SCIENTIFIC ABSTRACT GRIDINA, Z.P. - GRIDNEV, V.N.

L 07466-67 _4& NR, AT60345,'4 Of) smaller or greater than the wake flow uO. The length of the initial section is then calculated to be . I A I + A2ttr + A3M2 .L,-O = -4- 2ad(al-aOM+02 I (I - M)2 where A is 'a coefficient determined from the velocity profile I - 6YI02 + 8ilo' -7 3T)o, 2 2 166 48 -~a, a a3=F 7 7 a4z= 35 In the main flow, the same length parameter takea the form a4 M2 which for m - 0 simplifies to + !!ZL' X-0)]2 UO a3 similar analysis is made for the axisymmetric jet. The results are shown graphicaA as plots of velocity profiles in the jet and mixing boundaries along the jet axis. The analysis is then extended to a converging or diverging radial slot Jet issuing from a nozzle with thickness 280 and diameter 2x . (see Fig. 1). The governing inte- gral relation for this case is given by d .~-Luh-'-L"-dy. (k.0.1 2, .dX X ~ Ul,+2dy A!(k+l)x Q dy 0 Card 2A  L 07W AT603455A Converging jet Diverging jet X '91 W Fig. 1. Ix Once more the solutions are given for the initial and main parts of the flow, and the results are presented graphically. This analysis is shown to be directly related to the plane flow case with m - 0 through a Mangler-Stepanov transformation. A plot of um)ru0versus x shows excellent agreement with experiments. The above analyses are then compared to a similar integral method of L. G. LoytByartakiy where the governing equations are it t1(u-its)dy~O, dx 0 d ~U(U -uj)ydy-~v(n-u&)dy=v,(u,- it,)' dx t - .-0 The two approximfite methods are then compared to the exact solution Vith the Card 3A  L 07466-67 Act -N--R-s AT60345IF4 result; K2 I at aim us K Im. 0., (VXUI iFv 11 at j a Golubev expression 0.442 0.286 Loytsyanskiy expression 0-434 0.280 Exact solution 0.454 0.282 A brief discussion is given showing how to extend"the above integral methods to a turbulent jet which is nonisothermal, compressible, and has variable properties. Calculations of the above formulas were carried out by T. P. Kondakova and V. M. Arbekdva. Orig. art. has: 110 equations, 12 figures, and 2 tables. SUB CODE: 20/ SUBM DATE: none/ ORIG REP: 008/ OTH REP: 004 / ATD PRESS: 5104 V 4  m.) A7;U6Lb345 5 5 A T 12 A,~ I AbTHOR: Cinevokiy, A. S. (Candidate of technical sciences) ORG: none TITL7,: Turbulent noniaothermal jots of comproijoiblo gaa with variable composition SURCE: Moscow. Tnontral'W acro-gridrodinamichookiy inatitut. Prorvahlennaya acrodinamika, no-. '27, 1966. Struynyye tacho'niya'(Jet atre-ama), 31-54, TOPR; TAGS: LiLrbulont flow, compressible floa, Gnio jot, temperature distribution, u7aa diffusion, boundary layer i'LBSTRAC70.A compressible, variable -compoci t i on turbulent analyzed using the intcjral method. The analysis ic divided into six parto with tho-followinr, assump- tions holding throughout: the flow is isobaric; the specific beat of each component in the jet is independent of the temperature; pressure and thernal diffusion are neL-,Iected; the density is determined from the Clapoyron equation; and there are no chemical reactions. Part one trouts the plane noniaotheriLal jet in a walco with Prt - Prd - 1 at high velocities. The governinG boundary layer equations consist. of species and overall continuity equationof the momentiu7i equation, and the erLcrV epation. Uaing integral rolationa) tho following equation is obtained for tho flaw along the jet axis Card -1 3.601.17.001.2632-517.4  L 05" ~1-o'?__ ACC "" AT6034555 0 I -ni C,& D 2~O (tt" d -------- T FX 110 MY.P (0). Ito UO in part two, the same problem ic analyzed for the axiayuunetrip jot where the viscous stress is expressed by the polynomial, -(T/Y)Y-ol I'llO - 0', which, upon cubutiLution into tho govofnina equation quid integration, yioldo flI) Cr ]112 X-xo= ',~,M L-n - ni 24-x 2DC,O (00 UO ~---O Part three is the same as part one and two codoined, except that the flow velocity is assumed to be very low. The results of the analysis are shown as velocity profile cu--ves for various radial temperature distributions. In parts four through six the conditions Pr (turbulent and diffusional) equal unity are relaxed, and the viscous stress and thermal conductivity are expressed repectively-by 2 my( O=QOI11nIhM'Y 1-7 V"-) -i.t. - - - . ( . - - T For cp const and small flow V010C ieeg the following expressions are obtained for Card 2/3  -r AC~ AT6034555 the velocity and temperature diotributione -M b, -=- + dil .1 2 T--M AIIM ~")Mlldqr r M b, -+b3 I -M All, T, 0Pr-I Fit 5 P'Irl - I 10 Pf" 2-8 P(l + 105160 Por a submerged jet, these results agree very well with experimental values for Pr -= 0-5. The corresponding concentration profile ia given by t -f PA12 7 d .4z A11M -~. p,2 8' Pld + 7L Ply 2_ 1 5 d 35 7 35 i which also agrees with experimental-measuremente if Pr d0-5- Orig. art. haas 135 equations, 8 figuresp and 1,table. SUB CODE: 20/ SUBM UTE: none/ ORIG REF. 008 / ATD PRESS: 5103 Card 3/3 1s  I. OM67-67 EWP(M)IEWT(l) FDN,4&7/51/~4E- ACC NR' AT6034556 SOURCE CODE: Ult/2632/66/000/027/005 AUTHOR: Ginevskiy, A. S. (Candidate of technical sciences) ORG: none TITLE: Calculation of transverse velocities in the initial and main portions of turbulent jets in wake flow SOURCE: Moscow. Teentrallnyy aero-gidrodinamicheskiy institut. Promyshlennaya aerodinamika, no. 27, 1966. Struynyye techeniya (Jet streams), 55-70 TOPIC TAGS: wake flow, jet flow, plane flow, axisymmetric flow, turbulent flow, turbulent jet ABSTRACT: Formulas are derived for the construction of the transverse velocity profiles for both the main and the initial portions of jets in wake flow. The .10 r rmulas are derived on the basis of two approximation methods. The first uses boundary layer equations, and the second uses the fiuid continuity equation with the condition of momentum conservation in transverse cross sections of the jet. The degree 6f approximation of both methods depends on the approximation expression for the longitudinal velocity profile used as the initial condition. Using the boundary layer equations, the transverse velocity profile of the main portion of a plane jet given by i V t--=F[ T , 12iL u)m T. Aom. Card 1/3 UDC: 532-522.001.2,  L 07467-67 ACC NR: AT6034556 X'~ (1 39) 0 - To dq~ [ -J- + (I + 3q) _,1)3]2 I M au, 0 where .11 it, -t- Ulf (11), 6il" 893 - 31,4= (I + 31l) (I - 9p. Y Us M I Up, - U, UO Ulm M AUM _ U& U8 V/ UO and v is the virtual viscosity coefficient. The upperand lower siga3correspond to t .m>1 and m