The Woodruff School

SUMMARY

In this investigation, the flow friction associated with laminar pulsating flows through porous media was numerically studied. The problem is of interest for understanding the regenerators of Stirling and pulse tube cryocoolers. Two-dimensional flow in a system composed of a number of unit cells of generic porous structures was simulated using a CFD tool, with sinusoidal variations of flow with time. Detailed numerical data representing the oscillating velocity and pressure variations for five different generic porous structure geometries in the porosity range of 0.64 to 0.84, with flow pulsation frequency of 40Hz were obtained, and special attention was paid to the phase shift characteristics between the velocity and pressure waves. The standard unsteady volume-averaged momentum conservation equation for porous media was then applied in order to obtain cycle-averaged permeability and Forchheimer coefficients. It was found that the cycle-averaged permeability coefficients were nearly the same as those for steady flow, but the cycle-averaged Forchheimer coefficients were about two times higher than those for steady flow.

SUBJECT:	M.S. Thesis Presentation

BY:	Sung Min Kim

TIME:	Monday, January 7, 2008, 2:30 p.m.

PLACE:	Love Building, 109

TITLE:	Numerical Study on Laminar Pulsating Flow through Porous Media

COMMITTEE:	Dr. S. Mostafa Ghiaasiaan, Co-Chair (ME) Dr. S.I. Abdel-Khalik, Co-Chair (ME) Dr. Sheldon M. Jeter (ME)

SUMMARY In this investigation, the flow friction associated with laminar pulsating flows through porous media was numerically studied. The problem is of interest for understanding the regenerators of Stirling and pulse tube cryocoolers. Two-dimensional flow in a system composed of a number of unit cells of generic porous structures was simulated using a CFD tool, with sinusoidal variations of flow with time. Detailed numerical data representing the oscillating velocity and pressure variations for five different generic porous structure geometries in the porosity range of 0.64 to 0.84, with flow pulsation frequency of 40Hz were obtained, and special attention was paid to the phase shift characteristics between the velocity and pressure waves. The standard unsteady volume-averaged momentum conservation equation for porous media was then applied in order to obtain cycle-averaged permeability and Forchheimer coefficients. It was found that the cycle-averaged permeability coefficients were nearly the same as those for steady flow, but the cycle-averaged Forchheimer coefficients were about two times higher than those for steady flow.