SCIENTIFIC ABSTRACT VULIS, L.A. - VULIS, L.A.

Transactior.-i oA the Confererce (Cont.) SOV/52'~, Vulis, L.A. On the Circular Motion of a Viscoun Gas 2~1~7 Mironenko, T.K. Effect of the Local Distribution of Fnergy in a High Velocity Flaw of Gas 215 Lifshits, A.G. Flow of Boiling and Hot Water Through Conical Vozzlec 215 Radchenko, G.A,, and P.V. Belotorodov. Concentration Fields of Highly Dispersed Aerosols in Air Conduits 223 Contents of the Discussion in Brief 229 Decisions of the Conference 231 AVAILABLE: Library of Congress Card 9/9 AC/m/nas 7-29-61  MZE I BOOKmaWITATICK 80V/5179 Alma-Ata, Kazakhatim. Univerniteto Issledovaalys prottiessov perenotao Voyroey teorli crtnositellnocti (Study of Trans- fer Processes, Problems in the Theory of Relativity) Alns-At&., 1959. 236 p. Errata slip Insertedo 1,000 copies printed. (Series: Its Trudy) Sponsoring Agency: Ministerstro vysshego obrazoveniya SSSR and Knakaskiy gosudarstvennyy universitet Im. S.M. Kirovs.. Editorial Board: V#P# Kashkarw, N9D# Kosoy.. and N.Me Petrova; Reap* Ed.: L.A. Vu3is; Tech. Ed.: L.D. KashkAzov. PURPOSE: This collection of a2ticles Is intended for research physicists and engi- neers. It can &1so be used 17 instructors and students at universities. COVEWN: The articles of this collection contain the results of 19 studies in transport problms and the goneral. theory of relAtivity made fi'= 1956 to 1958 by the staff of the kafedra obshchey fiziki I teorpticheskoy fiziki Kazakhokogo universitsta im. S.M. Kirova (Department of General Physics and Theoretical CdrA_*  Study of Transfer-Processes (coat.) SOV/51T9 Physics of the S.M~ Kirov Kazft State University)# The articles axe arranged in two groups. Group one contains 16 articles concerning the research activity of the teplofizicheskaya laboratoriya pri kafedre obshchey fiziki (Heat Physics laboratory of the Department of General Physics) in the investigation of trans- port processes ar matter, impalse and energy; group tvo contains three articles reporting on studies of the Department ol' Theoretical Physics on problems of the theory of relativity. Article one of the collection is an introduction and re- vievs the problems of tranpport processes and gives a fairly detailed bibliog- raphy of contributions of members of physics department of Kazakh State Uai- versity. No personalities are mentioned. References accompany each article. TABLE OF CON Fron the Editor 3 I, INVESTIGATION OF TRANSPORT PROCESSES Vulis, L*Ao Contribution to the Investigation of Transport Processes 7 -------------) Card2 /5  Study of Transfer Processes (Conte) SOV/5179 Vuliss L.Ao Critical Regime of a System With Sources 16 VM4eL L*Ae, and A,Ae Kostritsaa Problems of Similarity and of Simulating Transport Processes in Nuclear Reactors 28 Isayevp Me Electric Simul tiag of Neutron Transport Process and of the Critical State of a Nuclear Reactor 43 Vulisp L.A., and A.T. Luklyanov. Electrostatic Integrator 65 Klinger, VOG., an& V.V. Ronzhin. Simulation of Light Produced by Gamta Radiation From a Cyclindrical Source 69 Dubovik,,.IOI*,, and V.G. M.Inger. Light Exchange Betvaen Kirror and Diffuse Sinlaces 97 Koeov, NeDo Application of the Normal Thermal Regime Metho& in the Determination of the Coefficient of Diffusion of Liquids 101 Card .36  10(2) 3, -7 PHASE I BOOK EXPLOITATION SOV/2271 Soveshchaniye po prikladnoy gazovoy dinamike. Alma-Ata, 1956 Trudy (Transactions of the Conference on Applied Gas Dynamics) Alma Ata) Izd-vo AN Kazakhskoy SSR, 1959. 235 P. Errata slip inserted. Sponsoring Agency: Kazakhskiy ~gosudarstvennyy universitet imeni S.M. Kirova, -Ed.: V.V. Aleksandriyski ;,Tech. Ed.: Z.F. Rorokina; Editorial Board: L A- Yulis (Resp. Ed.;~, V.P. Kashkarov, T.P. Leontlyeva, and B.P. U;timenko. PURPOSE: .'This book should be of interest to scientists and engineers working on problems of applied gas dynamics and may be of use to students. COVERAGEi This book presents reports grid brief summaries of the dis- cussions which took place at the Conference on Applied Gas Dynamics in Alma-Ata in October 1956. The conference was subdivided into three areas'of applied gas dynamics: jet flows of fluids and gases, the Card 1/8  Transactions of the Conference (Cont.) SOVA271 aerodynamics of heating r..!rocesses, and the discharge of a fluid. The practical value of the "Transaotionf3 of the Conference If consists in the development of theory, methods of technical cal- culation and m~athoda for systematic measurement applied to heat- ing, furnace, and other industrial processes for which, in most oases, aerodynamic phenomena are decisive factors. TABLE OF CONTENTSt From the Editorial Board Session of October 23, 1956 Abramovich, G.N. Turbulent Jets in the Flow of a Fluid 5 Ginzburg, I.P. On the Discharge of Gases.~rom Vessels Through ,Pipes.With Friction and Local Resistances 17 Card 2/8  Transactions of the Conference (Cont.) SOV/2271 Vulis, L.A; Basic Results and Further Problems in the Investiga- 1,r6-n---uf--Tet-like Motions of Fluids and Gases 29 Isatayev, S.I. On the Turbulent Wake Behind a Body in a Two- dimensional Flow 39 Brief Summary of the Discussions 44 Session of October 24, 1956 (morning) Antonova, G.S. Investigation of the Turbulence Characteristics of a Free Nonisothermal Jet and on Open Torch 45 Kashkarov, V.P. On the Mot1on in the Same and in Opposite Di- rections of Two Uniform Compressible-gas Flows 55 Leontlyeva., T.P. Propagation of Axially Symmetrical Jets in Flows in the Same and in Opposite Directions 62 Card 3/8  Transactions of the Conference (Cont.) SOV/22(1 Bukhman, S.V. Laws of Motion and Iaws of Combustion of Carbon Particles 69 Nazarchuk, M.M.,and N.I. Pollskiy. On the Critical Conditions for the Flow of a Viscous Gas in a Plane-parallel Channel 69 Brief Summary of the Discussions Session of October 24, 1956 (evening) 75 Terekhina, N.N. Propagation of an Axially Symmetrical Gas Jet in a Gas Medium of Any Density 77 Chebyshev, P.V. Electrothermoanemometers From 'VVI (All-Union Electrotechnical Institute) and Their Use in the Investigation of Nonisothermal Gas Flown 85 Trofimenko, A,T. Investigation of a Semibounded Jet 100 Card 4/8  Transactions of the Conference (Cont.) SOV/2271 Akatnov, N.I. Survey of Articles on Jet Theory by the Chair of Hydro- and Aerodynamics of the Leningrad Polytechnical Institute imeni M.I. Kalinin . 107 Shepelev, S.F., and S. Tsoy. Two-dimensional Jet in the Cross Section of an Air Duct 108 Bespalova, V.0% Use of Hydrodynamic Calculating Machines for the Solution of Jet Problems 115 Brief Summary of the Discussions 122 Session of October 25, 1956 (morning) Katsnellson, B.D. Some Problems in the Aerodynamics of Cyclone Combustion Chambers and the Combustion of Coal Dust 123 Ustimenko, B.P. Aerodynam:Lcs of,Twistod Jets and Cyclone Chambers 134 Card 5/18  Transa--tions of the Conference (Cont.) SOV/2271 Volkov, Ye.V. Some Problems in the Aerodynamics of a Two-phase Flow in a Cyclone Furnace 142 Tonkonogiy, A.V., and I.P. Basina. On the Working Process in a Cyclone Chamber 152 Yakubov, G.V. Generalization of the Aerodynamic Laws of Cyclone Chambers 158 Brief Summary of the Discuissions 158 Session of October 25, 1956 (evening) Reznyakov,, A.B. Direct-flow Pulverized-coal Torch 160 Telegin, A.S. Combustion Laws of a Clas Torch 16o Yershin, Sh.A. Aerodynamios of a Turbulent Gas Torch 168 Card 6/8  Transactions of the Conference (Cont.) SOV/2271 Kokarev, N.I. 3!ndustrial Testing of New Ports for Siempns-Martin Gas Furnaces .11 178 Bogdanov, Ye.P. On the Thermodynamics of the Gasification Process 186 Brief Summary of the Discussions 186 Session of October 26, 1956 Zhulayev, R.Zh. Survey of the Work on Hydrodynamics Done by the Electric Power Institute of the Academy of Sciences of the Kazakh SSR 187 Romanenko, S.V. (Deceased). Basic Problems of the Thermody- namics of Flow for Real Boundary Conditions 197 VuliB, L.A. On the Circular Motion of a Viscous Gas 208 Card 7/8  Transactions of the Conference .