Movement and Heat Transfer of Particles in Inhomogeneous and Nonisothermal Rapidly Oscillating Fluid Flow

Igor  Derevich; Olga  Soldatenko

doi:10.4236/jamp.2014.27078

Search Menu Sign in

Journals by Subject

Journals by Title

JAMP Vol.2 No.7 , June 2014

Movement and Heat Transfer of Particles in Inhomogeneous and Nonisothermal Rapidly Oscillating Fluid Flow

Igor Derevich^*, Olga Soldatenko^*

Abstract: Based on the Krylov-Bogolyubov method of averaging the closed system of equations for particle motion and temperature in inhomogeneous rapidly oscillating velocity and temperature of fluid phase is derived. It is shown that the particle movement in a rapidly oscillating fluid velocity field occurs not only under the force of gravity and resistance, but also under force of migration. The migration force is the result of particle inertia and in homogeneity of oscillation of velocity field of the carrier phase. Effects of dynamic and thermal relaxation times of particle and gravity force have been studied. It is shown possibilities of accumulation of particles under the combined action of gravity and migration forces. For a linear dependence of the amplitude of velocity and temperature fluctuations of the fluid an analytical solution was presented. The analytical solutions have been found in good agreement with the results of numerical solution of system of equations of motion and heat transfer of particle.

Keywords: Method of Averaging Krylov-Bogolyubov, Viscouse Resitance, Dynamic and Temperature Relaxation Times, Force of Migration, In Homogenius Turbulence, Velocity and Temperature Oscillations

Cite this paper: Derevich, I. and Soldatenko, O. (2014) Movement and Heat Transfer of Particles in Inhomogeneous and Nonisothermal Rapidly Oscillating Fluid Flow. Journal of Applied Mathematics and Physics, 2, 708-717. doi: 10.4236/jamp.2014.27078.

References

[1] Mednikov, E.P. (1981) Turbulent Transport and Sedimentations of Aerosols. Nauka, Moscow. (in Russian)

[2] Derevich, I.V. (2000) Statistical Modeling of Mass Transfer in Turbulent Two-Phase Dispersed Flows—1. Model Development. International Journal of Heat and Mass Transfer, 42, 3709-3723.
http://dx.doi.org/10.1016/S0017-9310(00)00038-7

[3] Zaichik, L.I. and Alipchenkov, V.M. (2007) Statistical Models of Particles Turbulent Motion in Fluids. Fizmatlit, Moscow. (in Russian)

[4] Terekhov, V.I. and Pakhomov, M.A. (2008) Flow Dynamics and Heat and Mass Transfer in a Gas-Droplets Flow. NGTU, Novosibirsk.

[5] Krylov, N.M. and Bogolyubov, N.N. (1947) Introduction to Nonlinear Mechanics. Princeton University Press, Princeton. (Translated from Russian)

[6] Verhulst, F. (1993) Nonlinear Deferential Equations and Dynamical Systems. Springer-Verlag, New York, Heidelberg, Berlin.

[7] Dubinov, A. (2011) Ponderomotive Transport of Charged Granule in Plasma. Technical Physics Letters, 37, 59-61.
http://dx.doi.org/10.1134/S1063785011020052