Abstract

An experimental study was conducted to investigate the heat transfer from a parallel flat plate heat sink under a turbulent impinging air jet. A horizontal nozzle plate confined the target surface. The jet was discharged from a sharp-edged nozzle in the nozzle plate. Average Nusselt numbers are reported for Pr=0.7, 5000Re30,000, Ld=2.5, and 0.833 at Hd=3 where L, H, and d define the length of the square heat source, nozzle-to-target spacing, and nozzle diameter, respectively. Tests were also conducted for an impinging flow over a flat plate, flush with the top surface of the target plate. The average Nusselt numbers from the heat sink were compared to those for a flat plate to determine the overall performance of the heat sink in a confined impingement arrangement. The experimental results were compared with the numerical predictions obtained in an earlier study. Although the average Nusselt numbers obtained from numerical simulations differed from the experimental measurements by 18%, the disagreement is much less significant when related to the junction temperature. Under typical conditions, it was shown that such discrepancy in the Nusselt number lead to an error of 6% in the prediction of the junction temperature of the device.

1.
Martin
,
H.
, 1977, “
Heat and Mass Transfer between Impinging Gas Jets and Solid Surfaces
,”
Adv. Heat Transfer
0065-2717,
13
, pp.
1
60
.
2.
Hrycak
,
P.
, 1984, “
Heat Transfer from Impinging Jets to a Flat Plate With Conical and Ring Protuberances
,”
Int. J. Heat Mass Transfer
0017-9310,
27
, pp.
2145
2154
.
3.
Hansen
,
L. G.
, and
Webb
,
B. W.
, 1993, “
Air Jet Impingement Heat Transfer from Modified Surfaces
,”
Int. J. Heat Mass Transfer
0017-9310,
36
, pp.
989
997
.
4.
Brignoni
,
L. A.
, and
Garimella
,
S. V.
, 1999, “
Experimental Optimization of Confined Air Jet Impingement on a Pin Fin Heat Sink
,”
IEEE Trans. Compon. Packag. Technol.
1521-3331,
22
, pp.
399
404
.
5.
El-Sheikh
,
H. A.
, and
Garimella
,
S. V.
, 2000, “
Enhancement of Air Jet Impingement Heat Transfer Using Pin-Fin Heat Sinks
,”
IEEE Trans. Compon. Packag. Technol.
1521-3331,
23
, pp.
300
308
.
6.
Issa
,
J. S.
, and
Ortega
,
A.
, 2002, “
Experimental Measurements of the Flow and Heat Transfer of a Square Jet Impinging on an Array of Square Pin Fin
,”
Proc., ASME Heat Transfer Division
,
New Orleans
, November 17–22, Vol.
2
, pp.
179
193
.
7.
Jung
,
H. H.
, and
Maveety
,
J. G.
, 2000, “
Pin-Fin Heat Sink Modeling and Characterization
,”
Proc., 16th IEEE Semiconductor Thermal Measurement and Management (SEMI-THERM) Symposium
, San Jose, CA, March 21–23, pp.
260
265
.
8.
Sansoucy
,
E.
,
Oosthuizen
,
P. H.
, and
Refai-Ahmed
,
G.
, 2003, “
Enhancement of Air-Cooling Limits for Telecom Heat Sink Applications Using Impinging Air Jets
,”
Proc., ASME Heat Transfer Division
, Washington, DC, November 15–21, Vol.
2
, pp.
307
315
.
9.
Sansoucy
,
E.
, 2003, “
Experimental and Numerical Investigation of the Effects of an Impinging Air Jet on the Heat Transfer Rate from a Parallel Flat Plate Heat Sink
,” M.S. thesis, Department of Mechanical Engineering, Queen's University.
10.
Kraus
,
A. D.
, and
Bar-Cohen
,
A.
, 1983,
Thermal Analysis and Control of Electronic Equipment
, 1st ed.,
McGraw-Hill Book Company
, New York.
11.
Craft
,
T. J.
,
Graham
,
L. J. W.
, and
Launder
,
B. E.
, 1993, “
Impinging Jet Studies for Turbulence Model Assessment – II: An Examination of the Performance of Four Turbulence Model
,”
Int. J. Heat Mass Transfer
0017-9310,
36
, pp.
2685
2697
.
12.
Polat
,
S.
,
Huang
,
B.
,
Mujumbar
,
A. S.
, and
Douglas
,
W. J. M.
, 1989, “
Numerical Flow and Heat Transfer Under Impinging Jets: A Review
,”
Drying Technol.
0737-3937,
3
, pp.
15
38
.
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