SCIENTIFIC ABSTRACT POPOV, V.M. - POPOV, V.N.

VASIL'YEV, Yu.S.; KALININ, A.G.; POPOV,.V.M. Effect of deflecting force on the extent of well deflection. Trudy VNIIBT no.10:88-92 163. (MIRA 17:4)  VASILIYFV, Yu.S.; KALININ, Relation br-tween the loads on the hook when hoi.Ain[Z an,' ---,wering and the loads on the bottom in a wel' that is slightly crooked. Trudy VNIIBT no.ll,:102-105 65. (MIRA 18: 5)  11 1 1 - I V Af~,' I L I Y ~ "I !- il . ; r. ;% ~, i, -, , , A , (~' . , ` (Ii ~ ("V V H - LOBANTCV, YII.K. 9 , i , i , . .1 Effect of th~~ c-f' a 31ant nale on the lra1-; rr: T-he hook wtien li'ting i 4r)(A. 'rlidy Vtlllfi'r no.14:98,101 16, f; . ( m la ", 18 : -- ) t  GLADILIfi, kriatoliy INJ.Rolayevi.-h, kand. tekhn. nau-l-,. dots.,, SYhkTYEGiN, Aleksandr kard. tekhn- st. prepod, MAYMENKO, retsenzent; ZHIDELEV, M. retserment, OVSYAIIII-TKOVA, Z.G., red. [Course of industrial training in tecimical schools for mechanical engineering for operators of grinders,. planers, and drilling machines] Kurs proiz-vodstvennogo obucheniia. v mashinostroltel*r~vkh tekhnil-makh dlia rabochikh professii.: shlifuvshchik. strogallsb-~bik 4- sverl---vshchik. Moskv&., V-ysshaia shkola~ Ft.3. 1965. 315 P. (MIRA 18!8)  POPGVJ, V.H. DECEASM ig6i/i c1958  PETUKHOVY B.S., POPOV, V.N. Theoretical calculation of the heat transfer and frictionh! resistance in the laminar flow in tubes of an incompressible fluid with variable physical properties. Teplofiz. vys. temp. 1 no.2:228-237 S-0163. 04IRA 17;5j' 1. Moskovskiy energeticheskiy institut.  L 07~Q3-67 S ACC NR: A-P-6021635 /V,) SOURCE CODE: U-,Voo6q/60/ozo/w-1/c--~ AUT-HOR -Brazhnikov, Ye. M. ~zantiyev, B. G Po.-,,M V. N. ; Rusciyan, Ye. K.; Shaic- meyev, A. S. ORG: none TITLE: Installation for the investigation of processes of chemonuclear synthesis un- der laboratory conditions SOURCE: Atomnaya energ:Lya, Y. 20, no. 3, ic,66, 279-281 TOPIC TAGS: chemical -Cnthesis, chemical energy conversion, fission product, radia- tion chemistry/ lQiYAU-4 'chemical synthesis unit,,,IRT nuclear reactor AESTRACT: 'The article deals with a possible direct use of atomic enerr.- by orm,ing the energy of the fission fraZments directly into chemical enerCeor, byT;as5iJ.-,z intermediate energy forms such a smechanical, thermal, or electrical. In such a I)ro- cess, a mixture of -simple gases passes through a chemonuclear unit, which is essen- .,h fucl elevaent. The radiation producer, radiation- chemical reac- tially a flow-tbroug I tions that produce the end products. An example is the production of ',402 froli-, air under the influence of radiation. The authors describe special de-,ricer for the pro- duc'4on of chemonuclear synthesis constructed at the institute of Chemical Fhysics AN SSSR, in particular a circulating chemonuclear intended IL '.1 to investigate synthesis in the ganeous phase under laboratory conditions. The paratus constituten a clooed loop in which the gas mixture is circulated by a c=-. uDc: 621.039. 541.15  L C) 7,:3 93 - 7 ACC NR: AP6021635 pressor. The products of the chemonuclear synthesis are produced continuously an the gas mixture flows through a thermostatically rAintained irradiator located in the vertical experimental channel of a research reactor. The irrad-iator tubes are filled A. I , B 0, or Lill. with I nely dispersed nuclear fuel, such as glass wool containing U235 I Another version of the irradiator, In which the fuel is deposited on disco, is also used. The reactor products are extracted from the gas mixture in a block of traps. A f"ilter block decontaminates the gas mixture. The apparatus can also be used with other sources of ionizing radiation (electron accelerator, cyclotron, or cobal instal-! lation). The apparatus described was tested with the electronic accelerator of the Institute of Chemioal Mysics AN SSSR, in the IRT-1000 reactor of the Institute of I Atomic Energy im. 1, V. Kurchatovo and in the IRT-2000 reactor of the Institute of 1 Nuclear Power All BSSff-.T1ii--exj~eriments have shown that the KhYaU-4 apparatus permit vs investigatlo-n-6-f-~i-e-monuclear synthesis processes in varicus gas systems. Orig. art. has-. 3 figures. SUB CODE: 38/ SM DAM 14Aug65/ ORIG RFM 001/ OTH FW: 001 Cmd J2  ACC NRv AT6031757 AUTWE: Popov 9 V. K. ORG: None SOURCE CODE: T=: Static characteristics of the slot device UR/3O92/66/0C0/OOVG07-//U08, SOUME: Moscow. Nauchno-inaledovatellskiy institut ele4ctrofiziebeskoy apparatury. Elektrofizicheakaya apparatura, no. 4, 1966, 77-83 TOPIC TAGS: particle accelerator, particle accelerator component, charged particle, particle beam, particle cross section, gaussian distribution, ion beam, ion beam focusing ABSTRACT: The static characteristics of the slot device, consisting of two con- ducting plates which of themselves form the slot, and which is used as the sensor in-aystems for stabilizing the energy in a charged particle beam in direct current aec'elerators, are calculated on the basis of the following assumptions: (1) the changed particle beam leaving the analyzer is of elliptical cross section; (2) the erdes section of the beam is oriented relative to the slot (one of the axes of the 0134ptical cross section is parallel to the slot); (3) the width of the plates making up the slot device is much larger than the beam's cross sectional dimension (always so in practice); (4) there is no emission of charged particles from tfie  Adif -NR:'kT663-1757 plates; (5) distribution of current density in the bean along the axes of the elliptical cross section is Gaussian. The results of the calculations sugEest th-e need for compromise between the desirable slot transmission coefficient and per- missible beam losses on the plates, and note is made of the fact that improving the focusing of the ion beam can improve the slot transmission coefficient while keeping losses at the awe level as before. Orig. art. has., 15 formulas and 3 figures. SUB CODE: 20/5M DAM None/ORIG REF; 004/OTH REF: 001 Card 212  POPOV.V.N., kandidat tekhnicheekikh nauk Hinge joints for gravity circulation pipelines and device f7r washing them out. Tekh.zhel.dor. 6 no-10:30 0147. (MLRA 8:12) (Pipelines)  MAKAVETSKAS, R.A.; '.'OPOV,_ V.,N.; TSEDERBERG, N.V. Experimental study of the viscosity of helium and ritrogen. Teplofiz. vys. temp. 1 no.2:191-197 S-0163. OMIRA 17:5) 1. M-oskovskiy energeticheskiy institut.  POPOV, V. N. Popov, V. N. "The sQnitary-hygienic characteristics of th- Vyatk2 RiVer in the portion near thn city," Trudy Kirov- skogo in-ta epidemiologii i milcrobiologii, Collection 2, 1948, P. 56-63. SO:~ U- 3736, 21 I-lay 53, (Letopis Zhurnla Inykh Statey, No. 17, 1949).  'PANOIJI, V-:- A P01.10V V . N S7r Programming Ja-F 164.  X,tKffANCk).%0V,"K1Y, L.A., Yit.A.; VOROPYEV, S,V.; GAYDIFO, F.A.; DOLGOV, Ye.? HIGLINY A.A.; G.F.; Hr,2 ~ - n. L. A -r,;V A. ty 7 R.I.: 'MORG"ZOV, N.P.; 0 Z T!::~ 0 ZETI SZ? ,A.S.; FA-~ILOV, FOPO'i-, V.N.; TA~~IAKCD!TqyW- I.A.i TAUBE, D.':.i KWD7 L.T.; SHAPIRO, TS.3.; SHN~'1TSBURG,-i.A.; SHEVTSOV, V.D.; DENISPENKOVA, L.M., red. [Assembler's handbook on performing mechanical assembly and special work on grain elevators and grain processing enter- prises] Spravochnik montazhnika; po proizvodstvu mekhano- montazhnykh i spetsiallnykh rabot na elevatorakh i predpri- iatiiakh po pererabotke zerna. 1.'oskva, TSentr. in-t nauchno-tekhn. infor-,atsij. 1. tekhniko-ekon. issl.., 1963. 519 p. (MIRA 17:?)  . I I . . 7 : ' ;_,- ~,--I - YESTIFBYZV. A.M., professor; POPOV, V.N.. kandiclat tekhnicheskikh nauk. - , Graphic analysis methods for pipe freezing. Is-v.VXIIG 41:123-128 '49. (Pipelines--Cold weather conditions) (NLU 10:2)  POPOV, V.N., kanclidat takhnicheakikh nivii1c; GONCHAROV. F.S.. inzhaner: SOWVOV. a-oar., inzhener. Instrument for the automatic measurement of water and other fluid flow by tho volumetric method. Rats. i izobr.predl.v stroi. no.94:24-28 154. (MLRA 8:8) 1. Otdal ftobretatel'stva i ratsionalizatsii Hininterstva stroitelletva. (Flow meters)  Fll-:-j7, "'. 