The necessity for an efficient thermal management system covering large areas is growing rapidly with the push toward more electric systems. A significant amount of research over the past 2 decades has conclusively proved the suitability of jet, droplet, or spray impingement for high heat flux cooling. However, all these research consider small heat source areas, typically about a few cm2. Can a large array of impingement pattern, covering a much wider area, achieve similar heat flux levels? This article presents liquid microjet array impingement cooling of a heat source that is about two orders of magnitude larger than studied in the previous works. Experiments are carried out with 441 jets of de-ionized water and a dielectric liquid HFE7200, each 200μm diameter. The jets impinge on a 189cm2 area surface, in free surface and confined jet configurations. The average heat transfer coefficient values of the present experiment are compared with correlations from the literature. While some correlations show excellent agreement, others deviate significantly. The ensuing discussion suggests that the post-impingement liquid dynamics, particularly the collision between the liquid fronts on the surface created from surrounding jets, is the most important criterion dictating the average heat transfer coefficient. Thus, similar thermal performance can be achieved, irrespective of the length scale, as long as the flow dynamics are similar. These results prove the scalability of the liquid microjet array impingement technique for cooling a few cm2 area to a few hundred cm2 area.

1.
Lienhard V
,
J.
, 1995, “
Liquid Jet Impingement
,”
Annu. Rev. Heat Transfer
1049-0787,
6
, pp.
199
270
.
2.
Incropera
,
F. P.
, 1999,
Liquid Cooling of Electronic Devices by Single Phase Convection
,
Wiley
,
New York
.
3.
Webb
,
B. W.
, and
Ma
,
C. F.
, 1995, “
Single-Phase Liquid Jet Impingement Heat Transfer
,”
Adv. Heat Transfer
0065-2717,
26
, pp
105
217
.
4.
Robinson
,
A. J.
, and
Schnitzler
,
E.
, 2007, “
An Experimental Investigation of Free and Submerged Miniature Liquid Jet Array Impingement Heat Transfer
,”
Exp. Therm. Fluid Sci.
0894-1777,
32
, pp.
1
13
.
5.
Fabbri
,
M.
, and
Dhir
,
V. K.
, 2005, “
Optimized Heat Transfer for High Power Electronic Cooling Using Arrays of Microjets
,”
ASME J. Heat Transfer
0022-1481,
127
, pp.
760
769
.
6.
Lee
,
D. Y.
, and
Vafai
,
K.
, 1999, “
Comparative Analysis of Jet Impingement and Micro-Channel Cooling of High Heat Flux Applications
,”
Int. J. Heat Mass Transfer
0017-9310,
42
, pp.
1555
1568
.
7.
Pan
,
Y.
, and
Webb
,
B. W.
, 1995, “
Heat Transfer Characteristics of Arrays of Free Surface Liquid Jets
,”
ASME J. Heat Transfer
0022-1481,
117
, pp.
878
883
.
8.
Womac
,
D. J.
,
Incropera
,
F. P.
, and
Ramadhyani
,
S.
, 1994, “
Correlating Equations for Impingement Cooling of Small Heat Sources With Multiple Circular Liquid Jets
,”
ASME J. Heat Transfer
0022-1481,
116
, pp.
482
486
.
9.
Jiji
,
L. J.
, and
Dagan
,
Z.
, 1987, “
Experimental Investigation of Single-Phase Multijet Impingement Cooling of an Array of Microelectronic Heat Sources
,”
Proceedings of the International Symposium on Cooling Technology for Electronic Equipment
,
W.
Aung
, ed.,
Hemisphere
,
Washington, DC
, pp.
333
351
.
10.
Yonehara
,
N.
, and
Ito
,
I.
, 1982, “
Cooling Characteristics of Impinging Multiple Water Jets on a Horizontal Plane
,”
Technol. Rep. Kyushu Univ.
0023-2718,
24
, pp.
267
281
.
11.
Garrett
,
K.
, and
Webb
,
B. W.
, 1999, “
The Effect of Drainage Configuration on Heat Transfer Under an Impinging Liquid Jet Array
,”
ASME J. Heat Transfer
0022-1481,
121
, pp.
803
810
.
12.
Lin
,
L.
,
Ponnappan
,
R.
,
Yerkes
,
K.
, and
Hager
,
B.
, 2004, “
Large Area Spray Cooling
,”
42nd AIAA Aerospace Sciences Meeting and Exhibit
, Reno, NV, AIAA Paper No. 2004-1340.
13.
Liu
,
X.
, and
Lienhard V
,
J. H.
, 1989, “
Liquid Jet Impingement Heat Transfer on a Uniform Flux Surface
,”
Heat Transfer Phenomena in Radiation, Combustion and Fires
,
ASME
,
New York
, Vol.
106
, pp.
523
530
.
14.
Bhunia
,
S. K.
, and
Lienhard V
,
J. H.
, 1994, “
Splattering During Turbulent Liquid Jet Impingement on Solid Targets
,”
ASME J. Fluids Eng.
0098-2202,
116
, pp.
338
344
.
15.
Kate
,
R. P.
,
Das
,
P. K.
, and
Chakraborty
,
S.
, 2007, “
An Experimental Investigation on the Interaction of Hydraulic Jumps Formed by Two Normal Impinging Circular Liquid Jets
,”
J. Fluid Mech.
0022-1120,
590
, pp.
355
380
.
16.
Ruch
,
M. A.
, and
Holman
,
J. P.
, 1975, “
Boiling Heat Transfer to a Water Jet Impinging Upward Onto a Flat, Heated Surface
,”
Int. J. Heat Mass Transfer
0017-9310,
18
, pp.
51
60
.
17.
Monde
,
M.
, and
Katto
,
Y.
, 1978, “
Burnout in a High Heat Flux Boiling System With an Impinging Jet
,”
Int. J. Heat Mass Transfer
0017-9310,
21
, pp.
295
305
.
18.
Blevins
,
R. D.
, 1992,
Applied Fluid Dynamics Handbook
,
Kreiger
,
Malabar, FL
.
19.
Martin
,
H.
, 1977, “
Heat and Mass Transfer Between Impinging Gas Jets and Solid Surfaces
,”
Adv. Heat Transfer
0065-2717,
13
, pp.
1
60
.
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