -- -- [Radar. calculation and planning] Radiolokatsionny'a priamniki; raschet i proektirovanie. 2 izd. Moakva, Izd-vo *:Sovetakoe ra- dio.6 1953. 359 P. (MLU 7:8) (Radar)  NAUMINKO, Ye.D., redaktor; SHORIN, Njk., redaktor; KORUZXV, N.H., takh- nichaskly redaktor. [Raflax klystrons. Translated from the English] Otrazhatellnve klistrony. PareTod a angliiskogo.-Moakvi. Izd-vo *Sovetskoe radio." 1954. 251 p. (MLEA 8:2) (Amplifiers, Electron-tube)  DAVTDOV, Grigoriy Borisovich; TAFT, V.A., otv.red.; SHDRIN. N.A., red.; KARABILOVA, S.F., tekhn.red. I [Fundamentals of the theory and analysis of phase-correcting circuits] Osnovy teorii i rascheta fazokorrektiruiushchikh tsepei. Moskva, Gos. izd-vo lit-ry po voprosar sviazi i radio, 1958. 292 P. (MIRA 11:12) (Electric networks)  IS H 0 t~j N' N - f), YEMEL'YANOV, V.S., otv.red.; BARDIII, I.P., red.; VINOGRADOV, A.P., red.; GOLIDANSKIY, V.I., red.; GULYAKIN, I.Y., red.; WLIN, P.I., red.; Y9F1Ufl4DV, D.V., red.; KRASIU, A.K., red.; LEBEDIIISKIY, A.V., red.; MINTS, A.L., red.; 140111, A.N.. red.; NIZE, V.E., red.; HOVIKOV, I.I., red.; SEHOOV, V.F., red.; SOBOLEV, I.N., red.; BAKBAROVSKIY, G.Ya.; nauchn" red.; BERKOVICH, D.M., nauchnyy red.; DANOVSKIY, N.F., nauchnyy red.; DELONE, N.N., nauchny-y red.; KON, M.A., nauchW red.; KOPYLOV, V.N., nauchnyy red.; MANDELITSVAYG, Yu.B.; MILOVIDOV, B.M., nauchnyy red.; MSTOVENKO. N.P., nauchnyy red.; MURINOV, P.A., nauchnyv red.; POLYAKOV, I.A., nauchW red.; PREOBRAZHETISKATA, Z.P., nauchnyy red.; RABINOVICH, A.M., nauchnyy rod.; SIMKIN, S.M., nauchnyy red.; SKVORTSOV, I.M., nauchnyy red.; SYSOYEV, P.V., nauchnyy red.; nauchnyy red.; SMTB~RG, G.L., nauchnyv red.,; SHTEYNMMI, R.Ya., nauchnyy red.; KOSTI, S.D., tekhn.red. [Concise atomic energy encyclopedia] Kratkaia antaiklopediia "Atomnaia onergiia.11 [ Tables of.isoto~es (according to'published data avAilable at the beginning of 1958)] Tablitsa Izotopov-(po dannym, opublikovannym k nachalu 1958. 12 p. Gos. nauch. izd-vo "Bol'--baia sovetskaia antsiklopediia,u 1958. 610 p. (WRA 12:1) 1. SotrudnikiBallsboy Sovetskoy Intsiklopedii (for Bakharovskiy, Berkovich, Danovskiy, Delone, Kon, Kopylov, Mandelltsvayg, Milo- vidov, Mostovenko, I/Airinov, Polyakov, Preobrazhenskaya, Rabinovich, Simkin, Skvortsov, Sysoyev, Shoria, Shrejrberg, Shteynman). (Atomic energy)  MAKARVIC9, SA14; SHORIN, N.A. Electronic digital computers. Priborostroenie no.10:24-26 0 160. (MM 13:11) (Electronic digital computers)  3"10TZI,-T, En-r-Lt Col I Author of article, "The Histor~,- of the DeveloFment of Small Arms ArTr-unition in Russia." OPI, No 1, 1955) SO: Krasnaya Zvezda, Sun #450, 11 AI--r 55  GUATOVSEIY, Hikolay Ivanovich, dotsent, kand.tekhn.nauk, inzh.-polkovnik; SHORO, Pavel Aleksandrovich, inzh.-podpolkovnik; VILtCHINSKIY, I.K., red-,13olkovnik; STRELINIKOVA, M.A., tekhn.red. [Evolution of small arms in Russia] Istoriia rzvitiia ote- chestvennogo strelkovogo oruzhiia. Moskva, Voen.izd-vo M-va obor.SSSR, 1959. 247 p. (MIRA 12:9) (Firearms)  W W-W--WW-W W-W vIF III IF III Wtllf~ 9 W W W W W 0 0 0 0 4 0W99W sow go, OW: 1 10 to 11 U ifWm 11Wa. it is so ad 01:110 0 p 4 101. ::'A I T- , ~ . t 1 0 1 1 - 11 00- The wolding of the hard allay Surntalt W u-I'll- h-I *0 politts with the use of the oftyscetylene "Ame. 1'. 1 Shorin. Artrrnnoe Pelft 8, NJ). 11), 30(110;;7); C*he- 00 AlI ZpxIr. 1938, 11, Z345- fit ortler to incrcu5c the rcnktami- -00 I., vat If l1wellille-f-I I.A111. 1-74"M ",mmil i~ W, I'l. 1-00 "lloy tmit li'l. C I.T.I. %III I T-1. Si .-t 00 *0 J: 00 16,14% kti-I't,ill [III%.IG M-1. .00 al 10 of if I ; '00 zoo :1z 5 L A-t I At L UNGIC At L I I f RA TLRl Cl A%SIF IC A TION is I- $I '1 .13 ItI 00 a0 0 0 i; 0 sos,00 000 a 0:609 is 0 0 it 0 0 0 a 4 0 a 0 0 0 0  !000*0000000*0*0 i -W I 0 01 0 900104tes 9 1 11 W 5 Is 11 If A j L a ft r-LA I T JL_Y A v x Y z As C' ..D 41~ _ 111 ko J.v cant as. _ - _L_ ~ - - - , - go *0 The prodnaon of spiM das with wxftp. p. 1. go Art,tenow Dek 10, No. 2-3. 29~31 MQ9); Chem. 030, 11, 21-5A.-The cutting properti,, of pi,.i 00 drill . oved by th Ii of a lay" contg. Is I" W :ffl 7'a !~ 4 0 C. 01X-0-18 V 17-19, C, 3. 4 nd V 0. 1 '7o togethrr o pecial hea a spp,.'i.1~1ratmrnt, The best-, reautteut fni- C th , ng consists of* Uniform 4: r.1i., up to WO- and fornace-cooling after a retention * period of 30 min.; heating to tXXI , holding at this temp. for 30 min.. followed by rapid heating to 1300' with coal- ing in oil after a retention period of I min.; and annealing (or I hr. at MP with cooling in air. If the Rockwell C 9 0 J. v hardness Is less than 01 after this treatment, the annealing should be reptated further to inaraw the bardnrvs. Cy- 0 0 tni(lcd drills with the caving %how a Rtwkwell C hardn- 0 0 4115A x(Cer the heat-trtatment. M. G. Mtwrr 6: Z #11ALLLSOKAL UTERAtISF CLASSIFtCATICK 'ZO 0.0 0 Ole 0 'Fe ~0- it 4 W 5 A3 a I XA 0 0 0 0 a a Ole 6 0 0 0 go 0 00 00 4 0 0 0 10 -00 -0 _O* -00 go 0 9 9=00 s r4 0 so 0 ISO* VOO Fee  ;;;; ; 00 9-0 0 0 A L _L-L -.fi h IL I- IT io. Lw~~ 0 0 A :0 4-0 a 0 a V III ~ - L Ak-.I-NVtP_V-%- -0 Cold Welding of Cast Im with Combinwation Elec- ennoe Deto Avlo l Sh P I 000 . ., p. g trodim, (In AURSIAII.) gK (Welding), no. 2, 1947, P. irt article gives details of the preparation and Sho constituents of the above electrodes. Applications rL outlined. and advantages over other typea a o 0 .4 00 z ~ASM.SLA 01TALLIJRGKAL UIESATURIE CLAHIFICATION T I ]OKI zoo ire 0 X04D go* see a** xes L 4.11131 GK CMV III 0 5 1 V " 5 a a 3 1 V ,1 41 K' a, 4 CF9 It PO 'I I"" 10401TOO UO '00 *000 04 000000 0 00000 0 0 0 0 0 40 41 0 0 0 0 0 0 do .0 0 6000 0 0 0 0 * 0 0 0 0 :10 0 0 0 * 0 a 0 0 0 0 0 st a 'o 0 0  TA 12T73 USSR/Welding - Cast Iron Jun 1947 Welding - Electrodes "Cold Welding of Cast Iran by Combined Elactrodes," P. I, Shorin, 3 PP "Vestnik 14ashinostroyeniya" Vol XXITII, No 5 Illustrated vith photographs a-rid cross sections. Describes process with Mark 1, 2 and 3 electrodes. 12T73  I-ITLT TOE (T ln u.~.3 a1ii. brief cl!Dsaription -3 inr-- 4-he var at torchtis. davolap3d dar _ ~ -L for autVf-ng mm-tal 50 to 4.a.0 nn. cl- o--Pygan nuirl Cu. m W. reslmative3'v. 8-52 vml 0. irmazodiato source clir -ng qgi 1-7  clHORIJI, P. I., Di.gr F., 167T51 USSR/Engineering - Boilers.* Welding Jul 50 "Devices for Automatic Welding of a Locomotive Boiler," P. I. Shorin, Engr "Avtogen Delo" No 7, pp, 25-27 Describes several types of tilters used in boiler making in combination with welding machines. Tilter permits 3600 turns of bulky heavy pieces and eliminates use of bridge cranes. Describes flux- holding devices to.keep gap between edges of parts to be welded filled with flux, thus preventing leak- age of molten metal during automatic welding pro- cedure. JIM 167T51  SHORIN,P.I., -inzhener --1:- "', Welding a steam engine cast iron cylinder of a rolling mill. Svar. proizv. no.2:27-28 F '55. (MI-RA 8:9) (Steam engines--Cylinders) (Cast iron--Welding)  18M SOV./117-50-2-20./27 AUTHOR: Shorin. P.I. TITIJE: Repair of Castings by Welding-Up (Ispravleniye otlivok zavarkoy) TPEIRIODICAL: Mashinostroitell, 1959, Nr 2. pp 34-7106 (USSR) 13STRACT: The author describes the reDair viork done on defec7 tive cast iron castings conducted by the Kolomenskiy zavod Y --I. ". -1 i- - -I- Plan-~-) im eni Kuybyshev, with the of cold and hot arc welding using copper- steel electrodes,. copper-riickel electrodes, iron- nickel electrodes TsCh-3, cast-iron electrodes GOST 2671-44, and hot mielding-up with the use of gas and added cast iron. The article contains a table show- ing what welding method is applied to which defect. Repair work on defective castings saves the plant over 3,000,000 rubles a year. There are 4 diagrams, 2 uhotos and 1 table. Card 1/1  Restoring stressed cast iron diesel engine parts. Llt.proizv. no.1008-39 0 164. (K-LFA 18-'4/1  SPOilIN, Pavel Matveyevich, inzh.; YER&BI, N.I., red. [The second life of machines] Vtoraia zhizn' mashin. Ullianovsk, Ullianovskoe knizhnoe izd-vo, 19611. -92 p. (MIRA 18:4) 1. Zamestitell nachallnika otdela glavnogo rekhanika i energetika Ullyanovskogo sovnarkhoza, Ullyanovskaya oblast! (for Shorin).  