1. pj?~---, 1,. '-.- "Tnv=~zti a'ior o~ of 7-low ;- the '7p: r ':a+-- of -,, I i - - - .- -- --I- - I -... - -.- ~ Pe .1 --- - an I.-aproved :,iin, 0.- Ir uc-nti:)n *.,7--" 1 -- I - -4-- .~ev S~r-7 I InSt, Kiev, 1955 (Disserttat-1--ons For 3el"'re' - ~andid,-tlr- of Tecrnical SO: Knlzhnaya_Letot.Js' No. 26, Ju,ie 1955, ',:ancow  POPOV, V.N., kandidat tekhnicheskikh nauk. Barth-soil methods of biological purification of hzamehold- fecal sevage for small capacity installations. Sbor.trud.VMIGS no.6:5-58 155. (KWA 9:7) (Savage-Furification)  124-58-9-9869 Translation from: Referati-,nyy zhurnal, Mekhanika, 1958, Nr 9, p 57 (USSR) AUTHOR: Popov, V. N. TITLE- The Velocity and Depth of the Stream Flow in the Headwater of Overfall Spillways (Skorost' i glubina protekaniya potoka v verkhnem blyefe perepadov) PERIODICAL: Tr. Kiyevsk. avtomob. -dor. in-ta, 1957, Nr 3, pp 134-144 ,ABSTRACT: Presentation of a calculation method for a nonsubmerged overfall spillway with a relative great length of the drop; the method is approximately applicable for sections having any desired regular geometric shape and for any desired straight slope of the bottom. The solution of the problem is based on the application of the law of the quantity of motion. The author introduces .,,. coefficient which represents the ratio between the resultants of the actual excess pressure on the contour of the overfall and the pressures corresponding to the hydrostatic pressure distribution. This coefficient accounts for the character of the flow of the stream on the overfall spillway (free, with air venting, without air venting, with suction). The author's experi- Card 1/Z ments substantiate M. D. Chertousovl s deductions to the effect  124-58-9-9869 The Velocity and Depth of the Stream Flow (cont. ) that when the slope of the drop is subcritical, the depth above the contour of the overfall is not equal to the critical value, but is smaller. Consequently the flow velocity exceeds that corresponding to the critical depth. This vel- ocity exceeds them critical velocity by 40 to 70 percent, depending on the flow conditions and the cross -sectional shape of the stream bed (rectangular, trapezoidal, or triangular). It is to be noted that the presentation of the paper is not sufficiently rigorous. Bibliography: 13 references. B. 1. Bek-Marmarchev 1 Dams--Properties 2. Inland waterways--Velocity 3. Fluid flow--Analysis 4. Mathematics--Applications Card 2/2  AM4008927 BOOK EXPLOITATION S/ Stepanov, A. A.; Popov,-V. N. Chemical warfare weapons and principles of anti-chemical warfare defense (Khimich- eskoye oruzhiye i osnovy* protivokhimicheskoy zashchity*), Moscow, Voy-anizdat 1962 123 P. il-lus. biblio. Errata slip inserted. 23,000 copies printed. TOPIC TAGS: civil defer-se chemical varfare chemical warfare defense lewisite J 5 ClCM, phosgene, diphosgene, CO, ada.-asite, chloropicrin, chloroacetophenone; tricUiortrie thylardne, mustard gas, HW PURPOSE AID COVERAGE: The reader will find in this book the necessary information on the use of chemical warfare in the past and the state of ito development at the present time. He will also obtain ansviers to his questions about how to protect ht-nself from chemical warfare. The book undoubtedly is of interest not only for the serviceman, but also for each citizen of our Xot;herland, especially for members of DOSAAF. The sections of the book on the characteristics of poisons and methods of using them are written from the vi.ws of foreigm armias. TABLE OF CONTENTS [abridged]: C.rd--1/2-  STEPANCYV, A.A.; 4DPOV,--V-.V.-i CHUGASOV, A.A., podpolkovnik, red.-, CHIPAYEVA, R.L~ tekhn. red. (Chemical warfare weapons and principles of antichemical defense] Khimicheskoe oruzhie i asnovy protivokhimicheakoi zashchity. Moskval Voen. izd-vo M-va obor. SSSR, 1962, 123 p. (MBA 15: 5) (Chemical warfare-Safety measures)  VUKAL(TITCH, M.P., prof., doktor tekhn. nauk; RASSKAZOV, D.S., kand. tekhn. nauk; POPOV, V.N., ke-nd. tekhn. nauk; BABIKOV, Yu.M., inzh. ------ t"-.- Heat properties of monoisopropyldiphenyl. Teplcenergetika 11 no.6: 56-58 Je 164. (KRA 18:7) 1. Moskovskiy energeticheskiy institut.  TSEDERBERG, N.V., doktor tekhn. nauk, prof.; POPOV, V.N., kand. t~qkhn. na-ak-, ANDREYEV, I.I., inzh. Experimental study of the viscosity of hydrogen. Teploenergetika 12 no.4$84-86 Ap 165. (MIRA 18:5) 1. Moskovskiy energeticheskiy institut.  POPOVY V.N.; FkDDEYEV, L.D. An approach to the theor7 cf a EdVE gas at I(rw temperalluireE. Z-'-iz-, eksp. I Loor. fiz. 47 rio.4:131~-1.321. 0 '64. Olliftbk 18: 1) 1. Leningradskoye otdcleniye FAtematicheskogo instituta, irmni V.A. Steklova AN SSSR.  ?C1f_0V V . 11; . function3 and thermodynamic function-; of a nonideal Bose-gas. "" r J~ " ~L -, ht; r. er. -,). i. tsor. f ` z. 1.7 ir,. 1: Mc~-1764 !1 1 ~4. 18:21 1. Leningradskiy gosudarstvenny.,y universitet  L 51-377-65 EWT(d)/T ACCESSIO~ ITRi AP5010970 --W/62S6/65/0OO/O()1/6i54/0155 I AUMORSP Popov, V. K.; Koleanikove; Ye. F., TITM: Clut f a Maximm momentc' Class 47f Ito. 169951 !SOURCEt ByUleten' izobreteniy i i6varnykh znakov, no. 7, 1961, 154-155 TOPIC TAGS: clutch, transmission,'-gear\1 ABSTRACT: Thia Author Certificate-~ipresents a clutch of a maximum moment, containing an immobile aasing within which ari contained the driven semiclutch and an engaging land a disengaging device (see Fig. 1 on the Enclosure). To improve the performance !of the clutch, a toothing and a planetary transmissionlre installed in the driven Isemiclutch. The satellite gears Wr-ekinematically engaged with the sola:- ring Lrd Iroll along the internal toothing, while the ring is rigidly connected to the d-rive- 'shaft. :n an alternate design the electric motor may be automaticall;r d~~Bcoanected from the working assembly by an arrangement of guides on the inside of the casing. 'The t,)othing rotates on rollers along these guides. In th6 third version, to Isimplify the conetruetion and to util.-Lize, the reactive turning moment of the drive , lithe engaging and disengaging assembly of the clutch consists of a roller, a hinged !racking lever, and a spring. These are fixed to the immobile casing and are spaced Isymmetrically an the outside rim of the toothing. Orig. art. hast I filpxre. :* U 113  L 51377-65 -ZSION NRt AP5010970r &-Got ASSOCUTICKi Donetskiy mashinostroitellnyy zavod im. 15-letiya. LEM (Donets i Ifachine Construction Plant) MOL z 01 %^,QDFl  ENCLOSM: 01 I I ul Fig. I I- i=obile :casing of thel Clutaht 2- toothingF 3- satellites of the -lanetary traunmiseion.1 4- solar rin9T 5- drive shaftj 6- electrio motor; 7- ring of the working assembly; 8- rollers;.9- spring [Card  AUTHOR: Gorbunovo- A. 6J(H68cov); p6pove 14, mi(Haircow) TITLE: Adams-type methalts for-an approximate solution of the Cauchy problew for ordinary dEfTerential equations with delay SOURCEt Chislenny*ye me-'tody* reshaniya diffarentsiallnyfth i Lntegrall- ny*kh uravnenty i kvadraturny*ye formuly* (Numerical methods of solv- ing differential and integral equations and quadrature formulas); abornik stitey, Hoscovi ttd-vo Nauka, L964, 135-148 TOPIC TAGS: Cauchy problein, generalized Adams formula, differentLal equaeiott with del approximdee method ay ABSTRACT: This article~..,.deala with an approximate solutiom of the Cauchy problem dx  L 13(3,E4-65 ACCESSION UR: AT4047142_~~ 0 f: ls~ sufficiently smooth a )Whe re curve defined in a certain closed domain of three-dimenstatial space, T(x) (delay) is a given positive iand sufficiently smooth function,and ~0(x) is a sufficiently smooth function defined or. a certain set of initial values. It is pointed iout that there is some p6saiblity that the approximate solution Y(X) :has weak discontinuitsas.':(discontinuities of the first kind of its derivative) and, therefore, "high accuracy" formulas of the Adams or Runge-Kutta type can not:be applied directly to the solution of this problem, and certain modifications of these formulas are necessary. Formulas for interpolating a function with discontinuous derivatives are derived which serve as the basis for constructiag generalized formulas of the Adams type,and the algorithm of their application to the solution of the given problem is presented. It is stressed tuat the method developed can~.