THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS

Applied Mathematics and Mechanics (English Edition) ›› 1986, Vol. 7 ›› Issue (9): 835-840.

THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS

蔡树棠¹, 吴烽²

1. Department of Modern Mechanics, University of Science and Technology of China, Hefei Shanghai Institute of Applied Mathematics and Mechanics, Shanghai;
2. Department of Modern Mechanics University of Science and Technology of China, Hefei

出版日期:1986-09-18 发布日期:1986-09-18

THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS

Tsai Shu-tang¹, Wu Feng²

1. Department of Modern Mechanics, University of Science and Technology of China, Hefei Shanghai Institute of Applied Mathematics and Mechanics, Shanghai;
2. Department of Modern Mechanics University of Science and Technology of China, Hefei

Online:1986-09-18 Published:1986-09-18

摘要/Abstract

摘要： In many studies on two-dimensional flows in field of atmosphere and ocean the equations which are extension of river-hydraulic equations ∂/∂tU_α+U_β∂U_α/∂X_β=-g∂h/∂X_α+g(i_α-|U|U_α/c²R)+F_α or Navier-Stokes equations ∂/∂tU_α+U_β∂U_α/∂X_β=-g∂h/∂X_α+gi_α+F_α+∂/∂X_β(v_t ∂U_α/∂X_β) are usually used. In these equations -g|U|U_α/c²R or ∂/∂X_β(v_t ∂U_α/∂X_β) stand for turbulent resistance. Obviously use of these equations in practice may lead to contradiction. In this paper the average of Reynolds equations over depth is taken. The motion equations, continuity equation and diffusion equation are obtained for the average physical variables.

关键词: viscous interaction, invariance, wortex field, Lagrangian density, turbulence

Abstract: In many studies on two-dimensional flows in field of atmosphere and ocean the equations which are extension of river-hydraulic equations ∂/∂tU_α+U_β∂U_α/∂X_β=-g∂h/∂X_α+g(i_α-|U|U_α/c²R)+F_α or Navier-Stokes equations ∂/∂tU_α+U_β∂U_α/∂X_β=-g∂h/∂X_α+gi_α+F_α+∂/∂X_β(v_t ∂U_α/∂X_β) are usually used. In these equations -g|U|U_α/c²R or ∂/∂X_β(v_t ∂U_α/∂X_β) stand for turbulent resistance. Obviously use of these equations in practice may lead to contradiction. In this paper the average of Reynolds equations over depth is taken. The motion equations, continuity equation and diffusion equation are obtained for the average physical variables.

Key words: viscous interaction, invariance, wortex field, Lagrangian density, turbulence

蔡树棠;吴烽. THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS[J]. Applied Mathematics and Mechanics (English Edition), 1986, 7(9): 835-840.

Tsai Shu-tang;Wu Feng. THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS[J]. Applied Mathematics and Mechanics (English Edition), 1986, 7(9): 835-840.

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THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS

THE FUNDAMENTAL EQUATIONS OF TWO-DIMENSIONAL LAYER FLOWS

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