(Cont.) SOV/2271 Mironenko, T.K. Effect of the Local Redistribution of Energy in a High-speed Gas Flow 215 Lifshits, A.G. Discharge of Boiling and Hot Water Through Conical Nozzles 215 Radchenko, G.A., and Beloborodov, P.V. Fields of Concentration ot Highly-dispersed A erosols in Airducts 223 Brief Summary of the Discussions 229 Resolutions of the Conference on Applied Gas Dynamics Held in Alma-Ata, October 23 - 26, 1956 231 AVAILABLE: Library of Congress IS/Sfm 10-6-59 Card'8/8  S/194/61/000/009/011/053 D222/D302 Poo a AUTHORS: Vulis, L.A. and Luklyanov, A.T. ._1. TITLEt Electrostatic integrator PERIODICAL: Referativnyy zhurnal. Avtomatika i radioelektronika, ru)* 9t 1961, 15, abstract 9 B100 (V ob, Issled. pro- t ssov perenosa. - Vopr. teorii otnositellnosti, Ata-Ata, 1959, 65-88) TMETi The operating principles of an integrator intended for solving partial differential equations of the heat conduction type are described. The main operating part is a collection of cap- acitors which imitate a discrete (finite-difference) representation of the problem. For this purpose a definite number of elements form part o the integratort each of them corresponding to a certain part of the physical systera investigated. An element consists of two series connected capacitors which are in turn connected to ad- Jacent capacitors; one switching cycle corresponds to one unit of Card 1/2  S/194/61/000/009/011/053 Electrostatic integrator D222/D302 time interval. The system provides for the npecification of sources, and for solving problems with variable coefficients. The theoreti- cal circuit diagram of the device, containing in addition to the 0 switch, stabilized supplies and measuring instruments, capacitot4w is described. Extimples show how the problem of co ling plates is solved. 11 figures. 2 tables. 11 references. ?=tracter's note: Oomplete translation-7 Card 2/2  VULIS, L.A. 0-0---ft pulsation of temperature on the rate of turbulent combu-stion. Izv.AN Easakh.SSR. Ber.energ. no.1166-70 159. (yraA 12: n) (Combustion)  VULIS. L.A.; BJ'. -;"PA Calml,ttim-, hent trvnef-r to liquid ritals, 12-/. AN 35R. S,.)r. onor!,. ne.2CUT-110 159. (I'Val 12:,71 (Hoat tranamisision) (Liqiild mehle)  VULIS, L.A.; XOSM-RI'.'SA, A.A. lor- oP dlff,-sion of neutrons an6 st,te Ryeranllc arki - I of r, wiclear reactcr. P.?-Port N'o.l. Izv. VI Xmzakch. SM. no.2:111-127 '59. (1-URA 12-:7) (Nuclear reactors-I'lectronechanical anal(,rion)  IrIjj,JS, L.A.; KOGILTITSA, L.A. ~ - " -Mrat -31 cf -no eiff-,Esion of routrons and crl'lzal ff. tMe analof, A ~ - v ot ~ t,~ of' nuclear reactcpr. Repor,14 :7o.1. Izv. AN Fazgkb. GO. Sei.enez.?. no.2:12cQ-138 150. (?!IR~ 12:7) (ITuclear rarctore-Elactromuchanical analoTios)  67148 SOV/31-59-9-8/21 AUTHORS: Vulis, L.A., Isayev, N.U., and Luklyanov, A.T. TITLE: Static Analog Devices ly PERIODICAL: Vestnik Akademii nauk KazSSR, 1959, Nr 9, pp 53-58 (USSR) ABSTRACT: The article deals with an entirely new type of analogs,, the static electrointegrators (SEI). Having been un- der development at the Problemnaya tep'Lofizicheskaya laboratoriva Kazakhskogo universiteta (Laboratory 'or Thermal and Physical Problems of the Kazakh University) since 1957, they greatly simplify the computing methods and at the same time widen the scope of problems to be investigated. The static eloctrointe-grators have al- ready been used for computing diffusion, of neutrons as L) well as for solving nonlinear problems pertaining to the theories of heat conductivity and hydrodynamics (Figure Card 112 2). The article also mentions two additonal SEI mode  67148 Static Analog Devices and 10 Soviet. SOV/31-59-9-8/21 the first being practically an electric analog of D. V. Budrin's hydrostatic integrator and the second an ,~SEI with an ohmic-type, movinE computor devicd (Figures 3 and-4). The latter has a Creat advantage as it can make calculations by dividing the space-time component into as many elements as desired. In addition to this, the SEI with an ohmic-type moving computor device has small dimensions, its only bad point being the neces- sity to make intermediate entries. The article also mentions the Problemnays. laboratoriya kafedry obshchey fiziki Kazakhskogo universiteta (Problem Laboratory of the General Physics Faculty of the Kazakh University). There is 1 graph, 1 set of graphs, 1 set of hookups, 1 photograph, and 12 references, of which 2 are American Card 2/2  VULIS).L -- A.-,.KASWMOV,IV.- P.' (Alm-Ata) "Boundax-j Layer of Compressible Gases on the Surface of a Burning Body." report presented at the First jUl-Union Congress on Theoretical and Applied Mechanics, Moscow, 27 Jan - 3 Feb 1960.  VYLIS, L. A. =TY-EV, S. I., KMIM~RV) ~V.P. "The Propagation of Viscous Streams (Jets) On the Surface of Bodies." report presented at the First A.U-Unlon Congress on Ilieoratical and Applied Mechanics, Moscow, :217 Jan - ~3 Feb 1960.  VULIS, L- A., USTIMENKO) B. P.) BESPALOVA) V. G. (Alma-Ata) "Liquid-Flow Analogy in the Treatment of Proble= Concerning the Propagation of Turbulent Jets." report presented at the First All-Union Congress on Theoretical and Applied Mechanics, Mm cow, 217 Jan - 3 -Feb 1960.  VULIS, L.A., otv. red.; KASEKAROV, V.P., red.j KOSOV, N.D., red.j FE14YA, N.M., red.; KASHUMV, L.D.0 tekhn. red. (Study of transfer processes. Problems in the theory of relativity] Iseledovanie protsessov perenosa. Voprosy teorii otnositellnosti. Alma-Atal Uchped i Kazakhskoi SSR. 1960. 161 p. (Its Trudyt no *2) %RA 17:3) 1. Alma-Ata. Universitet,  31293 S/124J61/000/010/028/056 D251/D301 AUTHOR: Vulis, L.A. TITLE: On the role of temperature pulsation in turbulent combustion PERIODIC.4L: Referativnyy zhurnal. Mekhanika, no. 10, 1961, 83, abstract 10 B594 (V sb. 3-e Wes. soveshchaniye po teorii goreniya, v. 1, M., 1960, 91-99) TEXT: The influence of pulsations of temperature and the connected pulsations of speed on the process of turbulent combus- tion is considered. Making use of the theorem of K.I. Shchelkin an surface combustion, the author constructs a model for calculating the time of complete combustion in a turbulent flow of a homogeneous mixture, and obtains the relation of dependence of the time of com- plete combustion and also (for a known dependence of the time of complete combustion on various factors) the dependence of the dim- ensions of the zone of complete combustion, the velocity of flame- Card 1/2  Ori the role of temperature... 1 93 S/124 61 000/010/028/056 D251 301 spreading and the evolution of.heat on the turbulent pulsations of temperature and velocity. The theoretical dependence is satisfac- torily confirmed by known experimental data. 13 references. Z-Abstracter's note: Complete translation_7 Card 2/2 1  ~ VULIS9 L.A. .Calculation of turlxlent free flow by the use of the equivalent problem of the theory of beat conductivity, Izv. AN Kazakh. SSR* Sere energ. no.2:60-67 160. (NIRA 14:3) (lets-Fluid dynamics)  JLRTnJKHI L.; ry~Is, L.A.; VSTI14EMp B.P. Hydrodynamic theory of heat transfer applie& to liqmids with suall Prandtl numbers. Jzv.AV Kazakh. SSR Ser.energ. no.2:76-89 160. (.MIU 13:7) (Wdrodynamics) (Heat-TrangMiSl3iOn)  2%12 8/137/6 IAW/006/00 1/1092 A A0061AI01 AUTHORS: Vulis, L.A., Kashkarov, V.P. TITLEs Heat 6onditions of the boundary layer during heterogeneous combus- tion PERIODICAL: Referativnyy zhtumal. Metallurglya, no. 6, 1961, 1, abstract 6B1 (V ib. "3-ye Wee. soveshchanlye po teoril gorenlya, v. 2, Moscow, 1960, 98 - io6) TMt The authors solve,d a system of equations for a flat laminar boundary layer of compressible gas, consisting of equations of motion, continuity, energy, diffusion and state, Dependences were obtained which made it possible to find the distribution of velocities, temperature and oonoentration, and also Ignition and extInotion oonditions In the boundary layor for a pltto pasafd around by a homogeneous flow of visoous gas. An analogous problem for the jet flow aro-and a oone 1.3 briefly mentioned. The euthors preafint eorrelations bet;Nevn two diman. aionloss parameters d dotermining the combustion proce3s, for 2 different types of prooess, i,e, a hysteresie" and a "non-orials" procoss. For the rapid motion Card 112  25743 S/M/61/000/012/036/02 A604IA101 AU OR i Vulis, L. A.1 Yershin, WSh.A. TITLE: On the aerodynamical theory of the gaseous tongue of flame PERIODICAL: Referativnyy zhurnal, Mashinostroyaniye, no. 12, 1961, 22, abstract 121180 (V sb. "3-.,re Vaes..soveshchaniye po teorii goreniya. v. 2". Moscow, 1960, 219-227) TMi The authors present a brief survey on Investigations of the aero- dynamical theory of the gaseous tongue of flame based on the idea of an infinite reaction rate of combustion. This assumption leads to a scheme of diffusion combustion as in.the case of both unmixed gases'and homogeneous mixtures. The latter! 