I I - -0 1111111,11bu 0,11 Ital va nun I'Djon 1* 11 1 q I, A A E 0 L -1 FA - A- J. L. L 0 It A I I W I A I t AA 04 1A W it 4 0 pr.9va taking piece in the combustion chamber with jsWW -4 S in a state dauspension N St I T kA s"'stl lvu 1933 "' P" .0 C . ~ . , y 13-19 No -Tbe following stages are dtALW comhu5tion 1he 3 rocess of solid . . , p fuel In couilmstion chambers of furnams: amAynamics of smqpcnded particles; kinetics in the adjacent layer: heat load of comImstion cbsimberi. A few diagrams are given. A, A. Boximmox -6 4 Th d namicsoicandmtimatwUdfu*ISLUEUP"RIW- - No. 2 1933 Ina kh " T -%46 . . . . eSmo jrr yo Kjjn_ 04. 60 00 -00 =00 .40 0 41 w*-- f, .40 040 f a S AI I A I I A I t LPGW A L LIT t *AT L-t L L MIF IC AT ICN .00 L 00 S1 , u I P .4 1) 1 W IH g 0 0 4 0 9 0 0 *4 0 0 IS 0 .01 : - IS 6 00 0 0 46 a 00 0  SHORIN, S. N. SHOFIN, S. N. Izvest. Teplotekh. Refera t. Zhur. _4, The heat capacity calculations. Inst. 1940, No. 9, 27-30; Khim- No. 5, 21, (1941) of flue gases from spectroscopic CA: 37-5570/7  ~ ! * * 0 0 0 P 40 0 .9 1 ~ gal 1 0 p w if 1? 1) 4 1, 4 14 ry x 21 22 zi a a x v a W 15 il ~. ;~ ~, 1 11 tl~ A A C_ C.-L-1 F-h _,L_L_L. ~A if -P 2 - I A U Y _w__x.qQAE '06 00 si: go i 00 jr ~ Throry of Ifeat Ext-hanigr in Co"llnuatiun Cban (in RussiAn.) C. L Pokak and S-_~ ~.Wriu- I-C ' -%kael(viii Nauk SSSR -tin of the Arallell (Built *0 o i ~:ienc" of the USSR), SmAiou of TeAnival Svil Dee. Mg. P. 1912-IF47. 0 '5 Prupowq a formulzit for valcuLition of the a Pn,,ciplvI of this new ult-thott art- thorou -itly n 1 %;I lyzeti. E"rimental invesligatiom tolifirm so la (it tile formula'. .. I a . S L A41TALLIAGICALLITCOATUArl CLASSIFICATtOW Q.- Car ja it v Li m is is v A a C- 7A-1--av-G--R-,_4-W & li_f f 1-k- i k_t, 1- -oil i-oo -00 _0 Writ. rhYd ~ of ices. 0 - -40 me. ana. dity 7L* 0 Zi givie 0 age 0 Cog I...... Isi a r4 a N 4 1 v w .3 a tr a 1, C, 44 w a, ; a, ~ C', I i Fw At T IR An It 'MCI, 0 0 :iq o see 00 go***** 001 9 *10 0 0 0 0 0 0 0 0 & 4 0 0 0 0 0 11440 - 's 19 0 0 so *iiiiese,o 0 0 e. 9 06 0 go 0 * Z & 0 * 0 0 0 o 4  SSR/Fuei - Combustion ju~l U' Thermodynamics F "Role of Radiant Energy in Combustion Processesp" r S. N. Shorin, Power Eng Iast imeni Krzhizhanov- skiy, Acad Sci USSR "I-- Ak Nauk, Otdel Tekh Nauk" No 7, PP 995-1015 Comparison of distribution of radiant and kinetic energies between vectors and element of volume shows that high-energy photons possess consid- erably greater statistical weight than gas mol- ecules of same energies. Probability of photon activation of burning mixture proves considerably 162T41 USSR/Fuel - Combustion (Coatd) Jul 50 higher, for suitable conditions, than probabil- ity of activation for colliding molecules. GIves equation of speed of flame propagation for the case of photon activation of molecules. Explains flameless combustion of gas. Shorin was advised by Acad M. V. Kirpichev and Prof G - L. Polyak. Submitted 21 Apr 50 by Acad M. V. Kirpichev. 410 162T41  4o Heat Exch~Eae~bv Radiation in the Presence of an Absorbing ___TWedium fix S. N. S110J11N (Froln In"e5liYa Akadeini Sauk, No. 3, 1951, pp. 389-400, 1) Illustrations) The author fitiredisces the eyttotiotis ri radiation in space in a vcry Septeralforni. lapgoly barrawed from '-J~ ~'i , III sirupitfled form, these e4tiations catt be applied to the rarfia(ioft practis itt indiattial -Sit" mher Prilreises tj' hear exchayWe imist be considered in addition, I he theory Isap"IM77 of Iteat in a jitnpl~fied furnace model tonjistitig of a ptane-parallet laver of Mrvhtg, ahfo-t-bbig meditan bet'.veen a raNazing surface and a coating 11irface. Finalk)., ana~yt;cal resuht are zompared rvith euipirical Inethods to evalualt heat tranimimion in titim exchange by tadiation in the, combustion chambers mos c0 ex a sorption distinguishes the of. boilers and furnaces usually takes place in the ascous components of the flue gas, such as CO, and ence of a burning, radiating, and moving medium. f1,0. Although the absorption spectrum of these f illelpencral, this medium consists of the gascous sub- gases hai bten stu led a long tirric ago, data on the s"I"Ce, CO,, 14,0, SO,, 0,, as well as 11, CH, C~Hta frequency distribution of absorption coefficients are a I wi r diluted with I parts of nitrogen (by volume). incomplete and the determination of the integral Vurt , rolorc, according to the nature of the fuel and the absorption is greatly complicated by a strong selective mcthod k;t it, combustion, the flue gat mity.friclude effect. The flarne of tar-containing fuels (incandescent adtnixture~ of I;olid fuel particle, such as lar and ash. flarsic) and the combustion products of coal full of soot Vach individual component of thc floc gm In a tviler or and carbon particles huc a weak selective effect, furnace poswmc!i it-, characteristic properties of In this paper, we do not deal with the determination radiation absorption. fabsorption cocificicrits of the different components of he heating medium, nor with it-, tout aliwiption, but are concerned first with the foundations of the theory of heat exchange by radiation in an absorbing medium, and subsequently discuss some (if its applications.  The boundary condition At x I can -b,e expressed In the following form (ice eq. (5)) 4 4 1, Ila, - I where n' dd (jM._I 40.y x T and '40 ; 10 d so d~tU) - .411 - I I -- - : dx dx k dxi Cirrying out'llic differentiation and sUbstitutinn, we 11" r7,' 2 4 'I'lir hcat tran,missinn by radiation -it 111c houndiry is vxprcssrd by (r1j), I or (12) where c I . I + (13) Ra, 2 R 4117" + or sit a: - 2 '0" Aaj - 2) at z G-6 'or at as 2 A a, 0 an' fill t Hit;,~ckb d he nominal enlisslvl .1~ c J;bILnds on Parameter ai. n- The minimum value of it,-obtained at 11" 2 !t iA Vco..S' f'JA or A at ~ Il, emin 1133 vind at a, ~- 0-85, 1 08 Tatl1c I gives the vidues of thr 11"ll."lat cv~~Ilivicnt of cruissivity c for different vibscq of par -.,n( ter If  of the -su`bs-fi_tu_ti_o_n~f the of the equitien of beat transmission q W, - 00 we find thaE (08 - 0.) AB Vor a stationary inctlium in tWlitinc- parAlet layer, the:11(frainker It 0 and Ailt Resolving the indeterminateness (0/0) of expressions 1 and, B thus obtained, we find that I I and R ~~ k1 - C, Ad, 2 As a result oJ the substitution intrithe eq. (18) of ,he values for A alld B at 11 0 lve obtain q (19) kf cs 2) V_ lFhe __ -same - ex-pression for hear transferrW y radiation with a stationary absorbing medium was obtained in 1940 by 0. L. Polinkoff. In the case of i non-absorbing mediurn In the plane- parallel layer ki vitnishes and, therefore, 0,-0, (20) at a, In other wordso we obtain the well-known equation I of beat exchatiRe by radiation between two hu&s with plane-parrallel surfaces. Figs. 2 and 3 show familics of curvcN representing the tern t I c 7' a a funetion of kx in,a pLine- i tie, ! h Para ayer in t c two Ca,1S of a stationary and a moving medium at kf - 0 It -is seen that in;the' ca5cs of a stationary and a -p. moviag medium in the plane iralld layer, a tetrillicra tum step exists at the radiating, surface, the magnitude of pit oil' h.-at tran.MliUctl and wld h, dic cilds on thelarliou t lcv c I Sp cy tit which it c medium in,ovc,, f panonclerfl). With all incrc.i,e in file ~ilct-d tit the inctlitim, thc  F. uming, the right-hand ~idcs of cq5. 6) and (21), pl~min an cqu.1tion for the determination of the 11 1" I,cr,~turc of the produc" of combustion at the loill,oing, %urfacc~ P 4 0, (22) I., e4 W/ - I III 111C sanic wav, 11-C obtain on C(Illition for the ion t it'll ~f tile terurcrature nt the vroducts of comb Pustion at the mcliation-abiotbing %urface v, (c, t, - C, t, ) ~. f (a 02) (23) F, introducing the mean %tEcific heat of The products of combustion in accordnn'ce with the equation C,1, c,1,, cjt, c, 1, --1 r, I" or c, cq-, (22) and (23) can b~ transformed into the following top tton-dimcn~ionnl forn: Pig. 3. Temperature diltribution In a moAng absorhinsr' M.dlum, K,. 