*also be applied to the solution of cauchy tlems for cl-ssical ordiniry differential equations with discontinuous 1right-hand-sidesi for tht' neutral type of aquatLons,'and for other gnal.0gous cases* The convergence of generaliged methods of the Adams type is provedand an estimate of the computaticn error is established The -deriverd -results I 'are - extendnd to a system of equations. The !algorithms for solving the Cauchy problem for a'system of equations Card 'Zf 3  L 13054-65 !ACCESSION M, AT4047142 an'~d daltyt*d twLth CaterpolatLag a for argument functions vLth dLij- continuous derivatives art written in ALCOL-60 lar-guage. Tvo nuser- ical examples illustrate the integration procedure. Orig. art. has: .36 formulas. OUAT  1,~)672-6c) E'W'P( I) :EPA' 5~-2,"VdVm' /EPF(c ).,/EPF(p ';-2/27dG1 AS D', J WF1 W E ACCEKIAOX NR: AP4042486 S/0152/64/000/006/0055/0057 AUTHOR: Popov, V. N,; Taedi&rberg, N. V.; Morozova, N. A. TITLE: An experimental study--of the thermal conductivity of seven types of petraleura productz OURCE.,. JVUZ -Ndft.- I wun '7AG 67: TOPIC TAGS: petroleum fraction, thermal conductivity, desalted petroleum, benzine, kerosene, dlesel-oll,- fuel oil, masut ABSTRACT- Data on the chemical composition, thermal conductivity and other physical properties are tabulated for despIted petroleum, NK-140 benzine, TS-1 kerosene,~iatplos- pheric diesel oif(B. P. 202C), vacuum Ee-s-e-T-oil (B. P. 213C), a Fr-o-WT-Fa-ctff-on-olf the vacuum columa-(B. P. 2800, and magut (B. P. 22-501, all obtained from the same Ec-uroe. As shown in Fig. I of the Enclosure, the thermal conductivity decreased linearly with incraasing temperature (17. 1-300C) and was highest for mazut- Orrig. art- has: 1 ffgure and 8 tables. ASSOCIATION: Maskovskly endr ticheskiy in6rdtut (Moscow Povyer lustitute) 98 SUBAUTTED.- 27Jan64 ENCL: 01 SUB COM. FP Wo IMF Sow  AccEssica Na: AF037641 S/0096/64/ooo/oo6/0056/0058 AUTROR: Vukalovich, Mo Pe (Doctor of ted-le&I sciences, Professor); Razakazow, D. S. (Candidate of technical sciences); Popcw, V. N. (Candidate of technical sciences); Ublkov,, Yu. X. (Engineer) TITIZ: The=ophvoical properties of monoisopropy1dilpenyl SCOCE: Tepldenergetika, no. 6,,.1964, 56-58 TOPIC TAGS*. monolsopropy1diphenyl, Hagen Poiseuille equatica, Vargattik equatica.. ABSTRACT: The authors present the results of on experimental investigation of W density, thermal ccaductivity, heat capecity, and viscosity of mcnoisopropy1diphenyl. Me density vas determined by the pynconetric method at room temperature and by the piezcmetrio method for & constant volume at t a 50-35OC- Froa the experiment- al results the authors determined that the temperature dependence of tboe density P = 984-3 - 0-473t - 0.8U . 16-3t21 kz/123 W Calculation and eAperiment agreed vithin. 0.3$, Thermal conductivity vas dater- Card 1/3  ACCESSICK M. AP40370~1 minbd at t = 30-230C. The experimental data am well described by the Vargaftik equation (ItTeplofizicheskiye evoystva. veshchestv," Gosenergolz4at., 1956.) 4/3 (2) Calculatiou accuracy was witbla experimental error. Viscosity was computed ac- cording to the Hageu-Poiseuille equation 8LVL and was measured at t = 20-3r5W. Beat capacit.-r was determined according to a foraula obtained from the them&' balance of two calorimeters, wd vas measur*d at t w 3&.23X. Mgerlwatal dats, we described by the foUawing equation 1AW + 34.8 '10-4t (5) I Card 2/3  au'l w3siat Ap4o3T641 Discrepancy between calculation and experiment did not exceed 1.%. All the above values agree within experimental error vith those obtal6A by N. B. Vargaftik et al. ("Neft' I gaz" no- 7# 1963). Orig. art. hw: 1 figure, 5 fonaul and 2 tables. ASSOCIATlai: Hookovskly energeticheskly institut (Xoscoir Power Institute) t SUBMIT=: 00 -DATE ACQ: 22jun& I=L: 00 SUB CODE: OCj' -rD NO MW BOW: 013 OTW S 001 Card 3/3  L 8652-65 Ewi,(J)li7dp(m)/~I-4i(m)/F,?F(o)/EPF(n)-2/T~PR/T/3PA(bb)-?-/ FCS(k) / 114?(b) 77~.~Pd-4/Pr-4/Ps-4/Pu_4 AFTC(a)/ArJD(d)/ASD(p)-3/AS(mp)-2/ASD(f)-2/L~SD/ EDC(a)/3SD/E3D(t) A Z _-9 - ------- -AC AP 52 . . . . . R 8~/0294164100210041059 THOR: jgAjjkh__Qv,,_ B.S PoRov, V. 9. 'AU TITLE: Theoretical calculation of heat transfer and friction resis- :tancd Ln, a'turbulent f Idir ina pipe of equilibriuM dissociating hydr*-' SOURCE: .:Teplofizika'7y*i3'okikh-temperatur~ v6:2. no. 4, 1964i 599-611 V0PrC:'TAG8* tr -fir. ans _d1sso6i&tioii1 turbulent 'flwor _Xdrozea Airisociatlion v jhYd_rogen-,-*.XY,6.Gn._1 M1'XtU,re:0,-_ equilibria-z --,dissociation TRACT: A me od is given for theoretical calculation of heat trans-- 1AB f er and friction resistaice in a turbulent flow of dissociating hydro-1 gen in a pipe. It is astumed that the dissociation rate exceeds con- I siderably the convective~ .4nd diffusional mass transfer rates. In this' :case, chemical equilibrium is established in each point of the flov, and the composition of the mixture is a function of pressure and tem- perature only. In the ciae of equilibrium dissociation, the doncentra- tion profile in the flow may thus be defined without solving the diffu-.-- I.sion equation. The heat.-,.tranafer, friction reeistanceland different 'C.'T  a6 5 2Z 5_-i -4527 CCESSIP0 _.NR z~ Ap4o~ 'phy6ical-properties (speaffic enthalpy conduc_~ specific beat, thermal tivity, density, dynamic viscosity, and Prandtl number) were calculated f. lat 1, 10, and 100 atm and 2000-5000K. Dissociation results in unique changes ofiphys-ical properties as a function of pressure and temuera- 1 tixrit~,-~Thd~speoi:Cia-heat~itnd the thermal conductivity change markedly with temperature and exhi.bit maxima. Fig. I of the Znclosure shows that owing to changes in physical properties caused by dissociation the heat transfer may change by 400%. Comparison of Fig. la and lb shows, J khat when the correction t /a (a . specific heat at variable physical hlit)'-.is ueed,..&c&ttering of the 1properties; c ,average a0le Lta 7- Acen be reduceg from 380%_~o 30%. This signifies that the best transfer fis basically influenced b~ changes in the specific beat, and the effe4;'u 'of changes in vigeo ity mud density on heat transfer does not exceed 0.~, formulas and. figurese- 3n%. Orig. art. ha ASSOCIATION; none 64 LTD PRZ-89 gummEn. 1~ ENCL.. 02 [SUB CODEt FP ~.90 REF GOV: 002 OTHSH: 13 -7 214  ACCUSION KRI AP404452T ENCLOSU": 01 I I V I I III I n 4r IF &0 Oleo 71 Afj 00 or of #fT 31k  T 8ACCZ.Ar A=SSION MR9. AP044527 ENCLOSUREs 02 t too ww 5= f a e nee- 34V Fig,- 1. In luie a of variable physical propertie on heat transfere (NuO and 1.43401 71 M are Nusnelt numbers at variable and constant physical properties at the same 'S 9 Iz U Reynolds and Prandtl numbers.) T 1-- 7 Ie5_  Zip%  '~&- _13486-65,. EKT(I) rip (C Mswa 4/0" 1IC-Cmamolt, n- 'AR464 IAqMRSt PMGVP--V& 11# -raddgyev, L. Do OW tem- TiTLEt concerning one approach in the Bose crals theory at I J"- rnal eksparit~-irftallnoy-i--teorcitichellFkoy-fiz -v&--.47L__---4-~~-_-- URCE: ZIIIZ 3jjj8f,:ej,' low,te' research* perturba- LTOPT.C an, Mpf~ratliid Oh. theory Armihilat Green function, phonon aTRACT i An-approach-is)3uggealted for the theory of the Bose gas, belidvied 'to be more rigorous and simpler conceptually than the ear- er treatments. Tho metli6d La based on the promise that the exLS It nce of a condensate at I:w temperatures precludes the application lor ordinary perturbation theory in which the unperturbed Hamiltonian ;14 that of noninteracting "particles, since in the ordinary theory 1:,/3  as the -poi t -where. -the.