6ase is Investigated in. detail. If for the case. of combustion of unmixed gases the equation system is complete, since the flame front Is found from the stoichiometric relation of the,flows of the reacting-,oomponents, an additional assumption on the position of the flame front is necessary for the flame tongue of a homogeneous mixture. In oiqer to solve this problem, the condition of the gas-dynamic scheme.of the flame front Is taken as an oblique heat discontinuity. In such a scheme thi whole range of flame tongue is replaced by the surface of Card 1/~  25743 S/123/61/000/012/036/042 On the-aerqdynamical-theory ... A004/A10l discontinuity in the.velocityj -temperature, mixture composition, eot. Equations bf.-pontinuity,.momentum and -energy-are written down, and*.the dependence- is darlyod'.of the gAs-dynamia parameters on angle C4,1 - the slope of the flame front relative., to. the inormal to the I.Lnes of the flow, up -to the discontinuity. It is assumed,thati the solution sought-for,is taking-plaee at-the maximum,deviation angle of.the~lines,of-the flow in the discontinuity.. At a-given heat rslease_ oharatterlalle (ratio-of-the thermal egfoot to the initial enthalpy) of the order 5-7 the magn itude of 0~1 is near to 70 . In this case the angle of slope of the flame front does not depend on the flow velocity and'only slightly depends on the heat releasq characteristic. A comparison of these results with the test data shows that.actually, as-this follows also from the "aerodynamical scheme", a certain warming-up of the fres'n mixture, its expansiori and a deviation of the lines of the flow to the flame fr nt can be always observed. Owing to this a value 3 Is obtained D, ~ner with an ordinary flame front, while with at the 19~ stabilizer) value U - 600. The authors an nverted flame (behind the i analyze the problem of an Increased flow velocity behinA the flami front. Also in this case the conception of an oblique heat discontinuity was used and experi- mental checks were carried out. From a nozzle 20 mm in diameter across which a stabilizer (1.5 mm diameter wire) was fastened, a jet of gasoline vapors and air Card 2/3  25743 8/123/61/000/012/036/042 On the aerodynamical theory ... A004/A101 mlied beforehand'flowed vertically upwards. With the aid of a special feeder .fine quartz sand was fed into the flow, which was photographtd when streaming o"U't'from the nozzle. The particle speed behind the flame frc,)nt was determined from the length of the trajectory and photographic exposure.~ It was found that during the passing of the flame front the speed increased by a factor of 1.5 which agrees with the theoretical results, There are 4 figures and 23 references. Sh. M. S. [Abs~raoterls note: Complete translatio.n) Card 3/3  VULIS; L.A.; CRUSHAN.Ux Lei. A-okbn. red. [Overlapping of molectlar and -molar effects In the transition region of a flow; Conference on Beat and Mass Transfer,, 11insk, June 5-1C, 1961] 0 vz&i=na1ozhonii moleku3,iarxqkh i moliarrykh effektorv v perekhodzioi oblasti techeniia; soveshchanie po teplo-i massoobmanu, g. 1-finsh,, 5-10 iiunia, 1961 g. Minsk, 1961. 16 p. (MIRA 15:2) (Hydrodynamics) (Heat-Transmission) (Mass transfek)  VULIS, L. A., RDSHX4R-vV) B. P.j, YARIN, L. P., and ARITM, L. Y. "Thexmal Problems of a Boundary Layer at Heterogenous and Diffusive Canbustions." Report submitted for the Conference on Heat and Mass Transfer, Minsk, BSSR, june 1961.  VMTS,. L..-A - 1. qO44VA)- T.* 1,.*j* PAIATNTK).1..B..).SAMOV)IZ.. B..) AXD USTDMW~ B. P. "Thermal Problems of a Free (stream) Turbulent Boundary Layer." Report submitted for the Conference on. Heat and Mass Transfer, Minsk, BSSR, June.1961.  VULIS, L. A._j ZHEREBYAT-EVj .1. F. and LUK-YANOV, A. T. "Solution of Non-linear Equations of Thermal Conductivity by Static Electrical Integrators." Report Bubmitted for the Conference on Heat and Mass Transfer, MinBk, BSSR, June 1961.  VULTS, L. A. ff0p Superposition of Mole.-ular and Molar Effects In the Transient Region of a Flow." .Report submitted for the Conference on Heat and Mass Transfer, Minsk, BSSR, June 1961.  87758 slo96161100010021011JO14 C9~'5'~7-00 llql /,~~7) E191+/EI55 AUTHORS: Doctor of Technical Sciences) G-urvien, A,M,l Doctor of Technical Sciencos, and Klineer, V.0.1 Candidate of Technical Sciences TITLE: Optical Modelling of Radiant Heat Exchange in Furnaces PERIODICALt Teploenergetika, 1961, No.2, pp. 67-71 TEXT: The general theory of similarity requires than an optical model should fulfil the three conditions: geometrical similarity; identity of optical properties of surfaces and media; and similarity in the distribution of radiation sources. A special feature of the optical modelling method developed in the Kazakh University is that it avoids fulfilling the third condition by determining on the model a system of optical-geometrical parameters. When these are known it is possible to calculate the distribution of radiant fluxes with an arbitrary distribution of sources in the system in which only the first two conditions need be observed. Thus the technique of op'(,4ical modelling is greatly simplified. The object of the present article is to direct attention to this method which is still not sufficiently widely used. Accordingly, Card 1/6 qr  87758 B/096/61/000/002/011/014 E19VE155 Optical Modelling of Radiant Heat Exchange in Furnaces ,the essentials of the method are described and practical results are given, In optical modelling of radiant heat exchange the radiant fluxes are so low that the temperature factor does not enter into the experiment. The method is nevertheless applicable to studies of furnaces where heat fluxes and temperatures are high, because the equations of radiant heat exchange are the same whatever the energy or spectral composition of' the radial fluxes. The temperature distribution is determined in the model by the self-radiation distribution both in the volume and on the walls. From this the temperature distribution is calculated on the basis of the Stefan- Boltzmann law if an integral radiation is modelled; or by Wien's formula if the nature of radiation is being studied from separate spectral bands. The present article considers only integral radiation and assumes that the radiating walls and media have the properties of grey diffuse radiating and absorbing bodies. In modelling, the object is sub-divided into a mimber of surface and volume isothermal zones. The optical properties of the surface zones are characterised by the mean absorption capacity and those Card 2/6 11K  A77-48 S/096/61/000/002/011/014 E194/E155 Optical Modelling of Radiant Heat Exchange in -Furnaces of the volumetric zones by the attenuation factor of the medium. Modelling consists in constructing a geometrically similar system of surfaces having optical properties identical with the original and a similar distribution of isothermal zones. The attenuating properties required of the medium are discussed. The method is based on the principlar of' additivity of radiant fluxes which makes it possible to determine the optical-geometrical parameters of the model. If only one surface zone in the model is radiating, the incident flux on different elements of surface can be measured. These incident fluxes will be both those received by direct but attenuated radiation and those reflected from other surfaces. By successively making one zone luminous after another and measuring the resultant incident fluxes, dimensionless absorption factors may be determined for various elements considered. Then the results are summated to determiner the flux density incident on any zone from all the other zones. Simple formulae are derived and it is dhown that by tests on a single model and simple calculations it is possibla to solve a range of problems. The study of radiant hoat Card 3/ 6 ~4r  87758 S/096/61/000/002/011/011+ E194/9155 Optical Modelling of Radiant Heat Exchange in Furnaces exchange in the chamber of a stoker-fired furnace by optical modelling is then considered. A transparent plastic model in the shape of a cube of side 15 cm inside contained thin metal walls painted matt black. In one of the walls there were 64. holes which were used to measure the incident radiation. Various difficulties that arise in malting the measurements are described. Experience has shown that they can be largely overcome if a thin layer of translucent celluloid with a matt surface is placed between the inner wall of the model and the outer. As incident radiation may be at any angle, the sensitivity of