7- Y 1r, - , and 01 T, T, 7"  .......... E 'T NSMISSION IN BOILER 3. IIEAT RA FURNACES I The solution (if the problem discusqed above of licat exchange by radilticm betweca two bodies with parallel StLrfdCCS iti the presence of -a radiation-abstirbing mediont ticEivecti ilicst: surfaces which JnOVCS JOW:19Lk th-, radiation-absorbing surface, can be applied to thr calculation of hear transmi5sion by radiation in boiler furmicm Yh c mast a pprop r i-i te model of a combus t ion chamber 'for the application of dit: solution obtained woold he as follows :- Thc conibustion -chimber represcills a channel of arl,itrary Mmpc~ but a cross-~cciion of 'Aficient size. ,j,bu ~i,jc w:jIls of the channel are hcat-insulating, and the cooling SUrfaCCJ5 Sittlated across (lie section 'A the combustion clianther. The heating nlcd~k= UU7ves along (lie Channel towards #jw radii rion-absorbing surface with a uniform velocity of tv, [Nin'.1in'lirl. 'I'lic combustion of the fuel in the combustion chamber is completed beforc penetration of the beating medium through the radi-mimi-absorbing surface. 1:1,r bj)jlcr furliaces, the iviripmature of the com- buoion products at the exit front the conibuWun chmnhcr can be dctcrinincd from eq. (25), which, tin ~:~,ndmwi thm 4),' - 0' ' i, tram(mmcd into 1 0 (26' I I is inter-:,tin6 to notc that eq, 1261, whicil is-' only [fir coulbu "i". chambers with cooling colifincd 11) onc surface, in (lit first approximation desclibe-, the result-, of experiments on indmirial boilcr . furnaces with the heating criterion K, ranging ftom zero to 1 8, and a constint va!ue of (lie nominal coJficient (if emissivity , .7 0 8% but irrespective (if the con- structional shapt! of the. combuition chamber, the nqcurcoftticfticlatictiliciticthodofctittibtiqitin. This result is forcshadowcd by eq. (26), in which variation of the nonlinal cocIficient of enlissivity ~ has a iL:IjtivL!ly weak iotItienct: on the value of 0". For insimut-, it t is rcduccd to one half, front a value of 0 85 to 0,PJi atjj_ --- __ c mtan~ ~1. _ I ~H, thc nmj!mttt,je ill change frum 0 679 it> 0 753, i.e., by I I 1,,:r ~cnt only. For smaller values of the criterion K_ the variation of 0" will lie even less. The weak influence tX c, which satisfies the sit-callcu condition afniodeteepresc-,itatioti,consideralily implifics [tic analysis of beat transmission in boiler furnaccq. The comparison ofcq. (26) with the "isting Immulae for the calculation of heat transmission in boile r furtiaces, which are established from experiniental djtj jind ~vljiclj contain the maguitude R_as a dc(crinining paraincter* is shown in Fig, 5, where the of 0 , 1(fK-) re- firricot otir eq. (20), and r%vo nih,.r methoeli 4 calculation.  - . ~ ; . !~ ~ ~ I PI , Z, . ~ ; . "Heat Transfer" 1-1-2 Textboolk for students specializing in gas heat supply and ventilation. However, the theoretical part is of general interest for heat transfer.  AN f j ~_-N C I :j A "~A Y- A a s oz~ _~- 1 F.C; Sua 22 IMAY ~2, r,-,, Dic i ti~ ~~z i u.3 1 N S T I MFN I R ZH I ZA.,. 5 ,, I Y A T THE [jIE:GREi. F L',OCTOR j.. TEcHmCAL 5CIENCETI VECHERNAYA M1,3KVA, JANUA F-DECEMU~R iq~;2 Dissertation by S.N.Shorin "Heat transfer in a radiation absorbing madium~" Izv. AN SSSR Otd.tekh.nauk no.5:788-789 My 153. MRA 6:8) (Heat--Convection) (Shorin, S.N.)   USS R 1621115 621.438.016.4 Radiation Heat ExchanU in the Cooled I~v.Akadjlaukfotd. Combustion Ohambers of G-Ls TIWI:g- 7.. -Inas TQkh.Nauk 1954 S. N. Shorin U S.S.R. Mathematical a1scussion of various processes in a flow of burning mixture is offered, yvith particular -Vfcrcncc. to raaiation heat exchange, Radiation temperaturej, which exists aloogside kinatla tomporatLire in a fluw Of radiating medium is taken into aoco -unt, since it determines radiation heat exchange. Results of oalorifiomoaaur6ment of heat j, exchange in a cooled combustion chamber are briefly summarised. Because of the possibility of considerable radiation heat exchange in.combustionchadbers, in order to reduce the convective heating surfaces of heat exchangers. In closed cycle gasl'~turbine,a, provisions should ~e made t6 increase beat emission criteria In,cornbustion apace. (Bibl. 2) ..........  ARTYUKHOV, Ivan Mikhaylovich, kandidat tekhnicheskikh nauk- SHOR-IN Serafim Hikolayevich, doktor takhnicheskikh nauk; NO HADOV, A.D., redaktor; KOHYASHINA, A.D., tekhnicheskiy redaktor [Gas supply] Gazoanabzhente. Moskva. Izd-vo Ministeretva kommunall- nogo khoziaistva RSFSR, 1956. 325 P. (KLRA 9:9) (Gas suoply)  KOLCHENOGOVA, I.P. (Moskva); SHORIE, S.N. (Moskva) Study of radiation energy transmission in attenuating media. Izv. AN SSSR.Otd.tekh.nauk no.5:29-39 MY '56. (HIJIA 9:8) (Heat--Radiation and absorption)  'j Cam rim 7 O~Itn -inor Importance in tawstrial heating 'Af-,~he PgAwn-1011 dt --ew f eitrrely Uw therwl eg V-AII,;Iktq, ~StNh ke erd amfibaotte am ezLqust r - . 1p, hot ttXWJrop co Wim engim Yhas isd :o -mrWe Abdies or the of wNdhNAUAM tf~i design ot !Pecial ba-nfm, equimant. Me h!~t UPZt CrOfil 8 WOU'r PaS set with average cartun mowxi:ie ard *-O1VgFn W-t 9 )~-r 7.2 ard 2.0~% at a t Emp,3rature of 561', and a q value of 266 tIlzu.r- (29 B.t.u./Cu.ft) 18 succEssPilly utjlt~.ed aZ a Russian dlemical plant by the applicatirn .)f the principle of captact catalysts " Zbe use --)r preheated air. The gGs-air mixture (coefficient or excess, 1.08, at a temperature of ?900 is completely burned in passing a contac% bed 3D M deep consist Ing ot lumps of refrectoi-I gilog 30-W &M In 41metef to generate 1 11630. Gas consumption la 26W cu.mfti ma'%he heat a bed temperature G4 output at t tie bed 18 2.7 X IOP kcal/sci.mIts. A.11 data cice~! are tveraeea or 11 test runs. Schematic drein rZs Illustrate laboratory ani plant =a1e furnaces (rhzoug)1 make up error explanatory legends are Intereftarged),i-_. (L) C.AO ~w  ADRIANOV, V.N, inzhener;IqgO2LRIN, S.N., doktor Haat transfer by radiating combustion Teploenergatika 4 no-3:50-55 Mr '57. (Heat--Transmission) tekhnicheskikh nauk. products floving in a channel. 04LRA 10:3)  SOV/24-58-5-8/31 AUTHORS: Andrianov, V. N. and Shorin, S. N. (Moscow) TITLE: Radiant Heat Exchange In a' Trent of Radiating Medium (Luchistyy teploobmen - v potoke izluchayushchey sredy' ) FERIODICAL: Izvestiya Akademii Nauk SSSR, Otdeleniye Tekhnicheskikh Nauk', 19587 Nr 5, pp 46-53 (USSR) ABSTRACT: In high temperature heat exchange devices heat transfer by radiation plays an important role. In a number of papers (Refs 1-6) this problem was considered assuming a uniform distribution of temperatures and velocities over the cross-section of the current; V. I. Pukhov (Ref 5) does assume uniform distribution across the cross- section of the speed but not of the temperature. The present paper presents an attempt to solve this problem taking into account non-uniform distribution of velocities and temperatures over a cross-section of a current of a radiating medium in the case of cylindrical and plane channels. The corresponding differential equation is solved under the assumptions that the medium is purely absorbing, the scattering coefficient equals zero, and the radiant heat transfer Card 112 between elements of the medium within its volume can be  SOV/24-58-5-8/31 Radiant Heat Exchange in a Current,.;,Qf Radiating Medium neglected. The absorption coefficient of the medium is assumed to be constant. Explicit expressions are derived for the above two cases and the results are summarised in five graphs. There are 7 figures and 8 references, 6 of which are Soviet, 1 German, 1 French. SUBMITTED: February 18, 1958 Card 2/2  AUTHORS: Shorin, S. N., Adrianov, V. TITLE: The Investigation of the Raiiation luchistogo teploobmena) Conference at the Institute Energeticheskom institute) PERIODICAL: Vestnik Akademii nauk SSSR, X. SOV/U-58-7-39/49 Heat Exchange (Izucheniye of Power Engineering (Sessiya v 19158, Ur 7, pp. 129-130 (USSR) A13STRACT: This conference took placc March 25 - 2B, and was called by the Committee for HiGh-Pressure, Hioh-Temperature Steam at the Institute of Power En-ineerin- imeni G.11. Krzhizhanovskiy AS USSR (Komissiya para vysokikh parametrov pri Energetiches- koin institute ini. G.M. Krzhizhanovsko-o Akademii nauk SSSR). It was attended by; representatives of academic and branch institutes,of universities, of design organizations and in- dustrial enterprises. MI.A. Mikheyev, Member, Academy of Sciences, USSR.opened the meeting. The work of the conference was per- formed in sections: Fur-lace and firebox systems, furnace heat er,Eineerin~;, physical-technical section. Theoretical research was touched upon by a considerable proportion of the reports. Co.,imunications concerning various model representations of Card 1/2 processes of radiation energy exchange were met with great  The Investigation of the R--.