论文信息 - Entropy Generation Rate for a Peristaltic Pump

Entropy Generation Rate for a Peristaltic Pump

Abstract In view of the second law of thermodynamics, the idealized process is usually so selected as to be one of minimum available energy degradation. A measure of departure from this ideal process is the entropy generation rate. In this paper, we shall investigate this aspect concerning an adiabatic peristaltic pump. Our analysis also exhibits the general features of a flow in a contracting tube. It is shown that the dynamics of the system can be reduced to that of a classical Hagen-Poiseuille flow with a source term in the continuity equation and an additional induced force in the momentum equation. In reference to exergy, the analysis reveals that peristaltic pumps generate more entropy than steady walled tubes and are not, from this point of view, competitive devices. The reason for this high-energy degradation is found in the dynamic behavior. The flow rate is not constant along the tube, but increases as sections downstream are reached. This results in high velocity gradients and therefore in strong dynamic irreversibility, which is the prime entropy source of the system. For the classical Hagen–Poiseuille flow, the entropy is mainly generated by heat diffusion.

Nabil Benyahia | Ferhat Souidi | Kheira Ayachi

[1] Lingen Chen,et al. Finite Time Thermodynamic Optimization or Entropy Generation Minimization of Energy Systems , 1999 .

[3] Syeda Humaira Tasnim,et al. Entropy generation in a porous channel with hydromagnetic effect , 2002 .

[4] M. Heil. Stokes flow in an elastic tube—a large-displacement fluid-structure interaction problem , 1998 .

[5] K. Ayukawa,et al. Numerical study of two-dimensional peristaltic flows , 1982, Journal of Fluid Mechanics.

[6] Mohammad T. Khasawneh,et al. Entropy generation due to laminar forced convection in the entrance region of a concentric annulus , 2004 .

[7] Roydon Andrew Fraser,et al. Second law analysis of heat transfer and fluid flow inside a cylindrical annular space , 2002 .

[8] A. Bejan. A Study of Entropy Generation in Fundamental Convective Heat Transfer , 1979 .

[9] Hiroshi Aoki,et al. Unsteady flows in a semi-infinite contracting or expanding pipe , 1977, Journal of Fluid Mechanics.

[10] Fluid-structure interaction in pipe flow , 2007 .

[11] Roydon Andrew Fraser,et al. The second law analysis in fundamental convective heat transfer problems , 2003 .

[12] Roydon Andrew Fraser,et al. Thermodynamic analysis of flow and heat transfer inside channel with two parallel plates , 2002 .