the pick-up should not depend on the angle of incidence, This condition is largely satisfied by a germanium photodiode operating as a valve. This photodiodo has maximum sensitivity In the infrared where the absorbing capacity of ordinary water 13 fairly great. Accordingly water may be used as the attenuating medium in the model. The problem of modelling self- radiation of the medium filling the volume is overcome by having a single source of radiationg moving it from place to place and summating the results. The particular model described was divided Card 4/ 6 ~e  87758 s/o96/61/oOO/002/011/014 El9'+/Rl55 Optical Modelling of Radiant Heat Exchange in Furnaces into 61f zones. The radiating element was a cube of transparent plasticp corresponding accurately to the size of the zone. The cube contained a small lamp; it was filled with water and the outside was covered with translucent celluloid. To check the experimental procedure a model was used to study the radiant output of a cylindrical source for which a method of calculation exists. The calculated and experimental results_a reed within 5% and the accuracy could easily be increased to 2 W The burning layer of fuel was represented by a flat illuminator with uniformly luminous matt surface. The measurements were made and for each unit of sub-division a table of 64. local values of absorption factor was drawn up. There was no need to make 64 such tables; because of the symmetry of the model only 16 were required. The tables were then used to calculate absorption factors from formulae (3) and the distribution of incident; fluxes on the walls of the model was determined for the case of a uniformly radiant medium and a fuel layer. Examples of radiant flux distribution of the model were plotted. Attention *.ias recently been drawn to radiation Card 516  87758 S/096/61/000/002/01.1/01)r E19VE155 Optical Modelling of Radiant Heat Exchange in Furnaces back from the screen tubes. Accordingly the difference between the actual operating conclitions of screens and those which are usually assumed was investigated. A study was made of the influence of the degree of blackness of the screen tubes on the heat exchange conditions in furnaces. The method of setting up :the model to do this is briefly described and comparative data for tubes,with absorption factors of 0.6 and 0.9 shows that alteration of the degree of blackness of the screen tubes has no important influence on the radiant heat exchange in the case considered. Results obtained in tests on the optical model with almost black surface were compared with calculated values for absolutely black tubes and agreement was good. Ways in which the procedure may be further developed are discussed and it is recommended as a useful aid in calculations of beat exchange. There are 3 figures, 1 table and 11 referencest 7 Soviet and 4 English. ASSOCIATIONs Kazakhskiy universitet i TsKTI (Kazakh University and Central Boiler Turbine Card 6/6 lnstjtute~  89925 3/170/61/004/003/003/013 B117/B209 0 0 AUTHORSt Artyukht L. Yu., Vulie, L. A., Kashkarov, V. P. TITLE: Flow of gas around a plate with burning surface PERIODICAL: Inzhenerno-fizicheakiy zhurnall v- 4, no. 3t 1961, 39-45 TEM The authors investigated the flow of a homogeneous compressed gas around a burning plate. The variation in velocity, temperaturep and concen- tration profiles along the plate was considered in the approximation ob- tained. The studies were devoted mainly to laminar flow in the boundary layer along the plate. In order to find the "quasi-progreasing" profiles u, T, and c, solutions of transcendental equations of the heat theory of com- bustion are used, which are reduced to the boundary conditions on the Bur- fave of reaction. For this purpose# the boundary conditions of the surface of the plate are transformed into the form usually employed in problems of the thermal conditions of combustion. The transcendental equation (8) from Ref. 6 (vulis; L, A. Teplovoy rezhim, goreniyaj GEI, M. -L., 1954) r/[r + ex ( /Ow) (1/vl)[Ow - X0oD+pT(6w -1 00 0j was graphically solved Card 1/1  89925 S/170/61/004/003/003/013 Flow of gas around ... B117/B209 in a +-19, plane. Figs.'l and 2 illustrate typical results of these solu- tions. The schematic representation of the graphically determined results (Fig. 1) gives a clear picture of the dependence of the surface temperature on the velocity of the incoming flow, when the parameters of heat exchange A and of the length x are given and various values of heat generation 4>3 3>.92>'91 - 0 are ass=ed (B - point of ignition, n-point of extinction, A and T - adiabatic and heat exchange, reopectively). When the values of heat generation are given for two velocities of the incoming flow, the tem- perat'ure variation along the burning plate shows (Fig. 2) that ignition of the plate takes place, if any at a certain distance from the front edge of the plate. The values of temperature 0 and of concentration cw determined by a graphical solution of Eq. (8) accowrding to the coordinate xf make it possible to construct the profiles of u, T, and c in the cross sections of the flow if all the other parameters are given. Fig- 3 shows the profiles for two cross sections (before and after ignition) as an example of such a construction. It was further shown that the state before ignition belongs to a kinetic combustion according to the nature of the process, and after ignition to the diffusion zone, This result is typical of a hysteretic Card 2/4  S/170/61/004/003/003/913 Flow of gas around ... B117/B209 process of an exothermic heterogeneous reaction if combustion takes place only in the vicinity of the diffusion zone. The authors point out that, in principle the obtained solution may be generalized to the case of a burning plate with a turbulent boundary layer. More details about this case will be published in a special paper. From- the prac-tical standpoint, the present problem has to be treated as one of the limiting schemes of ignition and burning of bodies which move at high speed through the atmosphere. Mention is made of Dorodnitsyn, Ya. B. Zel'dovich. There are 3 figures and 7 refer- encest 6 Soviet-bloc. ASSOCIATION: Kazakhskiy'gosudarstvennyy universitet, Alma-Ata (Kazakh State University, Alma-Ata) SUBMITTEDt June 21, 1960 Card 3/4.  27242 S/17 61/004/009/001/013 0 BI 04YBI 25 AUTHORS: Vulis, L. A., Palatnik, I. B. TITLE: Mechanism of turbulent mixing in gas flows PERIODICAL: Inzhenerno-fizicheskiy zhurnal, v- 4, no. 9, 1961, 5-11 TEXT: The experimental arrangement shown in Fig. I was used to study the turbulent mixing of a gas jet with a gas flow of different temperature. The limits vith~n which the parameters of gas jet and Cas"flow were varied, are listed in Table 1. In their experiments, the authors determined the velocity head and the temperature distribution along the axis and over the cross section. The velocity head was measured with a Pitot tube 0.8 mm in diameter, and the temperature was determined by means of a platinum - platinum rhodium thermocouple. The turbulence of the gas jet and of the Eas. flow at the exit section of the nozzle was measur6d by means of !in 9TAN-3A (ETAM-3A) electrothormoanemometer. The flow velocities .,ere computed from measurenento of Qu2 and AT. As characteristics for the intensity of turbulent mixing at a given point of the flow, tho following relations were used F_. 1 - (Qu2 )m/(Qu 2)0and Card 114-3  272,42 S/17 61/004/005/00,11/013$ Ecchaniam of turbulent mixintr ... BI 04Y111 25 0 I - (T.A - T )/(T - T Yj where the subscript m refers to the axis of T n 0 n the jet. These characteristics tend toward zero ift'thd absence of mixing and toward unity with complete mixing, The authors determined-the function 6 T = f (m) , where (M2 _ .(Qu2)0); it may be seen, from ihis function that at any given distance from the mouth of the nozzle, the quantity 1 - IT and consequently, the conditions for a minimum mixing of the jet with the flow practically coincide at m - 1. In this case, jet and flow have the same velocity. The decisive role played by the density of the pulse flow in turbulent mixing may be seen from 'the function F, T . f(m). Measurements were then obtained at one and the same point on the axis of the jet (x/do - 51 x is the distance from the mouthpiece of the nozzle, and do is its diameter) at different temperatures. The relative disposition of the curves E T . f(m) indicates Uat the damping rate of the Jet varies with increasing temperatures The decrease of the quantity AT M/,OTO and also of um/U0 with Q. T 0/T n> I i e greate r than wi th Q fZo 1 .On the basis of the "similarity of QU211 it is shown that a universal dependence of (Qu 2 )MAQU 2 Card 2/6  27242 S/170/61/004/009/001/013 Mechanism of turbulence mixinj; ... B104/B125 on x1do on the axis of the jet is confirmed by the results of measurement. 