~-ca,.ionical--t-rans-f-armation -degenerates the--identity trans arm t and th6'specially developed pertur- a ion an '!bation theory goes over i6to the usual one. The one-particle exci- :tation spectrum is shown t6 have a phonon character below the transi- tion temperature. Orig. art. has: 3 figures and 5 formulas. !ASSOCIATIONz Leningradskoye otdeleniye Hatematicheskogo instituta n4kad Div-' '- -on-'- im~.. Vo-A.~.Steklova (Leni LSi -Mathematics Tnstilbute, Academy of SciencesSSSR7   NU., MICIROZOVA, N.A. Fxp~--rimeraf,al Investivation of' the hippat cordi -Ictivity cUr WIP10:3. 1 zv. -JY!I. tic he b. zav. .- no no.4-'tl-'?4 164. 1. MrS'A-o-,%iklv en;~rgceticheskiy inst--*7;ulc;,  Programming system 4 no.ltl89-.192 J,  J :LcCNSSTO'N NO: AP4012005 L S/0208/64/004/001/0078/0095 AUTIHORt3 iPopov, V. N'. (moscm); Stepaov, V. A. (1.11asoow)l Stishavait A* 0. (3140900W)l Travnikov-a "'(1I"6ow) TTTL!5': Pro(Crwzing program SWIM.: Zhurnal vy*chisl. m9tem. i matem. fiz-, V. 4, no- 1, 1964,le-o.5 ,TOPIC TAGS- programming, program, triple address machine, binary code, uncondi- tional transmission, conditional transmission, manual programming, machine language ABSTUICT: A programming program is set up for. a triple-address machine vrith a nine- place binary code of operation and twelve-place addresses. The system of commands for the machine has all the basic arithmetic dhd logical operations'and operations on commands. There are commands of unconditional transmission of control and com- m=ds of conditional transmission according to the sign worked outby the preceding command. The machine has a large external memory. Programming programs have been in use since October 1962. The time of progrdmming is small; in the processing of one bit of information the time expenditure corresponds to 1000-2000 machine commands. Programs composed by a programming program are 1.5-2.5 times longer than Card 1/3  ACCESSION NO: AP4012005 pro~7rams oet up manually. The solution time fpr problems by progroms composed by a pro,-ran,.r,dn,,,, p~ro:--am it, 1.5-5 times greater than by programs composed marually. 'I'hi.15 relationship d(.,pendo stront~ly on the quantity of cycles and variable addresses in them, and also on "lie quantity of procedures. The authors discuss the input lan- t-,ua-e of a prog-r=min- program, the history of programming programs., and trans cod ing Q t. - U of informationi. They construct a table of boundary of conditional addresses, treat. preliminary processinU of information and its translation into machine lanoaa-e, classification of Drocedures and formulation of procedure-schemes, and processin1r; of informa' ion on block-s wid variable addresses. The problem of programing operators is separated into two stages: regulation of the oDerations and their Progranning . Reaulation of overations is reduced to seDaration of all syntactical units of the lang-Lia-gre into the sequences necessary for the program. Determination of the length of the pro3ram, construction of scales, and appropriation of true addresses are discussed. There are certain deficiencies in the programming program. It may have uneconomical formation of variable addresses. Now blocks are set up due to which these and other deficiencies are remedied. included in a programming program is a block for processing. variable addresses, linearly dependent on the parameter, With the help of commands of recovery and transaddress. With new processing of blocks an abstract of blocks is not set up, and the restriction on the quantity of bloeks is 213  V Al AUTHOR: Popov, V.N. 89-10-34/36 ---i- TITLE: _B4_;i:ew o the Book "Radiohydrogeology" by A.N. Tokarev, A.V. Shcherbakov, Geological State Publishing House. 1956, 262 pages, price Roubles 13,40 ("Radiogidrogeologjya",Tokarev, A.N., Shcherbakov A.V., Gosgeoltekhizdat, 1956, 262 stranits, tsena 13,4o Rub.) PERIODICAL: Atomnaya Energiye, 1957, Vol- 3, Nr lo, PP- 376-377 (USSR) ABSTRACT: This book is the first of its kind to be published in the Soviet Union. It consists of two parts. The first part contains three chapters: The first chapter discusses the causes of radioactive elements contained in water. The second chapter deals with the problem of various types of natural radioactive water. The third chapter is devoted to hydrogeological conditions which lead to the formation of uranium deposits. The second part consists of aix chapters dealing with radiohydrogeological methods of investigation. The book contains both theoretical as also a is 'rge number of ex- perimental data which were most suitable selected by the authors on the strength of their many years of experience. It is a draw- back of this book that the text was not sufficiently well revised and corrected. AVAILABL4: Library of Congress Card 1/1  P.'J7.-,C)Vj V. N. Popov, V. Ii. -- "Aspects of the Growth and Developirlent of Apple S,-edlirxs when Grown in Nurseries on Various Types of Stock." Min Higher Edu,-.ation USSR. Voronezh Agricultural Inst. Voronezh, 1956. (Disseration For the Degree of Candidate in Agricultural Scienccs). So: Knizhnaya Letopisli No. 11, 1956, pp 1034-11),  P V VI'__ USSR / Cultivated Plants. Fruits, Berries L-6 Abs Jour : Bef Zhur - Biol., No 6, March 1957, No 22823 Author : Popov, V.N. Inst : Not Given Title : Mother-seed Apple Tree Plantings. Orig Pub : Sad i ogorod, 1956, No 7, 48-50 Abstract : The results of a study are stated on the effect of pollination in mother-seed gardens on the yield of apple seeds, their quality and vitality of wilding seedlings, conducted in the I.V. Michurin Scientific-Experimental institute of Fruit Cultivation. The most successful ovary was obtained by dusting with a pollen mixture of local, stable varieties yielding large fruits. Card 1/1  POPOV, V.m. -- - 111--,- Iffect of rootstock on the water cycle of grafted apple plants. Fiziol.rast. 3 no.1:66-72 Ja-F '56. (WaA 9:5) 1. Ilauchno-issledovatellskiy institut plodoyodetva imeni 13. Nichurins. Hichurinsk. (Apple)  POPOY, V.11.. kand.sellakokhoz.nauk Apple traos for need and the effect of various pollinizors and varieties used for grafting on the root system of stock. Dokl.Akad.sellkhoz. 24 no.12:1)-17 159. (MIR4 13:4) 1. Rossoahanakeya plodovo-yagodnaya opytnaya stantRiya. Pred- stavlens soktai7ey plodovodstva Tsnsoyuznojr akademit aellskogo khozyaystva imeni V.I.IAnina. (Apple) (Ronts(Botany))  -t,resigr T-1 and of Its si;T- -_law cr I cOnd Dt IZ OL ~S 4' thcr= Of kf.-,~SiUe IE tcm!ir.. up to 2log' vad p~murtx up to 100 A un, Ilm rimz5urements w~-c madt in a quartz app., and tle results-wtrc v3mpar,,-3 vnth those -mmordiug to 0. formu!i. Thr agre=4mt, whimh b fair, c= b-c L-aproyta a (tcvLt0,nmj etc (Aklal jaw rq1t;61crottan tx~".c4a (6.  POPCV, 0:-Ild lech Sci-(di2s' tuc-, n", physical properties oi' liquid fue1c." 195-~- 16 rp of fl-~eher .