A three-dimensional model has been developed to analyze the transient and steady-state performance of flat heat pipes subjected to heating with multiple discrete heat sources. Three-dimensional flow and energy equations are solved in the vapor and liquid regions, along with conduction in the wall. Saturated flow models are used for heat transfer and fluid flow through the wick. In the wick region, the analysis uses an equilibrium model for heat transfer and a Brinkman-Forchheimer extended Darcy model for fluid flow. Averaged properties weighted with the porosity are used for the wick analysis. The state equation is used in the vapor core to relate density change to the operating pressure. The density change due to pressurization of the vapor core is accounted for in the continuity equation. Vapor flow, temperature and hydrodynamic pressure fields are computed at each time step from coupled continuity/momentum and energy equations in the wick and vapor regions. The mass flow rate at the interface is obtained from the application of kinetic theory. Predictions are made for the magnitude of heat flux at which dryout would occur in a flat heat pipe. The input heat flux and the spacing between the discrete heat sources are studied as parameters. The location in the heat pipe at which dryout is initiated is found to be different from that of the maximum temperature. The location where the maximum capillary pressure head is realized also changes during the transient. Axial conduction through the wall and wick are seen to play a significant role in determining the axial temperature variation.

Issue Section:
Heat Pipes
Keywords:
heat pipes, pipe flow, flow through porous media, two-phase flow, hydrodynamics, mass transfer, kinetic theory, capillarity, heat conduction, vapour pressure, flow simulation, porosity, equations of state, Electronics, Heat Pipes, Phase Change, Three-Dimensional, Transient
Topics:
Heat, Heat pipes, Temperature, Vapors, Transients (Dynamics), Flat heat pipes, Pressure, Flow (Dynamics), Separation (Technology), Steady state
1.
Garimella, S. V., and Sobhan, C. B., 2001, “Recent Advances in the Modeling and Applications of Nonconventional Heat Pipes,” Advances in Heat Transfer, 35, pp. 249–308, Chpt. 4.
2.
Tien
,
C. L.
, and
Rohani
,
A. R.
,
1974
, “
Analysis of the Effects of Vapor Pressure Drop on Heat Pipe Performance
,”
Int. J. Heat Mass Transfer
,
17
, pp.
61
67
.
3.
Ooijen
,
V.
, and
Hoogendoorn
,
C. J.
,
1979
, “
Vapor Flow Calculations in a Flat Heat Pipe
,”
AIAA J.
,
17
, pp.
1251
1259
.
4.
Chen
,
M. M.
, and
Faghri
,
A.
,
1990
, “
An Analysis of the Vapor Flow and the Heat Conduction Through the Liquid Wick and Pipe Wall in a Heat Pipe with Single or Multiple Heat Sources
,”
Int. J. Heat Mass Transfer
,
33
, pp.
1945
1955
.
5.
Issacci
,
F.
,
Catton
,
I.
,
Heiss
,
A.
, and
Ghoniem
,
N. M.
,
1989
, “
Analysis of Heat Pipe Vapor Dynamics
,”
Chem. Eng. Commun.
,
85
, pp.
85
94
.
6.
Cao
,
Y.
, and
Faghri
,
A.
,
1990
, “
Transient Two-Dimensional Compressible Analysis for High-Temperature Heat Pipes with Pulsed Heat Input
,”
Numer. Heat Transfer, Part A
,
18
, pp.
483
502
.
7.
Issaci
,
F.
,
Catton
,
I.
, and
Ghoniem
,
N. M.
,
1991
, “
Vapor Dynamics of Heat Pipe Start-Up
,”
ASME J. Heat Transfer
,
113
, pp.
985
994
.
8.
Ambrose
,
J. H.
, and
Chow
,
L. C.
,
1991
, “
Detailed Model for Transient Liquid Flow in Heat Pipe Wicks
,”
J. Thermophys. Heat Transfer
,
5
, pp.
532
538
.
9.
Tournier
,
J. M.
, and
El-Genk
,
M. S.
,
1993
, “
A Heat Pipe Transient Analysis Model
,”
Int. J. Heat Mass Transfer
,
37
, pp.
753
762
.
10.
El-Genk
,
M. S.
,
Huang
,
L.
, and
Tournier
,
J. M.
,
1995
, “
Transient Experiments of an Inclined Copper-Water Heat Pipe
,”
J. Thermophys. Heat Transfer
,
9
, pp.
109
116
.
11.
Zhu
,
N.
, and
Vafai
,
K.
,
1998
, “
Analytical Modeling of the Startup Characteristics of Asymmetrical Flat-Plate and Disk-Shaped Heat Pipes
,”
Int. J. Heat Mass Transfer
,
41
, pp.
2619
2637
.
12.
Um, J. Y., Chow, L. C., and Baker, K., 1994, “An Experimental Investigation of Flat Heat Pipe,” Fundamentals of Heat Pipes, 278, ASME, New York, pp. 21–26.
13.
Chesser, J. B., Peterson, G. P., and Lee, S., 2000, “A Simplified Method for Determining the Capillary Limitation of Flat Heat Pipes in Electronics Cooling,” Proceedings of NHTC’00, 34th National Heat Transfer Conference, pp. 1–6.
14.
Shimura, T., Sho, H., and Nakamura, Y., 2002, “The Aluminum Flat Heat Pipe Using Cyclopentane as Working Fluid,” Inter Society Conference on Thermal Phenomena, IEEE, pp. 224–229.
15.
Chien, L., and Chang, C. C., 2002, “Experimental Study of Evaporator Resistance on Porous Surface in Flat Heat Pipes,” Inter Society Conference on Thermal Phenomena, IEEE, pp. 236–242.
16.
Gillot, C., Avenas, Y., Cezac, N., Poupo, G., Schaeffer, C., and Fournier, E., 2002, “Silicon Heat Pipes Used as Thermal Spreaders,” Inter Society Conference on Thermal Phenomena, IEEE, pp. 1052–1057.
17.
Xuan, Y., Hong, Y., and Li, Q., 2003, “Investigation on Transient Behaviors of Flat Heat Pipes,” Exp. Therm. Fluid Sci., in press.
18.
Rightley
,
M. J.
,
Tigges
,
C. P.
,
Givler
,
R. C.
,
Robino
,
C. V.
,
Mulhall
,
J. J.
, and
Smith
,
P. M.
,
2003
, “
Innovative Wick Design for Multi-Source, Flat Plate Heat Pipes
,”
Microelectron. J.
,
34
(
3
), pp.
187
194
.
19.
Vadakkan, U., Murthy, J. Y., and Garimella, S. V., 2003, “Transient Analysis of Flat Heat Pipes,” Procs. ASME Summer Heat Transfer Conference, Paper No. HT2003-47349.
20.
Grubb, K., 1999, “CFD Modeling of a Therma-Base(TM) Heat Sink,” 8th International FLOTHERM User Conference.
21.
Carey, V. P., 1992, Liquid-Vapor Phase Change Phenomena, Hemisphere Publishing Corp., Washington DC.
22.
Patankar, S. V., 1980, Numerical Heat Transfer and Fluid Flow, McGraw-Hill, New York.
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