Jet impingement cooling is widely used due to the very high heat transfer coefficients that are attainable. Both single and multiple jet systems can be used, however, multiple jet systems offer higher and more uniform heat transfer. A staggered array of 8.46 mm diameter impingement jets with jet-to-jet spacing of 2.34 D was examined where the spent fluid is extracted through one of six 7.36 mm diameter extraction holes regularly located around each jet. The array had an extraction area ratio of 2.23 locally and was tested with a jet-to-target spacing of 1.18 jet diameters. Magnetic resonance velocimetry was used to both quantify and visualize the three dimensional flow field inside the cooling cavity at jet Reynolds numbers of 2600 and 5300. The spatially averaged velocity measurements showed a smooth transition is possible from the impingement jet to the extraction hole without the presence of large vortical structures. Mean Nusselt number measurements were made over a jet Reynolds number range of 2000–10,000. Nusselt numbers near 75 were measured at the highest Reynolds number with an estimated uncertainty of 7%. Large mass flow rate per unit heat transfer area ratios were required because of the small jet-to-jet spacing.
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Full-Field Flow Measurements and Heat Transfer of a Compact Jet Impingement Array With Local Extraction of Spent Fluid
Andrew J. Onstad,
Andrew J. Onstad
Department of Mechanical Engineering,
e-mail: aonstad@stanford.edu
Stanford University
, Stanford, CA 94305
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Christopher J. Elkins,
Christopher J. Elkins
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305
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Robert J. Moffat,
Robert J. Moffat
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305
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John K. Eaton
John K. Eaton
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305
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Andrew J. Onstad
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305e-mail: aonstad@stanford.edu
Christopher J. Elkins
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305
Robert J. Moffat
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305
John K. Eaton
Department of Mechanical Engineering,
Stanford University
, Stanford, CA 94305J. Heat Transfer. Aug 2009, 131(8): 082201 (8 pages)
Published Online: June 4, 2009
Article history
Received:
August 18, 2008
Revised:
February 18, 2009
Published:
June 4, 2009
Citation
Onstad, A. J., Elkins, C. J., Moffat, R. J., and Eaton, J. K. (June 4, 2009). "Full-Field Flow Measurements and Heat Transfer of a Compact Jet Impingement Array With Local Extraction of Spent Fluid." ASME. J. Heat Transfer. August 2009; 131(8): 082201. https://doi.org/10.1115/1.3109991
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