-duc-.Lion USSR. Los Ur'-Cr of Lenill Power 1-111cri 11c; Inst) 1(,-10 GQ'Ac:~ YTI, 9 25-58 2  POPOV, V.N.; TSIMEM, N.V. lxperimental determination of the heat of vaporization of liquid fuels. Nauch. dokl. vy-s. shkol7; anerg. no.1:161-168 '58. (MMA 11:10) l.Rekomendovano kafedro7 TOT Moskovskogo onergetichaskogo instituta. (Liquid fuels) (Heat of vaporization)  AUTHOR: Tsederberg, N.V. (Dr.Tech.Sai.) SOV/06-38-10-15/25 Popov, V.N. (1~igiueor) TITLE: An experimental investigation of the thermal conductivity of helium. (Eksperimentallnoye issledovmiye teploprovodnosti geliya) PIMIODICAL: Teploenergetika, 1958, No.10. (USSR) pp. 01-65 ABSTRACT: Published work on the thermal conductivity of helium is reviewed. experimental values over the pressure range of I - 212 kg/cM2 have been published in only one work and relate to a temperature of 42.80C. The most reliable data for the temperature range - 200 - + 6000C, at atmospheriepressure, are given in Table.l. The maxim= M error in these determnations is 1.83%. Determinations were made of the thermal conductivity of helium under pressure, using the hot-wire method in a glass measuringg tube. At pressures up to 100 kg/cm2 a steel bottle of helium was used, and at higher pressures a mercury compressor, The helium was 99.8% pure, the remaining 0.2% being nitrogen. The measuring tube was in thermostatically controlled water, glycerine or molten salts, according to the temperature. The apparatus is described, also the method of use and the way of working out the results. Correction for radiation from the wire and for the leads is explained. The main characteristics of the measuring tube are given in Table.2. The method of ageing in described. The equipment was checked by determining the thermal Card 1/2 conductivity of air, comparing the results with those of other authors.  An experimental investigation of the thermal conductivity SOV/96-58-10-15/25 of helium. Agreement was to within 0.5% of the most reliable values. Graphs of the thermal conductivity of helium an a functian of temperature on the isobars of 1, 100, 200, 300, 400 and 500 k9/cm , and the results of controlled tests at 10 kg/cW9 are given in Fig.3. The scatter of experimentnl points does not exceed 1~- Published data of other authors is included and agreement is good. The use of a logarithmic co-oz-dinate ry-stem in proposed and the experimental results are plettod in tii-s system in Fig.4. Equation (2) accurately represents the thezzal conductivity, of helium under pressure. Calculated values of the thermal conductivity recommended for practical use are presentcd in Table.3. There are 4 figures, 3 tables and T-Sovist references. ASSOCIATION. Moscow Power Institute (Moskovskiy Energeticheskiy Institut) Card 2/2  SOV/96-58-13/?l T AUTTIOR: P07dov, Y-T., - ti~ 1-3 a ~~~ 2?10 ergy rj.V., Doctor of Technical Science TITLE: The Thermal Conductivity of Liquid Fuels (Teploprovodnost' zhidkikh topliv) PERIODICJIL: Teplo-!~ner,-,eti!~-a, 1953, Nr 11, pp 7?-76 (USSR) ABSTR~XT: 1xistiRg wotl~ on the thermul conductivity of liquid fuel, mainly 2~merican and German, is briefly referred to. In Teplo~!nergetika 1-0,57, Nr 8, the present auth-ors described wox~-,: on the thermal conductivity of ~-erost-~ne. The Predvoditelev-Vargaf-uik formula for calcul-.~,,tin6 them thermul conductivity of pure normal li(yaids is Ljven. In order to verify the validity Card 1/5 of this formulu for other materials, determinations  .1 SOV/96 -5 ej -1. 1 -13/? 1 Th,~ Th!rrijul Coijductivity of' Li(.,,ui(I Flitla 1111.~A,! of the tlaer:n-l conductivity, da!ncity aid ,pncific I--- -~t for b!~nzinn, B-79, di.-!scl fu-1 NO.3 i a sp'!~cific 6ruv;ty L;,t 10 C of 0.843 and ilAtial th U boilix:L; point of "'10 C, nd -:7;utf--r ditscl fuel No.4. with " sp-~cific L,,-r-vity at ')0 0 8f 0.850 kdlitre --d initial boilir,~-, point of 190 C. T~ic uppurtnt n.i~!cular -2i -hts arid viscosities, of fuels d --t~~rmined by 1b.V. Samc!,-VIrj-alova amd R.Z. Sul~~vm,:~nova. The thermal conductivity of -U~.Le flUel WUS aetermined by the use of four meusurinE tub~-s similur to those described in the prTvious .iork; the mL~in churucteristics ol the tubes are U 0 ,:~iveia in Table 1. The ther;ni.;Ll c nductivity of b!!mzint-. B-70 u~-s investigated at a pressur- of 10 atm over the terilper-ituri rur~,e +90-+1100 C. The U r~!,--Ults art plott,!d in Fi8.1. and recorded in Tabl~! 1. The th~.-rmul conduct ivit ies. of diescl fuels "os.3 und 4 determined at 10 4nd 50 atm. 1'4 1) over the temperutur-~ r.-Ln~-,e - 50 to + 2150 C. Vit! r~~sults for tli,~ fortralnr urn .--ivea ir-. FiL.'). und Card 1)/5 C~ Tuble 3 and for t~,e lutter in Fi6-3- and Table 4.  SOV/%9' -5 8-11-13/21 The The---mul Conductivity of Li.-.:-"-id lla~--ls Tia~~ root me-n square! orror of individual determinations of thermul Conducti-,;-itY is 1-35. The r~!lationsliip betw,2-2n tli,,~ SpnCifiC- L'r,;Lvity and temperature of Fuel .,:,To-3. ut various pressures is plotted in Fig.4. und t:.ibulated in Tuble 5. Similar data for fuel No.4. ure given in Fi,~;.5- and Table 6. Tible 7 ~,ives tLe sp,acific ErcLvity of benzine B-70 at atmospheric pressure. The r -~l,.Lt ions hip bet-wi~en the specific beut und the tem.-,erutur,~ of fuel ITO-3- at constz.,.nt pr,!ssur.,! is ,,:-iven in Fig.6 . and Tabl- 8. Similar dattL for the fuel No.4. are given in Fir,,-.7. and Talbl,~ 9. Valu--,~s of t1ae specific lacut of benzine.- 1,To.D-70 are driven in Table 10. It -,,,iill be se3n -Lrom Fi-,s.1los.6 and 7. thut tub-e pressurT has no ,~-fff!ct on t1L -in specific b-cat in tt-ie range of 1-50 atm. In order to vprify tb-,!! accurUcy of the forrm,la-! of Cra~;oe (U.S. of Standards) and Predvodit,:!l,-v- Var,~~aftilr 'lie thermal conductivities of benzine B-70 C.-:ird 3/5 and th'! t'vfo diesel fuels vier!! calculated by these  The Therm"l Conductivity of Liquid F'aels SOV/96-5 (0-11-13/?l formiulut uiad compared with the expnriment,--l rts"alts. It is concluded that Cra6oels formula is int%ccur~~te --Oncl tb-ut the! Predvoditelev-Vur,~~aftik formula ,,eives the absolute value of thermal con~.Uctivity of the fu~,]- to -witLn 10%. The appurent molecular wei4L lat s of thf! fuels in question are 8iven in Table 11 as determined by a cryoscopic method. Experimental results for the ther:-,iul conductivity us a function of temperLAture ut atmospheric pressure for all. the fuels investir.-ated in the present work ure plotted LD in Fi,-,.8. -which also --ives data for kerosene T-1 L~ and its heav-y fractions. An empirical formula is offer,nd for calculation of the thermal conductivity of fuels in the Sp5cific gravity range of 0.750 to Card 4/5 0.350 kg/litrt. This formula ~,ives results  Tte Thermal Conductivity of Liquid F,,-iels SOV/96 -5 3-11-13/?l .7it hi- ,ccur~.,.tt- to T -q 41f the only d"ta 6equired is t'lle, S-pecif-!C ---r.LVitir of ttj~, f'UO,31 Lit C. TK,~!r-e mr-a t-,!C 5 'S6Viet'-references- ASSOCLITIOil: moslrovsl~iy ellar,cticllesl~iy irastitut i-> (Moscow Power Institute) Card 5/5  69205 ;Z t~, 52-oo S/096/60/000/06/018/025 E194/E284 AUTHORS: Tsederberg, N, V.1, Doctor of Technical Sciences, ,.Popov, V.,-N.,,'Candidate of Technical Sciences, and Morozova, N. A., Engineer TITLE: An Experimental Investigation of the Thermal Conductivit of Argon 1/1 PERIODICAL: Teploenergetika, 1960, Nr 6, pp 82-87 (USSR) ABSTRP.CT: Previous experimental work on the thermal conductivity of argon is reviewed. Published values for the thermal conductivity of argon in the temperature range from -200 to +6000C at atmospheric pressure from a number of authors are plotted in Fig 1. Available experimental data for the thermal conductivity of argon in the temperature range from 300 to 110000 at atmospheric pressure is plotted in Fig 2. It will be seen from -200 to +200'C there is good agreement between the results of all authors but there is increasing divergence at temperatures above 2000C. The thermal conductivity of monoatomic-gases at atmospheric pressure may be calculated