-diation Heat Exchange# 6OV/ 30-5a-7-39/49 Conference at the Institute of Power Engineering interest. Apart from successful work also shortcomings in the field of experimental research were noted. In the conference the necessity was underlined to close the gap between theory Rnd practice. The conference ordered the Commission for High- Pressure, High-Temperature Steam to coordinate research in this field in a systematic way and towork out a uniform multi- lateral plan of research. It was acknowledged to-be expedient for the USSR to participate in-he work of the International Committee for-he Investigation of Flame Radiation (Mezhduna- rodnyy komitet po issledovaniyu radiatsii plameni) in order to establish closer contact and collaboration with foreig-n scientists in the field of radiation heat exchange. Card 2/2  YERMOLAYEV, O.N., inzh.; SHORIN, S.H., prof., nauchnyy rukovoditell Experimental investigation of gas flame. Trudy MIKHM vol.16: 23-36 '58. (MIRA 11+:7) (Flame) (Gas burners)  24(8) PHASE I BOOK EXPLOITATION SOV/1826 Akademlya nauk SSSR. Energetichaskly Institut Toploperadacha I toplavoye ..a 0jjj;'.~v.Iy. ~ai'1GTFfFr_a_na_ Modaling of Heat Processes) Moscow. Ixd-vo AN SSSR, 1959. 149 p. Errata slip Lnsartad. ],500 copies printed. Boop. Ed.: M. A. Mikheyev, Academician; Ed. of Publishing Housai D. A. Ivanova; Tach. Ed.: C. N. Shavchanko. PURPOSE: The book to Intended for scientists concerned with heat transfer, heat emission, and hydraulics of liquid metals, etc. COVERAGE: This collection In dedicated to he memory of Academician M. V. KIrpichev who In the twenties initiated a systamatic Investigation of heat transfer processes and the arflclancy of' heat apparatus. Later he led the development or research work this field. Two special collections devoted to works of Kirpichav's school have been published, one in 1938, Materialy so7eshchantya po modelirovanlya (Materials or the Conference on Modeling) and In 19510 Toorlya podoblya I modeltrovaniye (Theory Of Similitude and Modeling). The present collection prepared in 1956 represents further development of the work or this school. This theory Is fundamental for the analysis or many heat problems in the field or electrical and radio engineering. Of great importance are the first systematic investigations or heat transfer and the hydraulics of liquid matalB which as a new kind or heat carrier may be used In the various bra~nchas or modern engineering. As a result of spaniel investigations or some cases or convective heat transfer* a dependence of the process on the kind of liquid, temperature, pressure, direction of the heat flow, and other factors, was discovered and established. On the basis of a -do goneralizationsor exp:rl mental data, now dependable recommendations for heat &=1y Is of ngineering equipment were developed. Of no long Interest is the work on heat transmission In boiling liquids and The condensation of vapors. All investigations are based on the theory of similitude, the nature 0( which, according to m. V. Kirpichav, is that of "experimentation.* Vork on the theory of a regular regime applied to a system or bodies with an Internal source of heat to of Interest for the future. 3horin. S. N.j 0. L. Folyak, 1. Kolchartogova, V N ',drianov --9H9-U-.1r.-TormoI&yev. Light 1io4olTiQ-af-tndiat ton 365 The arCro_1-e--grW!ffunIamenaIa or th~ theory a.' rallW-n exchange In transparent and In IllumInnted media. It describes sources of light and chwWoa of Ill'-m1natton and gives a photographic method for neasurine streams or light. Investigations or raflation eXC1dLnC63 in cylindricul chambers and In banks a' piper. transfer of radiation energy in an Illuminated medluit, local Illum-nution of a IIs of be IIrr burners AM hearth bottoms of open hearth oleo! furns". 3 ftre described. The followinr personalities arc mentioned: --Oo Yet VlUsov (approximate solution or a cylindrical equittion). Y4. S. KuznatBow (dispersion or radiation). 'todamicinn M- V. Kirpichav (Investigation of r~llation ho.L transfer In light models). L A Vulis (light modellng,). G. L. ?olyak, and 3- M. Shorin itheory of radiation exchur4:os), nnd with the cooperation of V. '.. Monstantinow (radla;iar. exchungoo in banks of piper). 'he section on -Ihotographic Method or Measuring Light Streams- wascomplIel by V. ?;. ~drlarov hnd 0. L. ?Olyak; the section "Inveslientl3n or the Transfer of Radiation Energy In an Illuminated MjdLum" was complied by 1. P. Kolchunova, S. N. :.horIn ani 11. N. driunov; nootlors an -Measurement of Local Illumination of 1:alls of' Modele of boiler Burners* and "Invertiration of ~icm'. Ill~mlnatlon or the Surface of the sotton or an Cp-n_hj,.rth PUrn1LCe* were compiled by 0. N. Yer-"IftyeW z.-M S. N. -hor-In. Ther-9 are 27 reforanceas 19 Zoviet. 5 ftglIshan4 3 (;erran. AVAILABLEs Library of Congress 13/drh Cord 20/20 8-7-"  i/36-5,J-2-10/18 AUTHORS: fbLmij"--~e Dcct.-r of Tecim:L.-,al `c-Jence,- Yermolayev, 0.14., Engineer TITLE: The Combustilon and- Radiation Characteristi,--s of a Turbulent Gas Flame (Kharal-c-ter-istiki goreniya J- radiataii tur-bulentnogo gazo-Togo -,E'akala) PERIODICAL:Teplc--nergetika, 1959, Nr 2, pp 5'7-62 (USSR) ABSTRAUT: Because of in~:reasing use of gas fuel it is import,ant to have general formulae for determining the flame length during the combustion of turbulent jets of various gases and to know the radiation -,-.haracteristies of burning gas_jet.=-,, Tlie chara-Lteristics of a turbulent gas flame ai-e discussed; ccrditions in general are unstable and pulsatino- ,,. A combustion front exists inside the flame and a fcraula is gi-ren for its length. The rate of propagation of the flame in a turbulent flow of com-tustible gas is considerably higher than the rate of flame propagation ia lamlinar flow. However, because of the lcw stability of t-'--,e fl~j-,a front- in turbulent flow variious ldnds o4L' aczificial sl,;abiliser are required to retain the fiame naar the. burners. On Card 1/'7 the basis of maEs transfer theo--w a formula is derived  SOV/96- -50-2-10/18 The Combustion and Radiation Charac;-Uer-ist'L`---s o-L--' a Turbulent Gas Flame for the iengt1i of the turbulent precombustion Zone. Finally an expression -.Ls gi-.- n.-n for the leng-th of a 'turbulent flame. With this general relationship as a basis spec-Lal tests were ma-de to obtain a definite formula for the langth cf a turbulent flame as a function of '~rarioiis go-Terning Griteria -x.-en ourning different cSolases, T-ni.e ex-Derimental set-up used to study the combusti:-in of Niraing jets of gas is illustrated diaErammatically in i~-'ig 2. It- J-nc?.ludes an arrangement uo preheat ta-1 gas t-o any reTuired temperature, a nozzle box whi~3h ,-,ar. take nozzles cf -,he different --hapes and sizes J-11-a-trated ij-i 3 and varicus devi,~es.tc control and meas,~-P- the floa of gas, its temperature and pressure and radiation from the flame. lariou;s methods of measuring the flame leng-rh were exami-ined and simp'e -,:is-aal examinati~~n was fc-and best. A hyd:~,aulic level indi.