2 2 Moreover, it wus --found that the quantity (Qu /Qu~) drops the more, the m 0 higher is the temperature or the -as jet. The mixing process accelerates slowly and continuously withr.). 711ith slight heating the level of pressure pulses rose f rom 1 -2~j at t_; - I to 10-1 2~f3 at I-) - 3; with intense heatinc, valueo of 3-4 and 12-1r" viere obtained at the analogous values of (a G. 11. Abramcvich is mentioned. There are 4 figures, 1 table, and 7 Soviet references. ASSOCIATION: Institut energetiki All KazSSR1 C. Al.ma-Ata (Institute of Power Engineering AS Kazakhskaya SSR, Alma-Ata) SUBMITTED: June 21, 1960 Fig. 1: Schematic representation of the experimental arrangement. Legend: (1) Outer tube; (2) inner tube; (3) nozzle for the central gas jet diameter, 10 mm); (4) nozzle for the outer gas flow (diameter, 250 mm); 5) air intake for the inner tube; (6) centrifugal ventilator for the outer ~ Card 3/6  S/057/61/031/007/008/021' B111/B206 AUTHORS: Vulie, L. A. and Guaika, P. L. TITLE: -The "reversal" cf effects in-magnetohydrodynamics PERIODICAL:, Zhurnal tekhnicheskoy fiziki, v. 3f;.no. 7, 1961, 866-818 TEXT: The application of the "law of the reversal of effects" on steady quasi-unidim4nsional flows of a conductive gAs which is affected by hydro- and electrod namic factors, is discussed. This law was formulatedsby L. A. Vulis ~Ref. 1: DAN SSSR, 5A, 669, 1946; 5-6, 799, 1947) in the genr eral for the uaidimenaional steady motion-of a gas, and has the form 2 dw )dln z 2 ~LP dx i dx dx (1), where M is the Mach numberp z th' a P e raTe of flow u, the mach number or*a state paramet symbol for th er of the gas, x the direction ~o:r-u, dwi/dx the "effect", and dJ1/dx the sum of ef--' feats. By the "ef f so t adwidx the authors mean cross sea ti onal change.,( of the channel, changes of the outflow rate, or supply and removal of'onergy in the form of work, heat, and friction. Of special interest in magfieto- Card-1/4  5027 S/057/61/031/007/008/021 The 7reversal" of effeqts in B111/ .206 hydrodynamics is the effect of the electromagnetic fielu-I on the fl'ow of the co;iductive gas. This effect is studied in two aspects. 1) The passage, through the critical rate of' propagation of disturbances in any dense moving medium is investigated by means of (1). '2) Thd dependence of the electric volume force (and d.issipation) on the rate*bf flow is investigated. The passage throu&h sound vclccity and the application of the "Law of the reversal of effects" in magnetoliydrodynamica was'explained by G.-S. Golits~n and K. P. Stanyukovich (ZhEW, 1j, 6 (12), 1417, 1957) for finite, but large electrio conductivityp i.e., Ereat Rom* The same study was conducted by E. L. Real era,andil. R. Sears (ZAIIP, 96, no. 5/6,,509, 19561 J. Aeron. Sci.,. no. 4, 235, 1958) for small Re M values. From the magnoto4ydrodynam'ic fundamental equations, the authoi~s derive aquation Wt 1) d I- dx dr as dx Pa- (8) dil I JP (dQ IQ,p. 12 -W-) Te, 6-T.W 77- Pue Card 2/4  11/057/61/031/007/008 /01 The ','reversal,, of offects in ... 1111/M6 for the reversal of effectu, where F is the channel cross section, ip the gravitational potential, L,p and qT~ the frictional energy and -heat, L the mechanical energy, Q the heat from other heat sources. In the'next two-.. paragraphs, first theelectroinagnetic effebt.and then the passage through the hydrodynamic sound velocity are isolated and studied in detail. 'IFor -the general case cf' the passage through the total magnetohyd.fodynamic sound velocity, d1nu I di F -1 dQ L 1 -o- M d"r (18) 14:2 _ 2 2), holds for the "law of the reversal of effects", where M Al + ~A 9' - 1.+ A 2, and for ~'holds 1/(1 HII/ReM.H') (20), 0 4 < 1. The .primed quantities ip (20) sicnify the derivation according to Y - x/l - A 4, special case of this problem aas dealt with by L. A. Vulis and X. P. Stanyukovich (Ref. 8: V sb. "IssledoVaniye protsessov perenosa. Voprosy teorii otnositellnosti" (-,Investigation of transfer processess Problems of relativity theory"), vyp. 2. Trudy KazGU, Uchpedgiz, Alma-Ata, Card 3/4  '15(127 - j -,3/05 61/031/007/008/021 The "reversal" of offocts in B I I I YB2o6 1960) and K. P. Stanyukovich (Ref. 9: Neustanovivshiyesya dvizheniye sploshnoy sredy, GITTL, M., 1955)during the study-of the gas loss of stars. Thel studies conducted by the, authors showed that the Rlaw of the reversal of effects" on quasi-unidimensional steady flown of a conductive 'gas can be applied for electromagnetic effects. In the*general case, the reversal of the -jeffects leads t6 a generalization of the mach number M u/ -A, whez;e 9 is the total sound velocity inmagnetohydrodynamicsi for Re m 2 2 2 a a + V A holds and for Rem < 1, W V a, so that in generall a becomes where I is determined from (20). N~ Ye.. Zhukovsl:iy is men-.. tioned. There are 3 figures, 2 tables, and 13 referlehat4s: 10 Soviet-bl;e and 3 non-Soviet-bloc. ASSOCIATION: Kazakhakiy gosudarstvennyy universitet im. S. Lt. Kirova, Alma Ata (Kazakh State University im. S. M..Kirov,,Alma-At&) SUBMITTED: July 25, 1960 Card 4/4 G11)  S105 61/031/007/qa9/021 B104YB206 AUTHORS: Vulis,L. A. and Gusika, P. L. TITLE: Hydro-gae-analogy in magnetohydrodynamics 'PERIODICAL: Zhurn'i~ftekhnicheakoy fiziki, .31, no. 7, 1961, 819-823 TEXT: N. Ye. Zhuko%-skiy (Trudy TsAGI, no. 1, 1925) showed that the motion 1 !3 of-an incompressible fluid in a closed channel is in many respects analo- gaus to the isentropic motion of a compressible gas. It'can be'easily shown that this analogy is also kept up for the motion of conductive media during the effect of elec'tromF-gnetic forces. The equations of motion for a-plane isentropic flow of a compressible conductive gas, and those for a quasi-plane motion of a conductive liquid in closed,qhanriels arc. investi- gated. In the first part, the system ap 0 ot dx dy Card 1 MONA  S/00'57/61/031/007/009/021 Hydro-gae-analogy in -BI04/B206 du au 0" OP PW Pu dx du Ju du dp (2) -4 PFt-f-PUW-f-PVW -Y C,T-i-L' -c ,is written down for the gas flow and in the 6econd part, the system (hu) -i -+- LL (7) ah a' -4- XU du TOJ a" = -4- XII Lv -4- TIV Lv = -g71 'l' -4- [J111111, -f-f,, dt ax OY Card 2/6 T ry maw TWO M MMOR  S/057/61/031/007/009/021 Hydro-gas-analogy in ... B104/D206 h -4- h , (9) o 211 for a fluid flow w1f5 'free surface. In both'cases wa3,considered, and from a comparison of the two systems it may be.seen that-they are analogous for 2. The following analogues are compared: Mach number 14 -- V/a - FroU number Fr - V/c; density ratio 9/k)o - height ratio h/h I 0 2 2- pressure ratio p/p ratio of the squares of the beighis h /h ; tempera-* 1 0 ture ratio T/To- height rhtio h:h ; Alfv~n number 'A V /a - analogue of 0 the Alfv~n number W - V /c. In the last ratio, V I t.LII/Q clenotes the A velooity of the magnetoacousti(.