by expression (1) --md the curve for argon for temperatures of 0 to GOOOC constructed by means of Uard 1/4 this equation is plotted in Fig 1 and in general  69205 S/096/60/000/06/018/02r-/ E194/E284 An Experimental Investigation of the Thermal Conductivity of Argon agreement is good. Values for the thermal conductivity is argon at atmospheric pressure over the temperature range of -200 to +6000C corresponding to the curve given in Fig 1 are presented in Table 1. Higher temperatures are not considered in the present article because of the great differences between the published results of various authors. The thermal conductivity of argon under pressure was studied by the hot wixe method using two glass measuring tubes, The instrumentat- tion, and experimental procedure are described and the method of working out the results was the same as that used in determination of the thermal conductivity of helium described in an article by the same authors in Teploenergetika, 1958, Nr 10. The principal characteri- stics of the two measuring tubes used in the tests are given in Table 2. In checking the apparatus measuremenil-_- were first made of the thermal conductivity of air and good agreement was obtained with published results as Card 2/4 will be seen from the graph plotted in Fig 3. Graphs  69205 S/096/60/000/06/018/025 E194/E284 An Experimental Investigation of the Thermal Conductivity of Argon. of the thermal conductivity of argon as function of temperature on isobars ranging from 1 to 500 kg/CM2 are plotted in Fig 49 in the majority of cases the scatter of experimental points did not exceed 2..q%. Values of thermal conductivity obtained by other authors are also plotted in Fig 4 and it will be seen 'that the present authors are in good agreement with some other published work. On the basis of available experimental data calculations %ere made of the specific gravity of argon over the temperature range from2-90 to 10000C and pressures from 100 to 500 kg/cm and the results are given in Table 3. Table 4 gives values of the specific gravity of argon on the upper and lower boundary curves. Fig 5 gives the results of experimental data on thermal conductivity of argon under pressure obtained by various authors when plotted in terms of Eq (3), which is the Card 3/4 empirical form of Eq (2) and it is concluded that this  /A J/00 B/096/60/000/010/012/022 E19VE135 kUTHORS: Tsederberg, N. .9 Popov, V.N., and Morosova, N.k. TITLE: Investigation of the Thermo-physical Properties of Heli in the Pressure Range 1 to 200 kg/CM2 and, the Temperature Range 0 to 600 OC~ PERIODICALS Teploenergetika, 1960, No 10, P 95 TEXT: The experimental equipment is described. Equations are given relating the thermal conductivity and Viscosity of helium with temperature and pressure, and tables.of thermal- physical properties are given. The tabulated data of thermal Ve. conductivity and viscosity are determined on the basis of' the authors' own experimental work and also published work. ASSOCIATION: Moskovskiy energeticheskiy institm-t (Moscow Power Institute) Card 1/1  TSEDERBERG9 nikolay Valerianovich; TP~OV,_Valentin -11~,IQlayqvtch; MORO- ZOVA, Nadezhda Anisimovna; RASSKAZOV, D.S., red.; VORONII, K.P., tekhn. red. [Thermal and physical properties of,helium) Tep-lofizicheskie Svoistva geliia. Moskvag Gos. energ. izd--wj 1961. 3.18 p. (MIRA 14:8) (Helium)  432-c-1 S/84 62/000/000/126/129 D444YD307 AUTHORS: Gudkov, B. 6., Dzantiyevy B. G. band Rum- yantsev, Yu. M. .I TITLE: Exi)erimental methods for radiation-chemical inveatigaticns on a nuclear reactor SOURCE: Trudy II Vsesoyuznogo sovesholianiya po radiatsionnoy khi- mii. Ed. by L. 6. 2olak. Moscow, Izd-vo AN S36R, 1962, 733-737 TEXT: Among reactions suitable for effecting in a nuclear reactor to make use of the kinetic Qnergy of the fission fragments is the fixation of nitrogen in the gas phase to corm hydrocy0anic acid, hydrazine and other compounds. The authors have studied such reac- tiono using methane, ethylene or acetylene as the carbon-containing and nitrocren and ammonia as the nitro,,ren-containing components. An ~fPT_1000~IRT-1000) reactor of 100 kv'capacity was used by the In- stitut atomnoy energii AN 33SR (Atomic bnergy Institute of the AS USSR) to study the reactions under flow conditions. The exit gases Card 112  PETUKHOV, B.S.; POP.OV, V.N. Theoretical calculation of heat transfer and frictional resistance in the turbulent flow of an incompressible fluid of variable physical properties in pipes. Teplofiz. vys. temp. 1 no.1-85-101 ji-Ag 63. (MIRA 16:10) 1. Moskovskiy energeticheskiy institut.  ACCESSION NR: AP4004139 S/0294/63/001/002/0191/0197 AUTHORS: Makavetskas, R. A.; Popov, V. N.; Tsederberg, N. V. TITLE: Experimental determination of the viscosity of helium and nitrogen SOURCE: Teplofizika vy*sokikh temperature, v. 1. no. 2, 1963, 191- 197 TOPIC TAGS: dynamic viscosity, viscosity, helium, helium vis- cosity, nitrogen viscosity, gas analyzer, gas analysis, gas property, rTas viscosity, nitrogen, helium nitrogen mixture a ABSTRACT: With an aim at filling the temperature gaps in the exist- ing experimental data, the coefficient of dynamic viscosity of helium, nitrogen, and their mixture was investigated experimentally in the temperature range 10--6600C and in the pressure range from 1 to 600 kg/CM2 using the method of Professor D. L. Timrot (Izv. VTI, Card 11A  ACCESSION NR: AP4004139 No. 3, 1940), which employs a capillary and an annular balance "I"he smoothed data obtained from several sets of isotherms agree with the experimental values within 2%. Orig. art. has: 3 figures, 5 formulas, and 3 tables. ASSOCIATION: Moskowskiy energeticheskiy institut (Moscow Power Engineering Institute), SUBMITTED: 03Jul63 DATE ACQ: 26Dec63 ENCL: 02 SUB CODE: AS, PH NO R113F SOV: 004 OTHER: 006 Card 2/1 '~--  ACCESSION NR: AP4004144 S/0294/63/001/002/0228/0237 AUTHORS: Petukhov, B. S.; Popov, V. N. TITLE: Theoretical calculation of heat transfer and friction re- sistance in laminar flow in pipe of incompressible fluid with vari- able physical properties SOURCE: Teplofizika vy*sokikh temperatur, v. 1, no. 2, 1963, 228-237 TOPIC TAGS: heat transfer, laminar flow, coolant, air heat transfer, hydrogen heat transfer, MS-20 oil heat transfer, transformer oil heat transfer, hydraulic resistance, Lqusselt number, incompressible fluid, fluid flow, incompressible flow ABSTRACT: Although calculations of heat exchange and hydraulic re- sistance in laminar flow of liquids with variable physical proper- ties in pipes are encountered in many branches of engineering, the existing theoretical papers are devoted only to limited aspects of the problem, and none contain an analytic expression for the hea'. transfer. The authors derive analytic expressions for the Nusselt numbler and the hydraulic resistance coefficient for laminar flow in Car" 1/2  ACCESSION NR: AP4004144 -1 pipe, away from the inlet, for an incompressible liquid with ar- bitrary temperature variation of the physical properties. These analytic expressions are used to calculate the heat emission and the friction resistance for air, hydrogen, water, Ms-20 oil, and transformer oil. In the calculations for oil and water, the vis- cosity ratio ~Wall/pliq ranged from 0.16 to 51. The temperature factor Twall /T liq for air and hydrogen ranged from 0.4 to 1.75. Em- pirical equations are derived for the Nusselt number and the friction resistance. Orig. art. has: 3 figures, 14 formulas, and 1 table. ASSOCIATION: Moskovskiy energeticheskiy institut (Moscow Power Engineering Institute) SUBMITTED: 18Jul63 DATE ACQ: 26Dec63 ENCL: 00 SUB CODE: Al, PR NO REF SOV: 004 OTHERt 006 Cad 2/2 V_  AMID, Yakov Isaakovoch; BUKMTTSEV, G.V., kand. tekhn. naukj, otv. red.; POPOV, V.N., red.; TIROMMIKO, A.S., takhn. red. [Thermal similarity, convective heat exchange and entropy] Teplovos podobie, konvektivrqi teploobuwn i entropiia. Izd-,vo KharIkovskogo goo. univ,, 1962. 