---atcr.. shovin, diagrammatically in --PiG 2.. was devise-d to facilitate e-raluation of e Card 2/7 position of t1--,e tac of the flame. The ccaposition of  ,The Combustion and --~adiatlion a GaS Flame the lAoscow Town gas used in the tests was not strictly constant, which somewhat, im-paired the accuracy Gf the resultsi the mean composition is given, Altogether, 23 series of tests were made on town gas, 9 series on propane and 4 series on hydrogen, making nearly 1000 individual tests in all. Each series of tests was made with a particular nozzle diameter. The -vari-ables in tests of a given series were gas consumption and temperature, The nozzles were made from a num1ber of different materials and ranged in diameter from 2.0 to 10.1 mm. In calculating the diffusion criterion the coefficient of kinematic, viscosity was calculated for the ambient air tem-oera:Uure and the coeffi(aient of molecular diffusioLl for tiie temperature of the gas on leaving the nozzles. This was a bit arbitrary since the temperature at which the process of molecular mixing occurs in burnin,-, jets is considerably higher thar the init-ial gas temperatul-e P-L-nd is different in different paints of the 'Llame. As tile object of this Uard 3/7 investigation was only to obt-ain quantitative data about  ~30V/96-51c~;- .2..10/18 Phe Combuson and Rad4a~ion Characteristio-s Q.`, a Turbulen-G Gas U _L U 'IT Flame the -characteristics of turbule-at flames" b-cLrnin~-, -as of given composition, the densities of the gas and air were not considered in working out', -the test results. The method of plottling the results th-at. was used to deteraline the influence of different criteria on the length of the f lame is ex-, :)lained an-3 the experimental results are then pio'jzed in Fig :: and 6. Florumilae (4), (5) and (6) are z~Ler. &Lven fox- the flame length of town gas, propane and 'iydrogen respectively. Formulae given by previous aut.-Ilors for flame length are briefly considerea and their limitat-,ions disC.ussed; one makes un~ustifJ.able assum-p-t-Lons and another Is valid only for U cold gas. However the present tests showed that the length of turbulent flames io much affec,-ted by the initial gas temperatxre. Other things being equal, increase in the gas temperatjxe sho-Ttens the ilame length because the temperature has a marked effect on the diffusion coefficient of the gas. The initial Card 4/7 diaaeter of che jet also has a very strong influence on CD  ,~OV/96-5 9. .2-10/18 The Combustion and acadiation Charac-.-Jeristic-c! oi~~ a Turbulent Gas Flame the length of the turbulent, flame, the less the initial diameter the iess the length of the flame. The most important feature of turbulent jets of burning gas in a free oxidising inedium is diffuse after-burning of gas clusters and it is this process that mainly governs the length of the turbulent flames. The radiation characteristics of a flame are tner, considered and formula (8) is derived for the total radiation from t)--:) flame,. The extent to which -oart of this radiation may be absorbed by the mediini immedia-Uely surrounding the flame is then considered and suitable corrections are given for the radiation formulae. In the tests the radiation characteristics of the flames were studied by measuring the radiation at a fixed place on the circumference of the flame., as shown in Fig 2. The radiometer was placed in such a way as to record radiation from the flame in a direction perpendicular to its ayis, because this corresponds most closely to conditions of radiation from a flame to the lateral Card 5/7 heatinG surfaces in furnaces. The results of local  ~130V/96- -5 9-2 -10/18 The Combustion P-,d Radia-r_,ion -Jciarac-"~erist~-irs of a `.!~L71~'bule_nt Glas Flame radiation ineasureiiients on flawes of tc-iiiin gas and propane -butane are plotted in Vig '? in which the bold 0 line corresponds to formula (12), The formulae previously deriirad_ to detaimine the length of the oas flames are a~pplied to obtain formulae (13) a-rid (W-for the radiation chaxacteristi~s US:irL6 1doscIlow City gas and liquid gas reapectively~ These characteristics can be used to explain the influence of various factors on the radiation from the flame, the most important of which is the initial diameter of t1ne -;et and t:~e t'neoretical combustion -11-em-oei_atu_-e of the -as. In actual furnace o-onditions part, of the rad-Jarion from the fLlane is absorbeed by oombustion products but the amount so absorbed can be reduced by keeping the flame Pear to the surfaces being -heated. T'he object of the tests described was to st-ady flaue Cnaract..erist-ics in the purest form witholit the complications that result from Card 6/7 the influenze of various oandi~:J.ons si)rrou.-nding the C)  SOV/96--59-2-10/18 The Combustion and Radiat~Lon Characteristics of P-- Turbulent Gas Flame flame such as 'Une arrangement, shape and size of surrounding walls, their reflecting and absorbing properties and so on. There are ? figures and Of WI-14 2 references -Leh 1 is Soviet and 1 English. ASSOC IATION: ivioskovskiy Institut Khimicheskogo L.1ashinostroyeniya (!,.Ioscow Institute of I'Dhemical -~;ngineering) Card 7/7  SOV/96-59-4-12/21 AUTHORS: Adrianu-, _V.7N.; Candidate of Technical Sciences and 4 Shorin, DofLto-r of Technc,,al Sciences TITIE. An Investi-ation of Heat Exchange in a Gas Combustion CD Chambe- (Issled~.7.raniye teplocbmena v kamere goreniya ga z a.) PERIODICAL:Tapl,-%er~r--:7getika., 1959, Nr L~, pp 62-67 (USSR) ABSTRACT.-, Vrtl--.n- a tu-rt-,u--,Ien+4 flow of gas previously mixed with air is burned the cc)iabust;ion prc-;~ess i.3 mostly localised into a small part of tLe combustion cthamber. Under these oonaw'- -.)ns the pro,:~,:~ss of heat exchange has special feature-S and i:,equir-'s special study. Purely analytical ill"IestiGation of the question presents great mathematical te---ause of the complexity of the systems of eq,Latio.as that des!---ribe '1-,,he -orccesses orcurring in gas --ombustion cliawbe:cs. For similar reasons it is very difficult to apply the theory of similarity to the sol---it-ic.n of such problems. There seem, hoviever, to be two possj:cle ar-.p:r,:)aches to investigation of the complex Card 1/7 pro..-:esses that in comVastion chambers. The process  SOII/96-59-4-12/21 An Investigation of Hea.1-4 Exchange in a Gas Combustion Chamber of heat exchange can be investigated experimentally making u-se of the theory of similarity in the simplest pessible devices that have real physical meaning. One variable can then be altered at a time keeping the others constant so far as possible, This approach greatly simplifies derivation of the final functional relationship, makes the results more reliable and has other practical advantages. Then the theory of similarity is developed so as to seek more general invariable links for the complex combustion processes than are giiien by the classical methods of the theory of Sim-ilarity. This mathod is a synthesis of mathemat,4-,--al and experimental investigations and it consists essentially in extending the concept of simllarity from a group of similar effects to a class and then considering more generally the conditions of uniqueness and making use of complex invariant links. -Ln zhis article use is made of the first of these two proposals to in-ijestigate the influence of the hydro- dynami-I and optic-al characteristics of the medium on heat exchange az a g;iven gas combustion chamber. The Card 2 invest igat- ions were specially arranged so that a  SOV/96-59-4-12/21 An Tnves-Gigation of Heat; E'x.~;hanga in a Gas Combustion Chamber .considerable umbar of invariants were maintained constant and a n:amt-er of :triteria were uniquely determined by the hydrcd.,~mamli,:~ ~.~r~terion., the Reynolds number. The entire comple-x cf physizal effects that occur in heat exchange chambers ran be rep-j-,esented by a system of differential and equations. The principal equatd.z)roq ioui~~:-.rued are the following: (1) the eqi_:ation cf motion of -OLscosity of the compressed flui-d~ for t1b..ree-dimen-Sional motion of the medium in which the coefficier.