Heat transfer and pressure results of an inline array of round jets impinging on a staggered array of dimples are reported with the consideration of various geometric and parametric effects; results are normalized against flat plate data. The heat transfer was measured by using transient wideband liquid crystal method. The geometrical configurations considered were crossflow (or spent-air exit) scheme, dimple geometries, and impinging positions. Three crossflow schemes were tested such as one-way, two-way, and free exits. These led to the idea of the coupling effects of impingement and channel flow depending on which one dominated. Hemispherical and cusped elliptical dimple shapes with the same wetted area were considered and found that both dimples showed the similarity in heat transfer results. Impinging positions on dimples and on flat portions adjacent to dimples were examined. Throughout the study, the pitch of the nozzle holes was kept constant at four jet diameters. The investigated parameters were Reynolds number ranged from 5000 to 11,500, jet-to-plate spacing varied from 1 to 12 jet diameters, dimple depths of 0.15, 0.25, and 0.29, and dimple curvature of 0.25, 0.50, and 1.15. The shallow dimples improved heat transfer significantly by 70% at compared to that of the flat surface, while this value was 30% for the deep ones . The improvement also occurred to the moderate and high . The total pressure was a function of and when , but it was independent of the target plate geometry. The levels of the total pressure loss of the dimpled plates werenot different from those of the flat surface under the same setup conditions. Wall static pressure was measured by using static taps located across each plate. and affected the level of the static pressure while the dimple depth influenced the stagnation peaks, and the crossflow scheme affected the shape of the peaks.
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e-mail: koonlaya@gmail.com
e-mail: rmbotas@imperial.ac.uk
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January 2008
Research Papers
Heat Transfer and Pressure Investigation of Dimple Impingement
K. Kanokjaruvijit,
K. Kanokjaruvijit
Department of Mechanical Engineering,
e-mail: koonlaya@gmail.com
Naresuan University
, Muang, Pitsanulok, 65000 Thailand
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R. F. Martinez-Botas
R. F. Martinez-Botas
Department of Mechanical Engineering,
e-mail: rmbotas@imperial.ac.uk
Imperial College London
, London, UK
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K. Kanokjaruvijit
Department of Mechanical Engineering,
Naresuan University
, Muang, Pitsanulok, 65000 Thailande-mail: koonlaya@gmail.com
R. F. Martinez-Botas
Department of Mechanical Engineering,
Imperial College London
, London, UKe-mail: rmbotas@imperial.ac.uk
J. Turbomach. Jan 2008, 130(1): 011003 (11 pages)
Published Online: December 14, 2007
Article history
Received:
October 1, 2004
Revised:
February 1, 2005
Published:
December 14, 2007
Citation
Kanokjaruvijit, K., and Martinez-Botas, R. F. (December 14, 2007). "Heat Transfer and Pressure Investigation of Dimple Impingement." ASME. J. Turbomach. January 2008; 130(1): 011003. https://doi.org/10.1115/1.2220048
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