112 p. (14IRA 15-10) (Heat-Transmission)  -POPOVI V. N. ------ IlTheoretical cal-c-ullattion o--:' heat transfer and friction resis-taz-,2e --~r sur-er- critical carbon dioxide." report submitted for 2nd All-Union. Conf on Heat & Mass Transfer, minsk, 4-12 May 1964. Moscow Power Inst.  FIEMKI10VI B.".; F-o',ov, V.N. Thaoretical calculatinn :Z the heat transfer and frictional resistance in turbulent flow of equilibrium dissociating hydrogen. Teplofiz. vys. temp. 2 no.4z599-611 JI-Ag 164. (MIRA 17:01) 1. Moskovskiy energaticheskly In5titut.   --card, 4/2  ACC NR- 2,26027579 Popov, V. 1-:0rozova, ."--'o3cm.- 111Gtituto of id -1-rol r duc '13 2',.-norimontal datei-iAnation of licat capacity of 'Liqu Pol OUM 1) 0 -LVZ;Z. -~eftl i no. 3, Ya66, 60 and p. 86 R Fq r c..) ij.-) c / 7, V TO'.':C '.~XS: petroleum, product,'notrolcum fuel, diesel fuel, lubricatinr~ oil D3 diezu.1. fuej., TS-1 potroleum fuel, ~'-3 iubricatiwr oil, lubmcati~,.d oJI, tc2ts pcrfom-.ed on 1L d-Ozol Tae a7ithors -,)rcscrt the rerults of licat can-acity -Val (density 0.537 r-/cu cm), TS-1 fuel (0.7866 d cu c-3), :.',-3 lubricatin,r oil 0.874 dcu cm) and AX-1 lubricatin.- o--*l (0.923 decu. ci;). A calorimeter witil an adiabat'c -for tests at- atmoop er closi-.re -;.,as used h ic pressure -Walle for hir~-,cr pressures an izozn~a;ri enclosure vas appaed. '!'ho calorimneters urcre cacclxcd for the knoim ca*aciTieo of tolueno an--7 va-cer, as s*.-.o-..,-.,i in two ~;=ohs. 'Z-.c result-. of tests a. different tomerat-arao ara -oresented in two tables of wliich the first covers the tcsts perfomeCL at a press-ure of I kg/sq cm and the second at 3 kp,/sq cm. OriG. art. has: 2 graphs, 2 table*. SO COM: 21 SUM DJV2E-. 1OFsb65 ord UDG: 665-5-:536.22.001.5  POPOV TSEDF, C, f i ra I c, nIf Experimental invesl~ i g,~z no petroleum Products. Ucheb. zav.; n (nir-A 79-81 165. 1. moskovskiy energeticheskiy institut-  ACC "" AR6036311 SOURCE CODE. UR/0273/66/000/009/0031/0031 AUTHOR: Popov, V. N.; Ashmarin, N. M.; Mazur, B. 1. TITLE: Boosting the performance of an internal-combustion tractor engine SOURCE: Ref. zh. Dvigateli vnutrennogo sgorantya, Abs. 9. 39. 208 REF SOURCE: Tr. Chelyab. in-ta mekhaniz. I elektrifik. s. kh., Vyp. 24, 1965, 69-77 TOPIC TAGS: internal combustion engine, tractor, carburation, film carburation ABSTRACT: The use of volumetric-film carburation (TSNIDI type combustion chamber) gas-turbine supercharge, increasing of the diameter by 716, and raising operating speeds from 1050 to 1200 rpm makes it possible to raise the capacity of an internal-combustion tractor engine by 80016. The advantages of volumetric- film carburation with respect to economy in the case of gas-turbine supercharge are practically unchanged. The method adapted for boosting the tractor engine makes it possible to increase its per unit characteristics to a level of the best _d efficient in achieving modern tractor engines. It is found to be economical an good results within a short period of time and at minimum cost. [Translation Of .abstract] 1 11 cTm t-nrwr- 91 1 TTnfl- A91 A'49 CNTJ  """CC AR6036310 SOURCE CODE: UR/0273/66/000/009/003110031 AUTHOR: Popov,. V.. N..; As.hmarin, N. M. -- Ashmarin, Yu. M.; Mazur, B. I.; Kochetkov, V. I. TITLE: Effect of gas turbine supercharge on the pickup of an engine SOURCE: Ref. zh. Dv-igateli vnutrennogo sgoraniya, Abs. 9.39.207 REF SOURCE: Tr. Chelyab. In-ta mekhaniz. i clektrifik. s. kh., vyp. 24, 1965, 97-101 TOPIC TAGS: internal combustion engine, supercharger, supercharged engine, combustion chamber, diesel engine/DSP 11 diesel engine ABSTRACT: Results are presented of comparative tests of the KDM-100 internal- combustion and the D-108 and D-130 diesel engines with TKR-11 turbo-compres's jr or.' manufactured by the Chelabinsk Tractor Plant. DSP-11 diesel oil with MNIIP-2~K-i additive and GOST 305-58 diesel fuel were used for the engines tested. The temperature conditions was maintained at practically the same level for all engines and the oil and water temperatures at the engin's outlet were 70-76C and 75-85C, L Card 1 / 2 UDC: 6 21. 436. 001, 4  -ACC NRx -AR6036310 respectively. The results of the tests obtained under identical conditions relative to the quality of lubricant and nearly equal moments in inertia of comparable engines, confirmed the following: replacement of the precombustion chamber on internal combustion tractor engines by a chamber in the piston TsNIDI type engine virtually did not induce changes in engine pickup. The pickup of the D-130 engine using the TKR- I turbocompressor and the chamber in the piston type TsNIDI is equal to or slightly better than the pickup of the KDM-100 internal combustion engine. [Translation of abstract) [NT) SUB CODE: 21 2/2  ACC NR: AP6033955 SOURCE CODE: uR/o294/0~6/coii/co5/o689/0697, Aum.-.3: Popov-, V. N. ORG: PlAoscow Power Engineering Institute (Moskovskiy energeticheskiy institut) !TITLE: Meoretlical calculation of heat transfer and friction resistance for carbon I dioxide in the supercritical region for laminar flow in a round tube .'SOURCE: Teplofizika vysokikh temperatur; v. 4 no- 5, 1966, 689-697 !TOPIC TAGS: carbon dioxide, gar. flow, laminar flow, heat transfer, I Jd frictlon U L iABSTRACT: This is a continuation of earlier work by the author (Teplo- i massoperenos; :V. 1, 11.1insk, 1965) where heat transfer and friction resistance were calculated for carbon dioxide in the supercritical region for turbulent flow in tubes. 'Ine present paper is devoted to laminar flow. The au'hor calculates the local heat trans 'fer and friction resistance far from the entrance to the tube at constant heat flux den.,iW on the wall. The calculation procedure was described in another paper by the autthor ,(with B. S. Petu],zhov, Teplofizika vysokikh temperatur v. 1, no. 2, 19 3' - The cal- :culations were made at pressure of 1.00 atm at 20 - 600c, both for heating and ior cooling. The physical properties of carbon dioxide were taken from various published sources. Separate calculations are made for each temperature. Plots are obtained forl It'he radiant distribution of the temperature, velocity, and mass velocity for t'he heat .- !transfer as a function of the density ratio at the fluid and wall temperatures, and of: the friction resistance as a function of the same ratio. Interpolation formulas are 1/2 UDC: 536.24: 6051-97  -1-0 _a.. peop 's Re -gol. i i..- 7!,) 1":  POPOV, V.N.; KUTSELI, Ye*N. Methods for compiling certain trpes of hydrochemical maps. Vop. gidrogeol. i inzh. geol. no. 18:176-184 159. (MIRA 14:5) (Water, Underground-41aps)  PCOOKAREV, VaBiliy Kaksimovich; P0POV.,__j.A,,_, doktor 63ol.-miner.nBuk. otv.red.; LADYCHUE, L.P., red.izd-va; MILINIKOVA, N.B., red. izd-va; GOLUB', S.F.. tekhn.red. - [Underground waters in regions with a thick layer of permafrost] Podzemaye vody territorii a moshchnoi tolshchei mno-oletne- merzlykh gornykh porod. Koskva, Izd-vo Akad.nauk ssm, 196o. 198 P. (MIRA 13:12) (Frozen ground) (Water, Underground)  RYABCHENKOV, A.S.; ADTON2-iKO, K.I.; TITOV, H.A.; CHAPOVSKIY, Yo.G.; CHUR JITOV, M.V.; KONOPIYANTSEV, A.Z.; VIKTOROV, S.V.; VOSTOKOVAYA, Ye.A.; SADOVSKIY, R.D.; EUDELINT ,, B.I.; OGILIVI, !".A.; LUNWISGAUZEN, Q.F.;B,:,,ODSKIY, ' '.A.; SEECIM G-V, A' .". . ; -V,AT.-;YEnL'YANOVA, SOKOLOV, S.S.; BERSETMEEV, I.I.; CFOS~w, S.I.; RAMCAVEYEVY A.Aj II-AMIOV N.A.- YEFEIIOV, A.I.; ASSOVSKIY, G.N.; VLADDIIROV, A.G. deceasedi; PROK"HOROV, S.P.; FILIPFOVA, B,S.