- of dynamic vi!5cosity and the density are con-sUered a!~ -variables depending on the temperature, press'tacp, Paid composition of the medium at any point; (2) -the aq:uation cJ:: mass transfer; (3) 7-he eneT&y equation that represents the law of consex.--,ration of energy for each elementary volume of the (4 the --,,cmtustion. equati-on that relates the rate of the Combustion reaction to the rate of supply of reacting components dn the elementary volume considered, that Card 3/? occurs as a result cif molecular and molar transfers-,  '~jj--"T/96-59-4-12/21 An Investigation of Heat Exchange Ln a Gas Combustion Chamber the equations that r-alate the physical parameter-s of the m~~d_-um to it-,q temperature, pressure and t~om 'LT~ iou (6) the stoit-.!aoiretr_;-_ evations of the reacting gas-air mi_)ct1L,,re that gi--ze the relationships 1>atween changes in concentration cf all the components of the reacting Mix-mre " By the applic-ation of the. theo2.7 of similarity to this system of equau-ions the dimensionless field of all the aauai. ud-es reriijared oai-i be represen~.(-,d as a function of that enter int-o the ~~onditions of 1--onsid-ers geometrically _-;hambers of given shape and arrangement of heat-,JMg and zalsc -,,vith given temperature, pressax_-, ~.omposition and vealo4Uty of gas mixture at ule-. Th5 3ystem. of determining iiryaziants is then 'Cl. It i9 then shovin how the system may be simplified I -L . %J and finally a vej_y simple sy_,~-'tem is armi-ved at. The aXpe:c-.L.M-'Iltal arpa:cat-j-5~ is then deEcribed. It consists of a mclei a :~~qfztem for deli-,ering dust, air and Card 4/7 gas ar-d arraneeme-ur; --'.-)r cemo,'ring ~icmbustior_ products. r')  SOV/96---59-4-12/21 1j - An InrestiEat-_'L~ Hea.. Cumbi-,,:3-11-ion Chamber The mciall. Is illustzat-ed in Fig.1 and consists . . .1.1 qr 4.C,-~_- of a '-:'-rft -, _J. :,hamber and cooling chamber -)f --a''9hape. The -vxpezlmental procedure is des,---c-ibed, T~ja fuej. use," ' -,Af,3,s Moscow Tcwn gas. Some tes-t-.s 1Eade wi~-ia a. c0l5ty flame using rl~hroiae-magrie site dust of an a-.-erase _~_Jze of 30 The equipment w 'as T,sing -11-bis e-LT.Lipment 67 tests were T.-ade and ~16 with dusty flames. The Tange o-f C_? M-~"qti Important experimental eration ~f exDression (5) RevLi.cids n:umber uniquely _9 Lteria and since the -.C-Vere"I a wide 2:ange of Reynolds it 'v 9 ou-Id b expe.';ted that .-r-terica would ha--~-, ar- iwpo:rtant influence on the 3at Th- natuTr:~ thi3 influence is -!a0:J,.~a'-'I.v J,n fti.-.2, vvhicth gi-%;,-es the C!I,Sb 4 relati ~P F, 7t the. c~ri+,eriia of heat ex--hangeJbr the I and as fun,'--tions of Reynolds Card Tt be Beea t..'A-at: these var-Lables are  :'C)V/96--59-4-12/21 An Inve stigal; ion --~f heat Ex.-;-riange in a Gas Combustion Chamber governed almost ,iniquely by tibe Reynolds number and accordingly the other criteria concerned must have con~ideiably le3s effect. A further way of showing the I t4 C--Lo~e rela~-Lonship between heat exchange --riteria and Reynolds number is illustrated graphically in Fig.3 from which approximate heat exchange formulae are derived. The strur3ture of the formulae reveals the nature of the influence on Leat exchange of such important factors as load and theoretical combus-,:-icn temperatures. It may be concluded f2?.-)nl the experimental graphs that under the gi-ven experimental conditions the hydrodynamic c-harai~t-eristics of -.-~he ficw represented by the Reynolds n-umber a dominating Influence on heat exchange. Withiii the ran-ge --onsidered other factors are relatively ~-nimportant- and may 'te neglected. Attempts to generalise the expa.ri-mental data by constriacting corresponding -as function of the Bolzmann criterion are m,-ich less satisfactory as will be seen from the graph gi-v,-en in The Seaneral fofm of the relationship is ob7F-,;.ou-sly similar to that given in Fig.2 but the scatter Card 6/? of *rt,.e poi-nts -Ij~-much greater and there can be no quest-'on  SOV/96-59--4--12/21 An Investisa-~'-Sioa Qt' Heat Ex3hange- ~jn a Gas Combusticn Chamber of there b-aing a un-!.,:rae relationship. This is partly be,-,aiise the Bolzmann xitericia dces not uniquely determ-:.iae the proc-ess ef heat exchange j-u combustion c1hP-mbe-.n2 La general ax-d for the given conditions in Fiirther '. the inclusion of the theoretical Jr, the BoLzmann critei:icn as a condition of u ni q - . - --)t -L- lelneSs lc, r- suffi~~iently well founded as this does uot in combustion chambers. There are f j i~-Ari~ F- ASSOC DV11 11 Oil . Hn ~ rge, t i'-1- sk:t.,1 ~-ristitut Aj:i sssR (Power Institute of the A.2,adam--, I,f Sot.en-;e ;ISSR) Card 7/7  KOLCHENOGOVA, I.P.; SHORIN, S.N. Intensification of heat exchange prom. 4 no.~:27-33 F 159. .(Heat--Transmission) during the burning of gas. Gaz. (MIRA 12:3) (Gas as fuel)  PHASK I BWK EXPIZITOICK X7/43% Akadonlya cook _SZSR. Margeticheakly Lastitut JonvaktivVy I lumblotyy toplacbmon (Convection and Hall Heat zxz~ Moscow, I -d-o AN SSSR, 1960. 254 p. Errat. slip Ins:Ir'Ll.cd. Printed. Zd.t M.A. Kikhey-, Icadomicim; Ed. of Publishizg Houset - G.B. &d.1 T.V. Brusgull. PURPMU The book to intandad for scientists and engineers wokizZ in branch.. of scionce and Industry concerned with thomodj- W. tr,- far prablens. COVER, =i The book consists of 19 original articles on arious pmbl -Z th..~ c dymaxi .. Th. following ..b]-t. a.r. dis."..dt .. hrism of he. far pr-ses. , It.maLfi.ati" of beat -b-g*' dotermics-.ion of pp.'tm of operating media, beat transfer I. supersonic flow of C%., -d cmd-tion cbAmbor3 and nual or reactors, Tbaory mrA exparlmentsa to,t~!qls are described. I ch rticl: do. rise: the nodit Iuse a the -, ~-- - tables of the *.p.~L-ntml data obtain d are it-. Th ;aUta naY be -i for Wmlatim. of hoist transfer -:I beat ox.bag-rm. alw. taking -.-t of )Ukb.ya, A v tig.tism or A-b-Ce at i;~ &c. of 'j.L.r "Ig In Pipes 33 ?-h$lkiD, I.H. Beat Tranafor I, Vertical pipe. in Natural Con, action 56, T- and L.D_ Red==, Critical rha~_l C~.n%. I. ih_'C~-ls of C-.Pl.x rom (100 at. prossurv) 'Ala d'yav, I.T. "L.D. Doducavv and V.S. 61,1_ rx"rl=dnt&l Data an =oat Tram.for In iabllZg Bow., or Und-rh.xtd W.-..r I. pip.. r&U a Ate on Viscosity "A Feet of Lc* ,.:ti= of Experimontal D 1quId ti. 917 t 'L"a -tig*UOU of the Process or C_b!..4 face R=Ation Beat RaChang- of Bodies Vith Arbitrw-y loii0ahricas 'hliso'W, S.S.. B.A. Khm.ta1-- &APV-9- Ldrisc-1. K-sur~t or %he Components of C&-61-1 C-0-acti- and Radiation Heat. j_h_V by th. X." Adr"'". RAdIcestric lostrusent for Measuring the plow of *-i.tjoa Thecr~ -of the Heat Regina of 5=6 Conatrus'John of X..U, G.N., G.P. po&2TAWA .at of j.4.nd Aj_~hjrn- MCI ... ri., -t_% for Calculating the T_ M Th-real Kdollog of the H..t_Prftcjng ga-ts or an Ltad, 176 'Nose-1, A.O.. -d A.I. B.rs.hny. In-gLICtion of MclasuU, n4 _,.~ Diffusion by the SIM1_,_rjTy_-FM-a- _to lea TA-Ivftq~in) _p4_-.q'hAk-n and With the Distortion of ls.th.roe in th. ;.ksgLom L_ act., cation of Thersocouplas '~illac*no,, B.S., and B.A. ghmot.l._ C.l.wl.tlos~f Heat Zc r draul4o Resistance An Lmlnr Motion of Fluids in "Pas he _ a " H'_ "'Y", I.T. Heat Transfer in Bubbling Boiling 233 ATAILABUS Libr"7 of Congress  SHORIN S N., doktor tekhn. nank., prof., red.; SHCHEPKIN, S.I., zasl. deyatell tekhtiki, prof.,. vtv. red.; LASTOVTSEV, A.M., prof. red.; K~V'Am' N.M., prof., red.; KOKOREV, D.T., prof., red.; FETROKAS, L.V., prof., red.; RFZHCMOV- P.M., dots., red.; SOKOLOV, S-N-.v prof*y red.1 SOKOLOT, S.I.-, mmf.. red.; KHODZHAYEV, A.M., dots*, red.; LEBEDEV,,K.I., kand-. tekbn. nauk,-'dbts, red.; TAIROVA, A.L., red. izd- va; UVAROVA,.A.F.,.tekhn. red. (Investigation a64 calculation of heat engineering and power generating processes) Issledovaniia i raschety Uploenergeticheakikh i energo- khimicheskikh protsessov; abornik stateio Pod red. S.N.Shorina. Mo- skva, Gos. nauchno-tekhn. izd-vo mashinostroit. lit-ry, 1961. 