- oscillations in a medium with infinite con- duotivity. These ratios forin 'tie basis 'or simulating flows of a oonduc-~. tive gas by means of the flows of a conductive liquid in a trough on appli- cation of olectric and magnetic fields. For both caaes the known relations ~_, -I , curl 11 and 6(E + N11j) hold for *the flow density vector and + -j 9Zft for the correlation between magnetic field strength all/at a, curl EVIII M Card 3/6  c*_ S/057/61/031,/007/009/021 Hydro-gae-analogy in ... and flow velocity. The completion of the initial equations by ~heee two differential equations determines the conditions for electromagnetic, simulating. The main criteriui,,i for both flovis Is the magnetic Reynolds number Rom a Vl/V . where ,)m - 1/ftcr is the -so-called magnetic viscosity, m and a the conductivity. As 13 shown, the analogy*i.nvestigated here per- mits the vaAation of Re in a vory %ido range. For lie (< 1, aerodynamic m m problems may -bo inventigated, for Rem problems of astrophysics. The authors investigato the fluid flow in an opeh channel with slowly cpanging width. Then, the e6ntinuity equation Lind the equation of motion are: dInh dinix 41 In h -0 (14) dis dh u -= -gkW; -4- (1-5) h Card 41b  DO S/057/61/031/007/009/621 Ilydro-gas-analogy In B1041B206 b b(x) being t1te channel width. By means of'the Froude number Fi u/fg-hp 1 06) dc dx V is obtained for the flow volocity and d In Fr! 2- 1 d I b .1 dx (17) for thu Froude number itself. These equations are analogous to those j in ordinavy gas dynamibs and in magneto6asdynanics. They are d1scusse'd ZO for Re 1 aod Ile I . There are 6 relverences: 5 Soviet-bloo and;1 M non-Soviet-bloc. ASSOCIATION: Kazakhskiy goaudarstvennyy univeraitet im, S. M. Kirova:Alma- :L':,, Ata (Kazakh State University Imeni S. 11. Kirov, Alma-Ata) Card 5/6  )1'124 5/057J61/031/0i2/011/013 B104/B112 AUTI 10HS: vulilj~jk. A., and Kashkarov, V. P. TITLE: The local redistribution of the total energy in the boundary ;layer of a compressible gas on the eurfaoe of,m burning body PERIODICAL: Zhurnal tekhnicheakoy fiziki, v. 31, no.'12, 1961, 1477-1484 TEXT: A at udy has been made of the local redistribution of the total energy (total-of kinetic energy plus physical and chemidal enthalpy) in the boundary layer of a compressible gas which passes arouni the surface of U Dlat of a plate in a laminar flow and reacts with it by an infinitely fast heterogeneous reaction. The nystem of equations ja aa di dT a U JT a~ aca oil UP atc Card 1b  11 211 S/05~ 61/031/012/011/013 The'lo.cal rpdistribution~of... B104 B112. YB! derived by-Ye. P. Vaulin (DAN SSSR, 6, 1957) is started from. For the boundary conditions wI OC C =0 UPH 1w 01 1~ - q -0 (2)p this system may be t.rans'f6rmed into.a. system of ordinary differential equations 2FI0~4-FF1=0, Us- (3) 2T".-4- Wr -2q (Fl', 2Cl-4-qOFC=O by the:substitution u -6 u F.' T T(.p)l C C(I)t where ul-Jq', u and v are the admponent Of,the velooity vectorl Xv v + u dy are the Dorodniteyn variablesi T and C Ca,rd W3 0  4 S/057 6Y/2031/012/011/013 The local redistribution of... B104/BB(1112 are temperature and concentration, 9 the gas density, q the heat of reaction, A the thermal conductivity of the gas, a and aD are Prandtl's heat and diffuoion numbers, and C p ie the specific heat of the gas. An solutions of this diffusion and heat-conduction problem, the profiles of velocity, temperature, and concentration of the reacting gas are plotted for different Prandtl numbers. B. A. Fomenko of the Laboratory for Problems of Thermal Physics of Kazakh State University is thanked for numerical calculations and plots. Ya. B. Zelldovich (Teoriya goreniya i detonatsiya gazov. Izd. AN SSSR, M., 1944) is mentioned. There are 9 figures and 10 references: 8 Soviet and 2 non-Soviet. ASSOCIATION: Kazakhskiy gosudarstvennyy universitet im. S. M. Kirova (Kazakh State University imeni S. M. Kirov) SUBMITTED: October 17o 1960 Card 3/3  511 VIt /62/012/04/002/014 S/089 B102/B104 AUTHORS: Vulis, L. A., Kostritsa, A. A., Kubyshkina, V. D. T IT LE: Calculation and simulation of optimal reactors with homogenized core (af;e apprc.ximation) PERIODICAL; Atomnaya energiya, v. 12, no- 4, 1962j 283-291 TMT: The authors discuss some methods for calculating homogenized-core reactors with minimum critical mass and constant density of released enerEy due to absorber redistribution in the core. By usinLr the integrators described in earlier papers (Vulis, Kost:ritsa, Tr. KazGU# Alma-Ata, 1959; Izv. AN KazSSR, ser. energet. no. 14, 111, 1959; Ve3tnik All KazSSq,.no. 9, 1959), some characteristic functions such as the fuel density distribution and the neutron density distribution are determined. The equations for a reactor with nonuniformly distributed fuel are difficult to solve in ase or multiEroup approximation but easy by simulation methods. A one-dimen3ional static integrator designed for solving heat- conduc tion- type aciiiationa withcon- otant fnotors is described and discussed. In principle, reactor simulation needs two integ;:,ators: the first one for neutron moderation whose results Card 1  S1083162101210041CO21014 Calculation and simulation ... B102/B104 are fed into the second one which simulates thermal-neutron diffusion. For determining the.minimum critical fuel mass, the function ipW + da. 01) V is used; in this case, the moderator density nT-T n,'.O-v(x) (T -T)/T, k Iqy/(y+l); To is the life-time of thermal neutrons in the 0 reflector, q is the mean number of scondary neutrons per thermal neutron absorbed by the fuel; N-r is the moderation length, -rt the thermal neutron age; all the parameters of the dimension of a length are taken as dimensionless. Calculations of the critical fuel mass fydx in ace and two- Group approximations are compared (Table 1). For thermal-neutron density smoothing by an additional absorber, T (12) las 143 Card 2/4  B/089/62/012/004/002/014 Calculation and simulation ... B102/B104 is used, where the sought function y(r*) - 2:1(r)& a3 is proportional to the density of the additional absorber whose absorption cross section is a r r Ir , the macroscopic absorption cross section ratio of fuel a3 2 and moderator: In two-group approximation f(y) the - q ly, 'f analytic form of f(y) and the criticality conditions are calculated in age and two-group approximations for a plane, a cylindrical, and a spherical reactor. From a comparison of the results it may be aeon that the age approximation is well usable, and that neutron density smoothing problems lead to heat-conduction-type equations solvable by static integrators.. Them are 5 figures, 2 -tables, and 15 references: 7 Soviet and () non-Soviet. The four most recent references to English-language publications read as follows: 0. Goertzel. J. Nucl.-EnerCy, Zp No- 3P 193, 1956; J. Wilkins. Nuol. Sci. Engngo 6, No- 3p 229, 1959; J- Ravets, J. LamArnh. Nucl. Sci. Engngp.Z, No. 6, 4796p 1960; M. Duret,,W. Henderson. Nucleonics, 16, No. lit 16e, 1958- Card,3/4  h2745 S112 62/000/011/011/017 D234X308 16.. C AUTHOR: Vulis, 1'. A. TITLE; An interpolation formula for transition region of flow PERIODICAL: Referativnyy zhurnal, Heldianika, no. 11, 1962, 90, ab- stract 11B639 (Tr.. In-ta energ. AN KazSSR, 1961, v. 3, 109-121) TEXT: The author introduces a measure of disorder' w()c.) of the state of transition between laminar and turbulent flow conditions L2(X) L(X) L R - Rcr. 1 W (0)'= 1 (1) ~4here L(4) is an integral (resistance, heat loss) or local (velo- city profile, temperature profile, intensity of turbulent Pulsa- tion) characteristic of flow, ~6 is the coordinate,of 8tate (d iffe- Card 1/3  3/124/62/00/011/011/017 An interpolation formuia ... D234/D308 ronce butween Reynoldo' zitu%iber R and its lower critical value 6r .1 at which the lairiinar flow loses its stability, Li R corresponds to laminar and L2 to turbulent conditions. By analogy with relaxa- tion processes it is asL;umed that w e_ OL2 (2) V7" where ct2 is an empirical constant. Prom (1) and (2) ail Interpola- tion formula 2 L(Je) = L, Pt',) +LLdr) - L,'(Jf~ (1 e,_'~ (3) follows for the conditions of transition. Plow characteristics cal- culated from this formula are c9mpared with experimental data (and Card 2/3  3/124/62/000/011/01,1/017' An interpolution formula 1)234/D308 the constantsX 2 are determined). It is proposed to interpret W as the probability of the viscous conditions predominating over the pulsation conditions (relative gap between pulsations). 8 refern- ces. /-Abstracter's note; Complete translat~ion.-7  ----!qqSO L.A. KASHK=Vo V.P. Local redistribution of the total energy in Use boundary layer of a compressible ps near the 3urface of a burning body. Zhur. tekh. fiz. 31 no.12:1477-1484 D '61. (MIRA 15-1) 1. Kazakhskiy gosudarstvennyy universitet imeni. S.H.Kirova. (Boundary layer) (Gas flow)  VULIS p L.A. No-of the interpolation formulas for the transiticn flow region. Trudy Inst.energ.!ff Kazakh,SSR 3:109-321 161, (MIRA 34-12) uid dynamics) rReat-Tranamission)  VULIS, L.A.