-, red. izd-va; BYKOVA, V.V., teklin. red. [Methodological manual on hydrogeological surveying at the scales of l:lpOOOjOOO - 1:500,000 and 1:200,000 - 1:100,000]1.fetodiche- s1roe ruk-ovodstvo po gidrogeologicheskoi s"emke masshtabov 1:1000 000 - L;5000 000 1 1:200 000 - 1:100000. Pod ob3hchei red. A.A.Ilal7kaveeva i A.S.Riabehenkova. Moskva, Gos. nauchno- tekhn. izd-vo lit-ry po geol. i okhrane nedr, 1961. 318 p. (MIRA 15:3) 1. Hussia. (1923- U.S.S.R.) Kiristerstvo geologii i okhrany nedr. (Idater, Undergrourd) (Geological surveys)  glav. red.; MAKKAVEYEV, A.A., zam. glav. red.; PAVLOV, B.S., red.; RODIONOV, N.V., red.; SHCHERBAKOV, A.V., red.; NEMANOVA, G.F., red.izd-va; SfIMAKOVA, T.M., tekhn. red. (Methodological handbook for making hydrogeological surveys on 1:50,,000 and 1:25,000 acales]Metadichaskoe rukovodstvo po pro- izvodstvu. gidrogeologicheskoi s"emki v masshtabakh 1:50,000 1 25,000. Moskva, Gosgeoltekhizdat, 1962. 370 p. (MIRA 16:3) 1. Moscow. Vsesoyuznyy nauchno-iseledovatellskiy institut g1dro- geologii i inzhenernoy geologii. (Water, Underground-Maps)  ;/169/63/000/002/070/127 D263/D307 .:AUTHORS: Ponov. V. N. and Kutsel" Ye. N. TITLj3: Formation of background and anomalous concentrations of radon in underground waters and their mineral value6; 'PERIODIGAL: Referativnyy zhurnal, Geofizikat no. 2, 1963, 10, ab- stract 2D63 (Sov.-geologiya, 1962, no. 4, 93-99) TEXT: Background concentrations of radon in the underground waters, of many lithological complexes of non-ore-bearing rocks are charac-i terized by Varying but fairly close values, not exceeding 36 emanso' Background contents of radon. in. waters underlying zones of tecto- nic disturbances in acid magmatic rocks may reach 75-100 emans. In areaiof deposits or ore-exposures-of uranium, and aluo in rocks containing radioactive-elements in a dispersed state, the under- ground waters contain-anomal-ous concentrations of radon. The authors concentrations to be regarded as anomalous are (a) in.exces6*oflOO emans for a background of.up to 36'.emans, (b) in exces's'.0f,.:'75 emans for a background of up to Card 1/2  S/162/63/000/002/070/127 Formation of background-... D263/D307 20 emans,.and (c) in excess of 50 emans for a background of up to 10 emans. Maximum radon-contents in.underground waters circulating in regions of hy-drothermal deposits may, reach 200,000 emans. For sedimentary deposits under-oxidative-conditionst concentration of radon in water is generally not greater than.10,000 emans; in the reduction zone it is not more than 3,000 emans. Radon anomalies- conne6ted with deposits or ore exposures of uranium are accompanied by anomalous radon and uranium concentrations in the waters.Accu- ..rate investigations of the nature of radon anomalies should be car- ried out with due consideration of geological, tectonic and hydro- ..-dynamic conditions of the region. Abstracter's note; Gomplete -translation. Card 2/2  A N -M--W-Al~ 602 9 778 SOURCE CODE: UR 10291, 1 '6'0(-A/00'1/053i/05 30 AUTHOR: Popov, 11. N. Petukhov, B. S. ORG: Moscow Power Engineering Institute (Moskovskiy energeticheskiy institut.) TITLE: Theoretical calculation of heat tranafer and resiattince in laminar plpe flow of_~y 49B~ij,'~dissociated in equilibrium SOURCE: Teplofizika vysokikh temperatur, v. 4, no. 4, 1966, 531-539 TOPP~ TAGS: heat 'exchanger, hydrogen, -j=0pw1s4:bw ABdTRACT: In high-temperature heat exchangers, the viscosi of the gas becomes so high that a laminar flow regime is frequently established. Therefore, a theoretical study us made Cf the Imal heat transfer coefficients and the flow resistan d#ing laminar pipe flow of dissociated hydrogen. The heat flux through the wall was assumed to be constant. The results calculated for pressuresof 1, 10, and 100 atka at 2000-5000K are presented In graphs. Orig. art. has: 5 formulas and 8 gures. [PV) SUB CODE: 21/ SUBM DATE: 270ct65/ ORIG EREF: 002/ OTH REF: 003 A7D Vo-lv,~ Card 1/jtz~ljn UDGG 536,24.01.532.542.2  L 417a8-66 EWT(1)/EW(n, )/T IJP(c) ACC NR: Ap6o20210 SOME CODE: W0056/66/050/006/1550/1155E AUTHOR: Popov, V. No CM: Mstbema-tic-4 Institute im, V. A. Stekloy, Aeadew of Sciences SSSR. rAn (Matemsticheskly institut.Akidemii nauk SSSR LeningradmkoVe Welenlye) Contribftlon to the theory of a Mae gas predueed ly bewd xtat*s of particles SOURCE: Zh eksper I teor riz., v. 50, no. 6, 1966,1550-1558 TOPIC MM: b"on., rersion,, quantum statistics., Green function., thernod7namic I function AB57RACT: 7he purpose of this paper was t obtain an exact solution vithin the limits or low density pf a model prcblem inSjjLg!j~ticle a!Sy,---/consisting of a number of Fermi particles interacting via a paired short-range potential. It is shown that in order for such a system to be of low density it is necessary that the chemical potential be negative., making this system different from similar systems ,"alyzed by quautva-mechanical means. It is shown that such a Fermi system behaves .,like a Bose gas of molecules - bound states - and that at sufficiently law tempera- -`-tiWez the bound pairs can form a Bose condensate. A preliminary calculation is made at at T - 0 using a variational principle based on the Bogolyubov transformation. ~s Is followed by the derivation of expressions for the single-particle Green's ; -density P#actions (normal and anomalous) at T a 0# vhich are accurate in the low 112 Cmd Card 2/2L 'Am  L 33672-66___E'NT(d)/EWT(1) IJP (c WW ACC NRs AP6014074 SOURCE CODE: UR/0294/66/004/002/0261/0266 ,~AUTHOR: Popov, V. N. 1/3 10RG: Moscow Power Institute (Moskovskiy energeticbeaki-y institut) .;5 ~TITLE: Distortion of the temperature field In the region where a !thermocouple Is fixed :30URCE: Teplofizika v-ysokikh temper9tur, v- 4, no. 2, 1966, 261-266 NOPIC TAGS: temperature distribution, beat conductivity ABSTRACT: The article presents an analytical solution of the problem of the distortion of the temperature field in the region where 9 thermocouple is fixed; this distortion is caused by a difference in the beat conductivity of the tbermocouple, or of the material filling the groove for fixing the thermocou.ple, and the beat conductivity of the body whose temperature is being measured. (See Fig. 1). The statement of the problem.is as follows. In a semi-infinite mass with a beat 1conductivityAL (Region II on Figure 1) there is an insertion in the form of an infiAltely long cylinder with radius a (Region I in Figure 1) and a beat conductivity of ?L I. The solution of the problem was carried out under the following boundary conditions: on the outer surface of the mass (y the temperature is constant and is equal Card 113 UDC: 536.532.088  L 33672-66 ACC NR- AP6014074 IC Figure lo Form lotion of the problem and conformal reflections of regions I and II from plane z on ploneL* to t at an infinite distance from Region I the temperature veries linegrly as a function of the coordinate y. that is: at P-6tainip, 9 to +T-(6 - M) 4 + -LO (6 - P sin T) 'at j All. - Ca,d 2/3  POPOV, V.N., kand. tekhn. nauk; GUSYATNIKOV, V.A., inzh. Results of the studies oil the D-130 engine at unsteady load. Trakt. i sellkhozmash. no.7:11-13 Jl 164. (MIRA 18:7) 1. Chelyabinskiy traktornyy zavod (for Popov). 2. Ghelyabinskiy institut mekhanIzatsii i elektrifikatsii sellskogo khozyaystva (fcr Gusyatnikov).  P0.10V V-N- Adams t"-pe Methods for for ordinary differe '~aunhY problem maze. j mat. fiz. r1ti-al equations retardation. 7hur. vych. no-4(supp-l-);135--lL/-8 164. jg.-Z)  10 I MAKAVETSKAS, R.A.;-POPOV, V.N.; TSEDERBERGY N.V. nI,- I Experimental study of the viscosity of mixtures A aitrogen and helium. Teplofiz. vys. tempo 1 no-3:346-355 N-D '63. (MIRA 17:3) 1. 14oskovskiy energeticheskiy institut.