This study numerically examines the influence of inlet locations on the performance of the Multichannel cold-plates. A total of five inlet configurations (namely I-, Z-, ]-, L-, and /spl Gamma/-arrangement) are investigated in this study. The velocity maldistribution and nonuniformity of temperature field caused by the fluid flow are shown in the simulation. For I-arrangement, higher inlet flow rate of the cold-plate shows more considerable maldistribution, and this maldistribution is decreased when the number of channels of the cold-plate is increased. The Z-arrangement and L-arrangements show a pronounced flow-recirculation that eventually leads to a much larger temperature difference along the surface of the cold-plate. Conversely, there is no flow recirculation in the ]-arrangement and a comparatively uniform flow distribution is seen. For the same average inlet velocity, I-arrangement has the highest pressure drop whereas ]-arrangement shows the lowest pressure drop. The I- and /spl Gamma/-arrangement give the best heat transfer performance due to their impingement configurations whereas the Z-arrangement shows the lowest heat transfer performance for its dramatic flow recirculation and maldistribution.
[1]
Allan D. Kraus,et al.
Thermal Analysis and Control of Electronic Equipment
,
1983
.
[2]
A. Mosyak,et al.
Nonuniform Temperature Distribution in Electronic Devices Cooled by Flow in Parallel Microchannels
,
2000,
Packaging of Electronic and Photonic Devices.
[3]
Chi-Chuan Wang,et al.
Investigation of the Flow Mal-Distribution in Microchannels
,
2003
.
[4]
A. B. Datta,et al.
Flow distribution in parallel and reverse flow manifolds
,
1980
.
[5]
Y. H. Hung,et al.
Heat Transfer and Flow Friction Characteristics for Compact Cold Plates
,
2003
.
[6]
Madhusudan lyengar,et al.
OPTIMIZATION OF VERTICAL PIN-FIN HEAT SINKS IN NATURAL CONVECTIVE HEAT TRANSFER
,
1998
.