137 P& (MIRA 24:10) 1. Moscow. Institut khimicheskogo mashinostroyeniya. (Heat engineering) (Power engineering)  32727 S/671/61/000/000/003/003 A059/Ai26 AUTHORS: Shorin, S.N. Doctor of Technical Sciences, Professor, and Ch-ipashvi1r,"O.N., Engineer TITLE: Action of circular flow on the heat exchange in a gas combustion chamber PERIODICAL: Issledovaniye i raschety teploenergeticheskikh i energokhimi- cheskikh protsessov; sbornik statey; Gosudarstvennoye nauchno- tekhnicheskoye izdatel'stvo mashinostroitellnoy literatury, Moskva, 1961, 135 - 138 TM: In circular-flow gas burners, the flow of the hot mixture un- like to straiglr,.-flow burners, takes place yielding an umbrella-shaped ex- panding current in the outer section and a countercurrent Row of combustion products in the central part of the combustion chamber. Under these condi- tions, it is evident that better exchange of heat will be provided due to the flow of high-temperature combustion products in the neighbourhood of the chamber walls. The heat exchange efficiency in the chamber is increased as a consequence of both convective heat transfer of the combustion products and Card 1/3  32727 ,9/671/61/000/000/003/003 Action of circular flow...... A059/Ai26 tion chamber, the relation 0 = 1 1 + 0,03Reo,45 holds for straight flow, and the relation 6 = 1 I + 0,0074ReO,55 for circular flow. Thus, the heat exchange in a circular-flow combustion chamber exceeds that found in the straight-flow chamber by 30 - 40%. There are 3 figurez, and I Soviet-bloc reference. Card 3/3  FEDOROV, L.Fa,. inzh.; SHORIN, S.N., doktor takhn.nauk, prof. Characteristics of flow circulation in evaporating units. Khim. mash. no.3:16-19 K~Je '61. (MIRA 14-51 (Evaporation)   L i647o-6e, 7" EPF(c)/EPF(n)-2/EPR/T/EPA(bb)-., ,,~ Ig'[A(l), Pr-4/#s~/Pu.4 AEDC(a)L ~ . ~SSD/ASD(f) 2/13s, ) AS(Dip)-2 WW.. ~ACCESSIOX NR AmW4625i2 BOOK EXPLOITATI,71 -;-Shorin, Serafim Rikolmovich 'Heat transLe e(Toploperedadha), Moscows W v -0 "Wathaya shkola"I 1964- 1 i 499 p. illus., biblio. Errata slip inserted* 2L.ooo co i6a printed, 0 ITOPIC TAGS: heat transfer ITABLE OF COZITENTS [abridged] !Foreword 4 'rSymbole iPart 1# Principles of.transfer theory, Xh. I. Energy transfer 11 Xh. Ii. Mass transfer 45 !Ch. III. Pulse transfer -- 76 lCh. IV0 Transfer coefficients 98 :Ch. V. Methods of solving transfer problems.,-- 1216 !Part 2. Thermal conductivity and'heat transfer :Ch. VI. General characteristics of thermal conductivity probleaM --149 1,77 ;Ch. VII. Stationary thormal conductivity and heat transfer 161 i Card 1/2 ~  65- L--16470 - - - ACCESSION--NR- I Ch_* -Vill. Nonatatlona~ th 16 uciiiitj 196: or ma onA j Ch. 1X# Temperature wavea -- 241 !Part 3- Convective heat transfer !Ch. X. Principles of convedtive heat tran.afar 259 - ICh. XI. Results of experimental investigation of Convective' heat:. exchange -- 323 ! Ch. 'XII -Heat transfer in_steam_.6ondensation_-_~.:340 -!Ch. XIIL Heat transfer in the boiling of~ - liqdid 361 ;Part 4. Radlation, heat exchange !Ch. XIV. Basic concepts and physical principles of thermal radi ation 379 :Ch. XV. Radiation heat exchange of bodies in a transparent' . medium- ;98 iCh. XVI. Determining the radiation of bodies -- 420 ICh, XVII. Radiation heat exchange in a weakening medium - 7 441 - . IBibliography 484 M :SUB CODE; TD S. ITTED: WanO NR' REr sov: orn OTHER: Oll  ACCESSION NR:' AT4037715 S/2865/64/003/000/0460/0473. AUTHOR: Shorin, S. X.; Dapshia, V. Mi.(DeceaBed) TITLE: The problem of burbing the waste products of vital activity of organisms SOURCE: AN SSSR. Otdeleniye biologicheakikh nau . -Problemy* kosmicheskoy biologii, v- 3, 1964, 460-471 ;TOPIC TAGS: manned space flight, closed ecological system, biological waste ,ABSTRACT: The propagation of a "normal-reaction" front is discussed in which a .front gas reaction is initiated (by preheating and by forming of intermediate products) and completed. The advancing of the normal front is considered a self- repetitioD o- this reaction in time and space, and its possibility is determined -by the thermodyna ics of the reacting system and by mass and energy transfer of the reacting components. A formula is derived Ny using the principle of energy gonservation) for determining the lower limit of fuel-gas-mixture concentration necessary for the self-repetition, and calculated limit-concentration values are compared with experimental values in a table for a numl.er of gases. Equations of mass and energy transfer are used in deriving a formula for calculating the rate of the normal-front propagation. The process is considered to be oue-dimenuionale 1/2  i0i-' tu- c o, v e r s i- n o f r, a t'll ra 1 2 a s f n Scob. AN Gruz . &5T, no .2, .- --2 9- streams. i. lifos':~ovskiy inst.itull kh.4micheskogo, mashinast-royf:ntya Min--sterstva vysslie-c) 1 s-rednego spetsiallnogo obrazovanlya RLT'~R. SuhrnifLed December 2, 1~161,.  I Z T-_;A -1 W, EWA ru r+- /I 6 i SIC0961651WO10021008110086 S N1, Ap ~7,_ HO R3 Te47~~slyants A. (En In6eir miorin Oct or -of tenhnicaj. sciences Frofeasor) M. L ajaw f IGI.r I BE i .11oatt, exchange and friqtionay rouiut Jai U6 SOURCE Teploererget:Uca'-no. -86 2, 1965~,._83 TOPIC TAQSt heat exchangej-~riction, Nusselt, mtrtoer Stantoh~numl)er i -combusti on; ccotloritneter, thermocouple, copper HK I micromanomdt'a~. mT -1 3(4) -A thermometei~ "T 3 It fiom. Studied 'on-.th heat exchan r3. 'Experimental reW ADSTILN, q resistance' during the cooling of t tbd~ou tempera ure s reco of gas flowing at: d dned-_`-'-,-, a pipe with constant wall temperature are'riq36r~,ed# Gas andair a Oterr pres5uxe were cidmitted int6 a combustion chamber. After =6 u-stion. the go .SOB- 1WOj'6__, -berj, aiA then let~out into the.-atmosphere,_~ la sent through a tube calorime Th calor-ift-ber tube was cooled by water.: The heat o!C combustion:-of the gas was -ared V~r a -as calorimeter, before passing the !3 into the ttbei ~The -as-' 0_.~ ga . .11b +~ a:Lr ratio was controlled by a flue gas analyzer installe& at'-th~O---eiA. 'bf the tube calorimeter. The static Dressure was measured b y+ a i d cromanoi~~6r AE-1 (sensi.L ivi jr Card 1/2  7-- nwqberg f ora 4000 to 30000, :Tfia~vaue r f ollol atile., varied from 2A to -3.7l.:'--, Anj -4. irIcal. U' mooth. 1 'for the N'sselt nuinber: for s pipe. =x 0.021 i ru and for rough pipes -~i 0,015 Rev. Nu 'The corresponding values of the St~zton numbers. werd:obtaiia 0.022 Re-9.16. Orig. art. has; 3.3 fonriulas and ASS,N'iATION Moskovskiy institut khimicheskogo Vero ~obtaihed e and cd~4 Chemical Construction Institute" SUMMED: 00 BNOL. 00 SUB CODE TD 'M 110 REY SOV 010 Card 2/2  SUM011, V.I.; SHORIP S.H. Effect of the Introduction of a combustible mixture on the hoat exchange in the coubustim gas chamber. Gas. prom. 10 no.9:35-39 065. OKM ISM)  DULIKIN,M., inzhener; SHORIN,V., inzhener New type of portable metallic props. Mast.ugl.4 no-7:23-24 Jlt55- (Mine timbering) (MLFA 8:10)  .Z)HORIN~ V., kand. tekhn. nauk; YAKIMOV, E., inzh. Reducing the maximum of the elr.~;tric load on feeders. Rech. transp. 22 no.9:21-23 S 163. (MIRA 16:10)  I __ . 1. %- t - ' ' 3- :- - ~ -, :'T ,-,;- .-, .1 n t illb _1 o t " c s Expe-rim...ental stullcly Of and" U-Urapeutic properties of a-1borVcin- ,ovcsti Ned. no. ", 1951. 1 10" 9. Monthly List of Russian Accessions, Library of Congress, /Di~53. Unclassified.   SHORIN, V.A., professor; Tt;RMOL'YEVjt, Z.V. Review of "Antibiotics and their use; collection of experim'ental studies." Edited by Z.V.Ermolleva. Transactions of the Academy of Medical Sciences of the U.S.S.R., vol.22, no.l. Vest.AMN SSSR no-3:60 153. (MIaA 7:1) 1. Chlen-korrespondent Akadamii meditoinakikh nauk SSSR (for Yermollyeva). (Antibiotics)  SHORIN, V.A., kandidat meditsinskikh nauk. Antibiotics and their role in modern medicine. Med.sestra no 5:12-18 My '53. 