Optimization of pin-fin heat sinks for impingement cooling of electronic components was studied. The study was based on a semi-empirical zonal model for determining thermal resistance as well as pressure drop. To test the validity of the model’s predictions, experiments and flow visualization were performed. The experimental results validated the model. The model enables cost-effective designs to be calculated in order to optimize pin-fin heat sinks. These calculations took into consideration 16 design parameters including pin diameter, minimum spacing between pins, and fin height. For the particular blower considered in our study, the optimum pin diameter was found being 0.35 mm. And the characteristics and limitations of air-cooling for such applications were investigated under various conditions. [S1043-7398(00)01704-7]

Issue Section:
Technical Papers
Keywords:
heat sinks, integrated circuit packaging, cooling, thermal resistance, flow visualisation, integrated circuit modelling
Topics:
Cooling, Heat sinks, Optimization, Pins (Engineering), Pressure drop, Thermal resistance, Impingement cooling, Flow (Dynamics), Fins, Flow visualization
1.
Nakayama
,
W.
,
1995
, “
Heat-Transfer Engineering in Systems Integration: Outlook for Closer Coupling of Thermal and Electrical Designs of Computers
,”
IEEE Trans. Compon., Packag. Manuf. Technol., Part A
,
18
, No.
8
, pp.
818
826
.
2.
Mahalingham, M., and Andrew, J., 1987, “High-Performance Air Cooling for Microelectronics,” Proceeding of the International Symposium on Cooling Technology for Electronic Equipment, Honolulu, HI, Mar. 17–21, pp. 608–625.
3.
Sathe, S. B., Kelkar, K. M., Karki, K. C., Tai, C., Lamb, C., and Patankar, S. V., 1993, “Numerical Prediction of Flow and Heat Transfer in an Impingement Heat Sink,” ASME, EEP-Vol. 4-2, Advances in Electronic Packaging, pp. 893–898.
4.
Boesmans, B., Christiaens, F., Berghmans, J., and Beyne, E., 1994, “Design of an Optimal Heat-Sink Geometry for Forced Convection Air Cooling of Multi-Chip Modules,” Thermal Management of Electronic Systems, Hoogendoorn, C. J., ed., Kluwer Academic, pp. 267–276.
5.
Ledezma
,
G.
,
Morega
,
A. M.
, and
Bejan
,
A.
,
1996
, “
Optimal Spacing Between Pin Fins with Impinging flow
,”
ASME J. Heat Transfer
,
118
, pp.
570
577
.
6.
Kondo
,
Y.
,
Behnia
,
M.
,
Nakayama
,
W.
, and
Matsushima
,
H.
,
1998
, “
Optimization of Finned Heat Sinks for Impingement Cooling of Electronic Packages
,”
ASME J. Electron. Packag.
,
120
, No.
3
, pp.
259
266
.
7.
Eckert, E. R. G., and Drake, R. M., 1979, Heat and Mass Transfer, McGraw-Hill, NY, pp. 167–254.
8.
Kays
,
W. M.
,
1995
, “
Numerical Solutions for Laminar-Flow Heat Transfer in Circular Tubes
,”
ASME J. Appl. Mech.
,
77
, pp.
1265
1274
.
9.
McAdams, W. H., 1954, Heat Transmission, 3rd ed., McGraw-Hill, NY, p. 226.
10.
Zukauskas, A., 1987, Convective Heat Transfer in Cross Flow. Handbook of Single-Phase Convective Heat Transfer, Kakac, S., Shah, R. K., and Aung, W., eds., Wiley, NY, pp. 6–31.
11.
Teuscher, K. L., Ramadhyami, S., and Incropera, F. P., 1993, “Jet Impingement Cooling of An Array of Discrete Heat Sources with Extended Surfaces,” ASME, HTD-Vol. 263, Enhanced Cooling Techniques for Electronics Applications, pp. 1–10.
12.
Holman, J. P., 1976, Heat Transfer, McGraw-Hill, NY, pp. 13–14 and pp. 38–41.
13.
Weisbach
,
J.
,
1896
,
Ingenieur und Mashinen-Mechnik
,
1
, p.
1003
1003
.
14.
Kays, W. M., and London, A. L., 1955, Compact Heat Exchangers, McGraw-Hill, NY, p. 93.
15.
Chapman, A. J., 1987, Fundamentals of Heat Transfer, MacMillan, NY, p. 261.
16.
Blasius, H., 1913, “Forsch. Geb. Ingenieurwes,” No. 131.
17.
Jakob
,
M.
,
1938
, “
Heat Transfer and Flow Resistance in Cross Flow of Gases over Tube Bank
,”
Trans. ASME
,
60
, p.
384
384
.
18.
Stoecker, W. F., 1971, Design of Thermal Systems, McGraw-Hill, NY, pp. 135–159.
19.
Sathe, S. B., Sammakia, B. G., Wong, A. C., and Mahaney, H. V., 1995, “A Numerical Study of A High-Performance Air-Cooled Impingement Heat Sink,” ASME, HTD-Vol. 303, National Heat Transfer Conference—Volume 1, pp. 43–53.
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