Cryogenic and high-temperature systems often require compact heat exchangers with a high resistance to axial conduction in order to control the heat transfer induced by axial temperature differences. One attractive design for such applications is a perforated plate heat exchanger that utilizes high conductivity perforated plates to provide the stream-to-stream heat transfer and low conductivity spacers to prevent axial conduction between the perforated plates. This paper presents a numerical model of a perforated plate heat exchanger that accounts for axial conduction, external parasitic heat loads, variable fluid and material properties, and conduction to and from the ends of the heat exchanger. The numerical model is validated by experimentally testing several perforated plate heat exchangers that are fabricated using microelectromechanical systems based manufacturing methods. This type of heat exchanger was investigated for potential use in a cryosurgical probe. One of these heat exchangers included perforated plates with integrated platinum resistance thermometers. These plates provided in situ measurements of the internal temperature distribution in addition to the temperature, pressure, and flow rate measured at the inlet and exit ports of the device. The platinum wires were deposited between the fluid passages on the perforated plate and are used to measure the temperature at the interface between the wall material and the flowing fluid. The experimental testing demonstrates the ability of the numerical model to accurately predict both the overall performance and the internal temperature distribution of perforated plate heat exchangers over a range of geometry and operating conditions. The parameters that were varied include the axial length, temperature range, mass flow rate, and working fluid.
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November 2010
This article was originally published in
Journal of Heat Transfer
Research Papers
An Experimentally Validated Numerical Modeling Technique for Perforated Plate Heat Exchangers
M. J. White,
M. J. White
Accelerator Division/Cryogenic Systems,
Fermi National Accelerator Laboratory
, Batavia, IL 60510
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G. F. Nellis,
G. F. Nellis
Department of Mechanical Engineering,
University of Wisconsin-Madison
, Madison, WI 53703
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S. A. Klein,
S. A. Klein
Department of Mechanical Engineering,
University of Wisconsin-Madison
, Madison, WI 53703
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W. Zhu,
W. Zhu
Department of Mechanical Engineering,
University of Michigan-Ann Arbor
, Ann Arbor, MI 48109
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Y. Gianchandani
Y. Gianchandani
Department of Mechanical Engineering,
University of Michigan-Ann Arbor
, Ann Arbor, MI 48109
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M. J. White
Accelerator Division/Cryogenic Systems,
Fermi National Accelerator Laboratory
, Batavia, IL 60510
G. F. Nellis
Department of Mechanical Engineering,
University of Wisconsin-Madison
, Madison, WI 53703
S. A. Klein
Department of Mechanical Engineering,
University of Wisconsin-Madison
, Madison, WI 53703
W. Zhu
Department of Mechanical Engineering,
University of Michigan-Ann Arbor
, Ann Arbor, MI 48109
Y. Gianchandani
Department of Mechanical Engineering,
University of Michigan-Ann Arbor
, Ann Arbor, MI 48109J. Heat Transfer. Nov 2010, 132(11): 111801 (9 pages)
Published Online: August 10, 2010
Article history
Received:
February 4, 2009
Revised:
October 1, 2009
Online:
August 10, 2010
Published:
August 10, 2010
Citation
White, M. J., Nellis, G. F., Klein, S. A., Zhu, W., and Gianchandani, Y. (August 10, 2010). "An Experimentally Validated Numerical Modeling Technique for Perforated Plate Heat Exchangers." ASME. J. Heat Transfer. November 2010; 132(11): 111801. https://doi.org/10.1115/1.4000673
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