00-RA 6-5) (Antibiotics )  SHORDT, V. A "Antibiotics and their r-,ractical use." P. N. Kashkin. Reviewed by V. A. Shorin. Milcrobiologiia 22 no. 3: -3147-31419 My - Je 153  SHORIN, V.A. Mechanism of the therapeutic effect of albomycin. 7,hur.mikrobiol lid - i immin. no.3:88 Mr 154. (MTR A 7: 04 1. Iz laboratorii antibiotikov Akademii meditainskikh nank SSSR. (Antibiotics)  SHORIN, V. Reviews and bibliography ("Elements of Bacterial cytology." G.Knaysi, Reviewed by V.Shorin.)' 4ntibiotiki 7 no.1:149-150 '54. NLRA 7:5) (Bacteria) (Calls) (KnaYBi, Georges Abdallah, 1898-  ect of aerobic and anaerobic conditions of growth of antibacterial activity of albomycla.and other an Lotics, W;y,;D~kradv Akad. -Nauk,"Yq; 0 '9,Ld7~~ in at all concris. represses the aerobic metabolism of staphylococcus and Intestinal bacteria but has no cfftct on their anaerobic Metabolism, Streptomycin In therapeutic concns. behaves similarly, while at high concas. it also repm-;ses the anaerobic metabolism. Aurcomycin and clfloromycetin repress bac. terial growth regardless of aerobic or anaerobic conditions of the culture.. G. M. Kosolap.off !7 0~ S JI  SHORINI V. "The sulphonamides and antibiotics in man and animals.* [in linglishl J.S.Lawrence, J.Francis. Reviewed by V.Shorin. Antibiotiki 8 no-3: 125-126 '55- 0MU 8:7) (IAWRENCE, J.S.) (ANTIBIOTICS)  -SHORIN,V.A., doktor meditsinskikh niuk Antibiotics in medicine. Nauka i zhiznl 22 no.8:21-24 Ag'55- (Antibiotics) (MLRA 8.10)  YERMOL'YEVA, Z.V., professor, otvetstvennyy redaktor; j3ILIBIN, A.F., professor; SHORIN, V.A., redaktor; POPRYADUKHIN, K.A.. tekhnicheskiy redaktor [Blowcin; experimental and clinical studies of biomycin] BiMitBin; eksperimentallnoe i klinicheskoe izuchenie biomitaina. Otv.red. Z.V. Ermolleva i A.F.Billbin. Moskva. Gos. izd-vo med. lit-r7. Yol.2. [A collection of articles] Sbornik statei, 1956. 202 p. ()GRA 9:11) 1. Chlen-korrespondent Akademii meditsinskikh nauk SSSR (for Yermollevaj Bilibin) (AUREOMYCIN)  SHORIN, V.A. [translator]; RUZHKOV, V.L., red. EThe ontogenesis of viruses; a collection of papers. Translations] Ontogenez virusov; sbornik statei. Perevod V.A.Shorina, pod red. i a predisl. V.L.Ruzhkova. Moskva, Izd-vo inostrannoi lit-ry, 1956. 278 p. (MIRA 11:1) (VIRUSES)  1e m; I/ - /)-, USSR / Pharmacology, Toxicology. Chemotherapeutic Agnets u-7 Abs Jour :Ref. Zh. Biol., No 2, 1958, No 8098 Author :Shorin, V.A. Inst Title zNew Realms in the Use of Alb,:)mycin Orig Pub ;Antibiotiki, Eksperim.-Klinich. Izuch. M., 1956, 224-226 Abstract :Various data from the literature are given indicating ahigh therapeutic value of albomycin in the treatment of Spiroohetosis aoarina, caused by Borellia sogdianum, It is recommended that albamycin in a physiological solution, or in a 1% solution of cocaine, be Anjected suboutaneoudly, first in large doses and later in gradually diminished doses. A 100,000 u dose of alb6mycin circumscribed exper- imental peritonitis in the rabbit. It acted fayorably on Card : 1/2  11 USSR/hiierobiology. Antobiosis, and Symbiosis, F-2 Antibiotics. Abs Jour Ref. Zhur-Biologiya, No 11 1957, 514 Author V.A. Shorin, 0. K. Rossolimo, E. S. Ku&r_i_ni__ Inst Title On Methods of a Search for New Antibiotics with Antivirus Action Orig Pub Antibiotiki, 1956, 1, No 1, 15-18 Abstract The upper surface of leaves of thorn apple (Datura stramonium. D. alba, D. bArn-I'lax-dii) nna tobacco (NI00-blameL GIIX-bl- nosa) were inlectecl with the virus of tobacco mosaic. Twenty to 30 minutes later an agar block with grown actinomyces was placed on one-half of a leaf. On the Card 1/4  USSR/Microbiology. Antuobiosis, and Symbiosis. F-2 Antibiotics. Abs Jour Ref. Zhur-Biologiya, No 1, 1957, 514 Abstract distance from the blocks. From one strain, antivirubih, an antibiotic which possesses strong antivirus action and which depresses the growth of staphlo- coccus aureus, was obtained. Culture fluids or solutions of antibiotics were mixed with a suspension of influenza A virus. Following a 3 hour period of incubation at room temperature the mix- ture was injected into mice. Of 212- cultured fluids (the largest portion of which was selected on the basis of their action on the virus of tobacco mosaic) 156 (73.6%) had no effect on the influenza virus, while 56 (26.4%) either partially Card 3/4 -------------------------------------------------------------------------------------------------------------------------------------  "Pharmacological Investigation of Colimycin,," by V. A. Shorin, L. Ye. Golldberg, and I. A. Kunrat, Institute of the Search for New Antibiotics, Academy of Medical Sciences USSR, Anti- biotiki, Vol 1, No 5, Sep/Oct 56, pp 8-12 This work reports the results of experiments conducted on white mice, guinea pigs, rabbits, and cats to determine the toxicity and cumulative properties of the antibiotic colimycin and its effect on the central and automatic nervous systems and blood circulation. The experi- ments established the following; the LDr,,, of eolimycin when administered intravenousuly to "white mice was 32-45 milligrans pcv kLlogram body weight; vb-- -1ministered subcutaneously, 260-270 utilligrams per kilogram body weight; colimycin had a depressing effect on the central nervous system of all animals; and it exhibited no cumulative properties; and repeated subcutaneous administrations of colimycin had no toxic effect on the peripheral blood and the blood-producing organs of the guinea pigs. Pure preparations of the antibiotic exhibited nc, pyrogenic )rop- erties. Colimycin was found to have a moderate hypotensive action. Large doses did not intensify its hypotensive action, but prolonged it. It had little effect on the automatic nervous system andin large con- centratiGnS, acted as a mild antihistamine agent.  SHORRI, V.A.,doktor meditsinskikh nauk. . .. ......-------- Antibiotics. Zdorovle 2 no-3:2-4 Mr '56 (MIRA 9:6) (ANTIBIOTICS)  SHORIN, V.A.,; ROSSOLIMO, O.K. Antiviral activity and therapeutic characteristics of the antibiotic antivirubin. Antibiotiki, Moskva 9 no.2,.47-50 Mar-Apr 56 (MLRA 9:3) 1. Institut po izyakaniyu novykh antiblotikov AMN SSSR. (ANTIBIOTICS antivirubin, eff. on viruses & ther. value) (VIRUSES tobacco mosaic virus, eff. of antivirubin) (INFLUENZA VIRUSES, eff. of drugs on antivitubin) (SMALLPOX, virus eff. of antibirubin)  'sn'U'u'r, vak._ (Dr. of Med. !3ci.) "New Fields of Application of Albomycin," Ministry of Health USSR Proceedings of the Second All-Union Conference on Antibiotics, 31 May - 9 June 1957- P. 405, Moscow, Medgiz, 1957.  SHORIN, Y.A.; YLIDINTSEV. S.D.; KUNRAT, I.A.; GOLIDBERG. L.Ye.; PEVZNER, N.S.; - - - -BRAZHNIKOVA, M.G.; LOMAKINA, N.N.; OPARYSHEVA, Ye.F. The new antibiotic actinoidin. Antibiotiki 2 no.5:44-49 S-0 '57. (MIRA 10:12) 1. Institut po izuskaniyu novykh antibiottkov AMN SSSR. (ANTIBIOTICS, actinoidin, pharmacol. (Rus))  r\," ~- I ,\,, , - , A, BRINBIMG, S.L.; TRAKErENBERG, D.M.;:SHORIN, V.A Second All Union Conference on Antibiotics. Antibiotiki 2 no-5: 54-62 S-0 157. (~aRA 10:12) (AliTIBIOTICS)  - - - ~ . I I -" - -~- - '~ " - GAUZA, G.F.; PREOBRAZHENSKAYA, T.P.; KOVALKNKOVA, V.K.; ILI ICERVA, N.P.; BRAZUNIKOVA, M.G.; LORAKINA, U.N.; KOVSHAROVA, I.N.;-AHORIII V.A.; KUHRAT, I.A.; SHAPOVALOVA, S.F. Grystallomycin, a new antibacterial antibiotic [with aummary in Nnglish]. Antibiotiki 2 no.6:9-14 H-D 157. (MERA 11:2) 1. Institut po izyslmniyu novykh antibiotikov AMN &SM. (AliTIBIOTICS, preparation of, crystalloaWein, prod. f~-" Actinomyces violaceoniger (RUB)) (ACTINOMYCES violaceoniger, prod. of antibiotic crystallon7cin (Rm))  BRAZHNIKOVA, M.G.; KOVSHAROVA, I.N.; GAUZE, G.F.; SVESHITIKOVA, M.A.; BQBKOVA, T.S.; SHORIN, V.A.; ROSSOLIHO, O.K. Coeraloc7cin, a new antiviral antibiotic produce-d by Acti=qces coerulescens [with summary in English]. Antibiotiki 2 no.6:16-20 N-D '57. (MIRA 11:2) 1. Institut Do izuBkaniyu novykh (ACTINOMYGES, coerulescensq prode of (RUB)) (ADTIBIOTICS, preparation coerLilomycin, prod. by antibiotikov AMN SSSR. antiviral antibiotic coerulor7cin of, Actinomyces coerulescens (%s))