Computational modeling of a segmented-involute-foil regenerator for stirling engines

Mounir B. Ibrahim; Daniel Danila; Terrence W. Simon; David Gedeon; Roy Tew

doi:10.2514/1.40330

Computational modeling of a segmented-involute-foil regenerator for stirling engines

Mounir B. Ibrahim, Daniel Danila, Terrence W. Simon, David Gedeon, Roy Tew

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

A microfabricated, segmented-involute-foil regenerator was numerically investigated using the Fluent commercial software under both steady- and oscillatory-flow conditions and using two- and three-dimensional numerical simulations. Steady-state simulations were performed for Re = 50-2000. The oscillatory-flow conditions were performed for Re_max = 50 and Re _ω = 0:229, with the hot end at 310 K and the cold end at 293 K. For the steady-state three-dimensional simulation, both the local friction factor and the local mean Nusselt numbers started to depart from the two-dimensional simulation values upon entering the second layer. At the entrance of every layer, the forced reorientation of the flow results in small rises of both the friction factor and the mean Nusselt number, with subsequent decrease as the flow settles into the new layer. As for the oscillatory-flow simulations, the two-dimensional model was used to study the effects of changing 1) the oscillation amplitude and frequency, 2) the thermal contact resistance between layers, and 3) the solid material. The effects of these parameters on the total regenerator heat loss (convection and conduction) were documented and are expected to be a useful tool for further development of Stirling engine regenerators.

Original language	English (US)
Pages (from-to)	786-800
Number of pages	15
Journal	Journal of thermophysics and heat transfer
Volume	23
Issue number	4
DOIs	https://doi.org/10.2514/1.40330
State	Published - 2009

Bibliographical note

Funding Information:
We are grateful for sponsorship of this effort by the NASA Headquarters Science Mission Directorate and the Radioisotope Power System Program and for the support of the NASA Glenn Research Center at Lewis Field under NASA Contract NAS3-03124, for which the Contracting Officer’s Technical Representative was Roy Tew. We wish to acknowledge the valuable guidance we received from our team of advisors: James Cairelli (retired) and Randy Bowman, both of NASA Glenn Research Center at Lewis Field, and David Berchowitz at Global Cooling, Inc.

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abstract = "A microfabricated, segmented-involute-foil regenerator was numerically investigated using the Fluent commercial software under both steady- and oscillatory-flow conditions and using two- and three-dimensional numerical simulations. Steady-state simulations were performed for Re = 50-2000. The oscillatory-flow conditions were performed for Remax = 50 and Re ω = 0:229, with the hot end at 310 K and the cold end at 293 K. For the steady-state three-dimensional simulation, both the local friction factor and the local mean Nusselt numbers started to depart from the two-dimensional simulation values upon entering the second layer. At the entrance of every layer, the forced reorientation of the flow results in small rises of both the friction factor and the mean Nusselt number, with subsequent decrease as the flow settles into the new layer. As for the oscillatory-flow simulations, the two-dimensional model was used to study the effects of changing 1) the oscillation amplitude and frequency, 2) the thermal contact resistance between layers, and 3) the solid material. The effects of these parameters on the total regenerator heat loss (convection and conduction) were documented and are expected to be a useful tool for further development of Stirling engine regenerators.",

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Computational modeling of a segmented-involute-foil regenerator for stirling engines

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