Experiments were conducted to study the flow and heat transfer characteristics of a natural circulation liquid cooling system for electronic components. The test loop consisted of a horizontal test section, a horizontal evaporator, a vertical tube, a horizontal condenser, a rubber bag attached at the exit of the condenser, a downcomer, a mass flow meter, and a liquid subcooler. The loop height H was set at either 250 or 450 mm. FC-72 was filled in the test loop up to some level of loop height and the upper part was filled with air. During the operation of the cooling system, the rubber bag expanded and stored the mixture of generated vapor and air. Thus the inner pressure was maintained at atmospheric pressure. In the test section, a silicon chip with dimensions of 10×10×0.5 mm3 was attached at the bottom surface of a horizontal duct with dimensions of 10×14 mm2. A smooth chip and four chips with square micro-pin-fins with 150 to 300 μm in fin height were tested. The duct height s was set at 10 mm for most of the experiments. The cases of s=1 and 25 mm were also tested for one of the micro-pin-finned chips. For each H, the average flow rate of FC-72 was correlated well as a function of the static pressure difference between the two vertical tubes. All chips showed the boiling curve similar to that for pool boiling except that the critical heat flux was lower for the natural circulation loop. For all chips tested, the maximum allowable heat flux qmax increased monotonically with increasing liquid subcooling ΔTsub. Comparison of the results for s=1, 10 and 25 mm revealed that the highest qmax was obtained with s=10mm. The values of qmax for s=1 and 25 mm were 36–46% and 87–90% of that for s=10mm, respectively. The maximum value of qmax=56W/cm2 was obtained by one of the micro-pin-finned chips at s=10mm and ΔTsub=35K.

Issue Section:
Research Paper
Keywords:
cooling, pipe flow, condensation, silicon, boiling, two-phase flow, integrated circuit packaging
Topics:
Boiling, Critical heat flux, Electronic components, Flow (Dynamics), Heat transfer, Pool boiling, Ducts, Condensers (steam plant), Heat flux, Cooling, Vapors, Evaporative cooling
1.
Bar-Cohen
,
A.
,
1983
, “
Thermal Design of Immersion Cooling Modules for Electronic Components
,”
Heat Transfer Eng.
,
4
, pp.
35
50
.
2.
Simons
,
R. E.
,
1995
, “
The Evolution of IBM High Performance Cooling Technology
,”
IEEE Trans. Compon., Packag. Manuf. Technol., Part A
,
18
, pp.
805
811
.
3.
Fairbanks, D. R., Goltsos, C. E., and Mark, M., 1967, “The Submerged Condenser,” ASME Publication 67-HT-15, ASME/AIChE National Heat Transfer Conference.
4.
Markowitz, A., and Bergles, A. E., 1972, “Operational Limits of Submerged Condenser,” Progress in Heat and Mass Transfer, Vol. 6, pp. 701–716, Pergamon Press, Oxford.
5.
Bravo, H. V., and Bergles, A. E., 1976, “Limits of Boiling Heat Transfer in a Liquid-Filled Enclosure,” Proc. 24th HTFMI, pp. 114–127.
6.
Bar-Cohen, A., and Distel, H., 1978, “Bubble Pumped Augmented Natural Convection in a Submerged Condenser System,” Proc. 6th International Heat Transfer Conference, Vol. 3, pp. 197–202.
7.
Nelson
,
R. D.
,
Sommerfeldt
,
S.
, and
Bar-Cohen
,
A.
,
1994
, “
Thermal Performance of an Immersion Cooled Multichip Module Package
,”
IEEE Trans. Compon., Packag., Manuf. Technol., Part A
,
17
, pp.
405
412
.
8.
Kitching
,
D.
,
Ogata
,
T.
, and
Bar-Cohen
,
A.
,
1995
, “
Thermal Performance of a Passive Immersion-Cooling Multichip Module
,”
J. Enhanced Heat Transfer
,
2
, pp.
95
103
.
9.
Tian
,
S. R.
,
Takamatsu
,
H.
, and
Honda
,
H.
,
1998
, “
Experimental Study on Immersion Cooling of an Upward-Facing Multichip Module With an Opposing Condensing Surface
,”
Heat Transfer-Jap. Res.
,
27
, pp.
497
508
.
10.
Mukherjee
,
S.
, and
Mudawar
,
I.
,
2003
, “
Pumpless Loop for Narrow Channel and Micro-Channel Boiling
,”
ASME J. Electron. Packag.
,
125
, pp.
431
441
.
11.
Mukherjee
,
S.
, and
Mudawar
,
I.
,
2003
, “
Smart Pumpless Loop for Micro-Channel Electronic Cooling Using Flat and Enhanced Surfaces
,”
IEEE Trans. Compon., Packag. Technol.
,
26
, pp.
99
109
.
12.
Wei
,
J. J.
, and
Honda
,
H.
,
2003
, “
Effects of Fin Geometry on Boiling Heat Transfer From Silicon Chips With Micro-Pin-Fins Immersed in FC-72
,”
Int. J. Heat Mass Transfer
,
46
, pp.
4059
4070
.
13.
Honda
,
H.
,
Takamatsu
,
H.
, and
Wei
,
J. J.
,
2002
, “
Enhanced Boiling of FC-72 on Silicon Chips With Micro-Pin-Fins and Submicron-Scale Roughness
,”
ASME J. Heat Transfer
,
124
, pp.
383
390
.
14.
Chang
,
J. Y.
, and
You
,
S. M.
,
1996
, “
Heater Orientation Effects on Pool Boiling of Micro-Porous-Enhanced Surfaces in Saturated FC-72
,”
ASME J. Heat Transfer
,
118
, pp.
937
943
.
15.
Chisholm, D., 1972, “An Equation for Velocity Ratio in Two-Phase Flow,” NEL Report 535.
16.
Friedel, L., 1979, “Improved Friction Pressure Drop Correlations for Horizontal and Vertical Two-Phase Flow,” European Two-Phase Flow Group Meeting, Paper E2, Ispra, Italy.
17.
Blasius, H., 1913, “Das Aehnlichkeitsgesetz bei Reibungsvorgaengen in Fluessigkeiten,” Forschg. Arb. Ing.-Wes. No. 134, Berlin.
18.
Carnavos
,
T. C.
,
1980
, “
Heat Transfer Performance of Internally Finned Tubes in Turbulent Flow
,”
Heat Transfer Eng.
,
1
, pp.
32
37
.
19.
Hewitt, G. F., and Roberts, D. N., 1969, “Studies of Two-Phase Flow Patterns by Simultaneous Flash and X-ray Photography,” AERE-M2159.
20.
McQuillan
,
K. W.
, and
Whalley
,
P. B.
,
1985
, “
A Comparison Between Flooding Correlations and Experimental Data
,”
Chem. Eng. Sci.
,
40
, pp.
1425
1440
.
21.
International Roadmap Committee, 2002, International Technology Roadmap for Semiconductors, 2002 Update, http://public.itrs.net/.
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