- Principal results of the studies of the aerodynamics of the combu--tion chambers and furnaces. Trudy Inst. enerF. AN Kazakh. SSR 2:225-233 ,6o. (MIRA 15:1) (Fluid dynamics) (Furnaces)  40956 S/262/62/000/011/010/030 ALMIOR Vuhs, L. A. 1007/1252 TITLE: On the turbulent wake behind a body PERIODICAL- Referativnyy zhurnal, otdcl'nyy v)pusk. 42. Silovyyc ustanovkj, no. If. 1962, 34-,5 abstract 42.11.159. (Tr. Kazakhsk. un-ta), no, 2, 1960, 33-40 TEXT: An approximate picture of the flow in a turbulent wake behind a body is obtained by supcrpcmit ion of a fo(ward hurnogencous flow over that generated by a turbulent stream. The solution is based on the fact that at Reynolds numbers of about 10-1 the average motion at a certain distance from, or close to, a body becorrici s'abilizcd and regular. An in&iteiimal sircarn inducing the final pulse is assumcd to exist at a ceitain point. The r atcA throughout the field of flow arc determined, on the basis of these assumpi ions, within the it amcwork of the. boundary-layer theory. In order to determine the flow pattern in a wake behind a bluff body it,% resistance is assumed to be concentrated at a single point, its center, constituting the point -.Source ofthe pulse wake, At first approximation, the velocity profile of a complex flow cin tv comtrijacd by geo aw.ttical ~ummadon of those of the %tteani and the tiniform, flow. Calculation% havo ihown that at Re, - 104-405, the zone or reversed Aow behind the bodies is: 1.3 diametets for a cylinder. 2. widths kv a plate; 1.2, diametets for a sphere and 1.9 diameters for a disk. There are 9 references [Abstfacter'e. note.: Complete tfanslation.] Card ~1/1  40955 S/262,162/000/01 IjO091030 100711252 AUTHORS Vulis. L. A. and Kashkarov, V, P. TITLED Boundary layer on a burning cone PERIODICAL - Referativnyy zhurnal, otdcl'nyy vypusk. 42. Silovyye ustanovki, no. 11, 1962, 34, abstract 42,11.158. (Tr. Kazakhsk. un-ta), no. 2, 1960, 19-24 TEXT: Investigations were carr ied out on the larninar flow of a compressible gas stream emctging from a nozzle mounted at the apex of a right cone and forming a jet spreading along the cone surface. The reactions taking place are assumed to be of endothermic character. For calculation of the velocity profile, tc mperature and concentration of the reacting gas, the motion in the boundary layer is assumed to be a flow in a semi - confined source-jet, the cone surface to bo non-conducting, and its rcactivity-to vary with the distance from the apex. The system of differential equations thus obtained is integrated by means of Daronitsyn variables, Solution of this problem permitted determination of the relationship between the hydrodynamics of a compressible gas stream and the combustion theory; results give a qualitative picture of the interaction of a burning gas and the surface of a body, rhcre are 7 references. [Abstracter's note: Complete translation.] Card III  9/263/62/000/006/013/015 1008/1208 A1,711ORS; Vulis, L.A. and Klinger, V.Go TITLE: k method of light integration PERIODICAL: Roferativnyy zhurnal, otdol1nyy vypusk, U, Izmoritell- naya toklinika, no.6, 1962,, 51, abstrnot 2112.0*324, (117r. Kazaldxk.un-tr., 1960, T~o.2, 103-108) TEXT : The po3sibillt-.N, oi. nalwilt.-inr, the irradistion of tnrget3, of the radiation of sourcos if self-absorption is taken into ac- e oun t, nnd of the radiation b.-,_rrier, etc., by means of an expari- mental ntudy of radiatior rays on &n optie,al raodol (tha latter serves as n light integrator), is discussed. The simplicity and the sufficient accuracy of the method are illustrated by moans-of an example, in which the rndiation dose received by a disk-like .target from a source of particles of the same shape is determined. [Abstracter's note: Complete translation.] Card 1/1  B112 62/000/010/010/015 D234YD308 AUTHORS: YajLg_,~.,_Apd Kashkarov, V. P. ,.TITLE: Heat regime of the boundary layer in.heterogeneous burning 'PERIODICALs Refert4tivny zhurnal, Mekhanika, no. 109 1962, 91, a~- atract 1OB43 (In collectioni 3-Ye Vaea. soVeahchaniye po teorii goreniya, V. 2,*M., 1960t 98-106) TEXT: The authors consider a laminar%boundary layer on a plate with chemical reaction. The following ass-umptions are made: The mixture is binary, the viscosity coeffi 'cient is'proportional to the temperature and is independent~of,the concentration of the mixture components, the specific.hetLts of the components are equal -and constant, the thermal and'diffubional Prandtl numbers are con- stant, the velocity of reaction at the surface,.js V = k0exp (-E/RT).Q, where C is the concentration ok the r-eacting gas, the coefficient k0 is a function of the length,of the plate, and the Card 1/2  IMB 8/124/62/000/010/010/015 Heat regime of the D234/ 08 form of this, dependence io.chooen in ouch a w~~ that the problem becomes self,-modelling. kialytical solution of.'tho oquationa of the bounda layer is obta ry and the conditig'no Of ignition and extinction are derived fr9m it. The authors also obtain the de- pendence of the regime of burning ('hysteresis# or Pnoncritic'alI----_._A on dimensionless parameters which detekmine the proceS86 Abstracter's note: complete translation. Card 2/2  --- VULIS, L.A. Applying the cemicondactor resistances mothod for the modeling of thermal conditions in combustion, Izv. AN Ka?,akh.,SSR. Ser. energ. no.l.-18-,22- '-60, (MM 15: 5) (Comhwtion-Electromechanical analogieg)  -VULIS, L.A.; KOSTRITSA, A.A.; KUBYSIIKINA, V.D, Deoigning and modeling of optim= homogenized-core reactorju (age approximatiori). Atom. energ. 12 no-4:283-291 Ap 162. (MM 15:3) .(Nuclear reactors)  VULIS, L. A. Research into Applied Mathematics and Y--chanics Conducted in the 'Thermo-Physic&I Laboratory of KAZAEH State University iemni S. M. XEROV. p. l9q6 TRAMLM(,VIB OF THE ?TiD RERMaCIUT CUD-EFOICE ON jIWM-V.TjCS AND MMMUrICS (TRM VTOROY MESIUWZ=1131v~N MIMMMII TIP, I I-MITAYEM- ) , VA pages, publinhed by the Publichinc-, House oll the f%S KAM"M ".')R, AW-AT41'. USSR, 1962  VULISI L.A., doktor tekhn.nauk, prof.; XOSTRITISA, A.A., dotsent Elementary theory of the Ranque effect. Teploenorgetika 9 no.10:72-77 0 162, (KRA 1539) 1. Kazakhakiy gosudarstvennyy universitet. .. (Fluid dynamics)  VU ;, L A.; SENDERIMINA, I. L. Calculation of turbulent friction and heat emission In jets using an equivalent problem of the theory of beat transfers Izv. AN Kazakh. SSI. Ser. energ. no.2275-82 162. (MIRA 161l) (Fluid dyniudes) (Heat-Transmission)  VULIS, L.A.,;,,YERMTRI., B.M.; INYUSHIII, M.V.; LUKIYANOV,, A.T. ..... Calculation of thermal conditions of a concrete dam for the selection of efficient methods of construction work. Inzh.- fiz.zhur. 6 no.10:3-11 0 !63. (HMA 16:11) 1, Hazakhskiy gosuda-.L;tvennyy univervitet 1mevi Kirova, Alma-Ata.  L- 26731-61 9PA(b)/EPF(4:)/OIT(I)/EPF(n-)-2/EWP(q)/tI~T(ni)/tO AFnCIASI)l IJP(G) /SSD Fd-4/Fr-4,/Fa-4 W/TD S/lWt/63/000/OC4/ 018/ 064 Vulis, L. A. and Genayava, L. L AUTHOR: --JTITLE: 0W9Mnt"he*'c*afaMtion of integral regularities in the traasitional region of f low 6- 1A kRIMICAL: Referatimayy zhurrials Mekhanika, noo 4i 19 3p 81, abstract 4B548 (Izv. AN KazSSR. Ser. anerg., no, 1(21) -1962P 66-73.) .-.,.-..TEXT: For -calculating the coeffici-3nts of -frictio&and beat exch aeAand other integral chaxacteristics), in the transitional flow regions the author =-oposes to compute, using certain weighTed factors, these coefficients at laminfr and turbulent flow conditions. The dependence of the weighted factors on the Reynolds nizaber is given. The results of calculation based on the method offered are co:kpared with experimental results. The tests are tied in vith specific cases: air flow around a plate, flort of moltern metal in a tubes flow in rough channels. There is satis- facto--y correlation between the test and the calculation. R. U. Kopyatkevich. (Abstracter' a note: -Complete tranalation. Card 1/1  7-7-1,7- A U"l '7~. V L,.~ ~f;a!i TITLX: Nlagnexohydrodvnlo~c C(uttto f SOURCE: Zhurna', teithnIches.Koy fizi"ci. '1964, 1171-2 77 TOPIC TAGS magnetonyurWyn,lm.,-~ ftu~u mid r 1/2  -L 2"3819-65 ACCESSION NR: AP5000942 e-quatio= ig reviff-ce! 'Iyr a eqImtimis by a F-Ingle t ransformation. Th.t :--,so taxe., (are 0: tLe bo,4naary conoi t ,,ins , for Lae z)as -4 p. - rameter - the distance between t,e p~tra' ',E!' plates - is brou7ht n f -om the r,art ,in the fr-rm -)f a ra t r, reply c t n e, r -n t i a 1. ();-~e ra tor:~ Ge ie ro s n i u i or f of t'ie e ,e s t ead,,, a taltps ore car, ma ~e u! v o~ Ef z timp, e Le 60 , U t 1 Or, case ot constant conductIv, At a I ys 15 of the different facto" wl!~n the a i d of t y the deduced equa*. ions Idads to rvSU1*.6 consistent with those of B"'i as regard& va- ria t I nf f1ho fri n-c 11on and he4 t traris fer i n a boundary layer. D'Ig art -has - 39 ASSOCIATION- none S 1,Mbi ITTKD i 5,1u 16,1 EXCL: CKD SUB CODE: NR REF SOV: 005 01MER: 003 2/1  L 4214OL4'r, IEW(" M) Ir-R PY-4/ Ps-4 IN-4 W141 71S f )N' ~~R- A 64 000 (YO 1 A T ~,,i\,evvkh zada,-r Aria.,)g mett-vis .-,T-.:TOPIC TAGS; lea t ff, analog computer AIIS7RACT- T~ e paz Pr i heat transfer problem in the presence of various Card  ACCESSION MR: AT6002502 af, !IF - - r lax III ut (0, u (t). U"k.. t) - I,, = U., (4 it (X. 0) 4) 'in 'rr-,zrat )?- -i-mont ,4htjwn In F,.g I of the Kn~lowjre -hwh  VJIIIN.' L. A. (Leningrad); YwIPELIH., V. Yeo; PALAT.W., I. B.; SAKIPOV, Z.; USTDIENKOp B. P. (Alma-Ata) "Laws of propagation.of turbulent compressible gas jets" report presented at the 2nd All-Union Congress on Theoretical and Applied Mechanics, Moscow, 29 Jan - 5 Feb 1964s  VULISI L&_A,;" MHAUGASHTEIj K. Ye. (Leningrad) ".The elementary thoor7 of hysteresis effect in magnetogaadymmics" report presented at the 2nd All-Union Congress on Theoretical and Applied Mechanicsj Moscowp 29 Jan - 5 Feb 1964.  VULIS, L.A.; DZHAUGASHTIN, K.Ye. MagnetoggaBdynsmics of.Cauette flow. Zhur.te)rh.fiz. 34 no,l2t2l7l- 21'n D 164- (MIRA 18:2)  VULJ.S, I,wl, Al-,ra- Iltinilly Potrovich; PAIRON, Theory Of JeLS Of' ViSCOUS fl.U.IdOl Teorlia strui viazkoi zlildkosti.. Moskva, Naukap 11965. 431 P~ (MIRA 184.9)  L i67o2-66 WN 'ACC HR., AP6003207 SOURCE CODE: UR/0302/65/OW/0014/0067/0014 ~AVMOR: Vulis.'L. A.; fthaugas1itin, K. Te. ORG: n.'one TITLE: A wnibounded conducting fluid stream iSOURCE: Magnituayet gidx-odinatoilra, no. 4, 1965, 67-74 TOPIC TAGS*-Raynolds number,,heat diffusion, HUD flow, cond%mtive fluid, nuid flow, magnetic field, notion equation 'ABSTRACT: The atationary problem of incompressible viscose con4hicting liquid mov- as a stream alongLa flat scurface Is considered. The problem considers a flow in a magnetic field normal to-the surface which constricts the flow to a semi- bounded space *-__TM magnetic field value restricts the Reynolds number values to .much less than unity. The usual equations of motion are-solved by use of slmilari-_ ~ty transformations and Iterative approximations whom the zero order solution is 1hat for the nonconducting fluid. It is shown that the velocity profile is given- Iuite -accurately--by -a- single -1teration.- -The- s6lu lons am plotted for several 4values of the parameter which deteimines the strength of the naVietic interaction. UDC: 538.4 jCard 1/2   -L 46844--44-- -EWT(1)/EWP[m))Tt1A(d ACC k4Rs JVI Monograph LkCM-N, R, 'Vuli, Vulis, Ley Abramovich; Kashkarov. Vasiliy Petrovich 7 Meory ot a--je t - vi 9 cou.3 -T1 ul d --(Teorlya - atXW -Vyazkoy--- zhi 0k,74t il Mos cow ;?d-vo 7f "Nauka.)" 1965, h'29 p. illus., biblio. Errata slip inserted. 46oo copies printed. TOPIC TAGS: fluid mechanics, gav jet, jet stream, turbulent jet, diffusion flame, Wall jet wake flow heat transfer, boundary layer, magnetokiydrodynamics, jet flow, Navier.Stokes eqwitlon -PURPOSE- AND COVERAGE: This book will be of partialar Interest to persons concerned 7 with- the problems~of fluidlet-- -strewns.--- The:lbook- is - devoted t o the- maul' to -of-- f, investigations -'of-abroad-an.djr:~~pread rategory of. incoUressible fluid motions in the form, of laminar and turbiU-nt jets. The development of computational methods applicable- to an important-type. of jet- streams -and based on a consistent and systematic study. of jet flows w1th a theoretical approach Is the aim of this monograph. There are four par~,,.s to the book including a fore6ord and an intro- ductinui -.--The- first part -deals with the- soluhons of.. jet-problems based an the exact Navier-Stokes equatims for. incompressible fluids and, in particular, -with the.Landau investigation of the propagation of a submerged axially symmetric viscous fluid Jet issuing from a thin tube. The second part contains a detailed analysis of laminar jet stre=3 of an incompressible fluid by methods of boundary layer theory. In addition to free jets flowing into a stationary medium or into ounded jets (wall jets) are considered. Turbulent Jetz homogeneous-,wake _flows, semiL of liquids and ga3eB are the subjects of the -third part, in vhich self-similar Card Jh UDC: 532-,-522  L 16844--66' ACC NRs Am6o=41 solutions-for free and wall 'let sources are investigated. It-iaso contains deta.Uet~ experimental data obtained under the guidance of one of the authors.in thermo- physical- laboratories in Alnut Ata for comparison with the theoivtical results. The fourth part deals with certain theoretical and experimental problems -of jet streams which may be regarded F-s complementary to the main topics treated in this book. Among them are complex turbulent Jetstream, patterns. of diffusion flames, and jets in magnetohydroVna:3i(_s. The authors thank X. E. Dzhitugashti and L. P. 1- Yarin for their help in selecting data and in writing SPters 17 and 18, and also N. Abramovich and- G-.- Yu. Steanov for their comments. TABLE OF CONTFATS [abridged].' Foreword 6 Introduction 11 0 1 Jet sources 11 Os2 Jet flows 15 Part I Sol*x;ions of Navier-mStokes Equations Ch. 1. Jet issuing Crom'a thin tube 21 Card. 2/4  ACC (A _"00104 Ch. 2. he Certain pr3perties oft. solut-tort 32 Ch. 3. Results of the solution -44 Part Il Laminar Fluid Jets 'Ch. 4. Free Jets of incompressible fluid 67 Ch. 5. Jet in a wake flow 100 ch. 6. semibotmded incompressible fluid Jets, - 115 Ch'# .7.. Laminar incompressible rluld Jets 140 Ch. 8. Laminar compressible gaxs Jets 166 Part III Turbulent Liquid and Gas Jets Ch. 9. Propagation of turb.ulent Jets 201 Ch.- '10. Turbulentmomentum arid-heat transfer in incompressible fluid Jets 216 Ch. 11. Self-similar,'turbulf!nt incompressible fluid Jets 228 Card 3/4   L a2~02-66 WP(iL) LWA(d)/EWA(l) CC NR1 A TWo6qofil 3OURCE CODE: UR/0000/65/000/000/0120/0128 AUTHOR: Vulisj I$. A. ORG: .941 TITLE: Nonuniform energy distribution in the flow of 9-gas SOURCE: Teplo-1 massoperenos. t. II: Teplo- i massoperanos pri vzolmodoystvii tel a potokeini zhidkostey i gazov (Host end mass transfer. ,v. 2: Heat and mass transfor in the interaction of bodies with liquid and gas flows). Minsks flaulca. i tekbnika,, 1965, 120-128 TOPICTAGS: L'ras flows gas dynamics, shook wave ABSTRACT: A-nonitniform.dis';ribution.of-energy is-cbaracteristic of the rapid movement of' a gas. The article surveys several examples of local. redistribution of' energy and.considers the physical nature of such effects* The first case considered is the flow ofu gas from a shock tube.- After a matbematictil development,, the article gives a relation- ship for the values of tbo atagnetion temperature as a linear funetion~ of the sqiiare of the Mach number. The result is applied to calculation 0 flame fronts. , In gonerals the article concludes that the effect of local redistribution is small in the dynamic problem and can be Ocard 1/9   kCC-NR, AP6008829 SOURCE CODE: UR/0294/66/004/001/0059/006,', Zz AUTHOR: Vults., L. A.- ashtin, K. Ye. Dzhaug, ORG.- Leninffrad 111&4er Naval Engineering College (Ieningradskoye vyssheye voyenno- morskoye Inzhenernaye uchilishche) TITLE: phenomena during the flow of a conducting gas In an MIIID-energy converter channel SOURCE: Teploflzika vysokikh 't;emperatur, v. 4, no. 1, 1966, 59-65 TOPIC TAGS: magnettohydrodynran lea, MIM flow, conducting gas, gas flow, magnetic hysteresis ABSTRACT: One of the characteristics of MHD flows of a low-temperature plasma iswell- defined temperature dependence of condu 'ctivity. 71i; Tonlinearity due to this may load to an ,unbiguity of steady states and to unique hysteresis effects. For MIID flows such effects were detected elsewhere In the course of numerical calculations of hypersonic motions. An elementary theory of the problem for Couette now has been published. Inasmuch as the nature of Me phenomena investigated, generally spealdng, Is not related to a specific type of flow, It is natural to assume that an analogous manitestation of nonlinearity Is found in cases other than thofle studied in relation to hypersonic motions. From this viewpoint, the present authors Investigate the practically important case of theflow of a conducting gas Card 1/2 UDC 638.4  L 31526-66 ACC NR, AP600BBZU In an Mh-D-energy converter channel. The sturly is made in the framework of a quastuni- dimensional steady-state flow at low values of the magnetic Reynolds number and Hall parameter. The stucty Is restricted to a general, primarily qualitative statement of the problem and some examples which allow the presentation of the final results in a simple form. Detailed data for specific cases may be obtained by means of nwmerical caltvilations, unrelated to extensive simplification of the problem. Orig. art. has: 7 figures and 20 formulas. SUB CODE: 20 SUBM DATE: 12Oct64 ORIG REF: 004 OTH REP: 002 2 9,