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Title: Axially Tapered And Bilayer Microchannels For Evaporative Cooling Devices

Patent ·
OSTI ID:880227
 [1];  [2]
  1. Cardiff, CA
  2. Livermore, CA
+ Show Author Affiliations

The invention consists of an evaporative cooling device comprising one or more microchannels whose cross section is axially reduced to control the maximum capillary pressure differential between liquid and vapor phases. In one embodiment, the evaporation channels have a rectangular cross section that is reduced in width along a flow path. In another embodiment, channels of fixed width are patterned with an array of microfabricated post-like features such that the feature size and spacing are gradually reduced along the flow path. Other embodiments incorporate bilayer channels consisting of an upper cover plate having a pattern of slots or holes of axially decreasing size and a lower fluid flow layer having channel widths substantially greater than the characteristic microscale dimensions of the patterned cover plate. The small dimensions of the cover plate holes afford large capillary pressure differentials while the larger dimensions of the lower region reduce viscous flow resistance.

Research Organization:
Sandia National Laboratories (SNL), Albuquerque, NM, and Livermore, CA (United States)
DOE Contract Number:
AC04-94AL85000
Assignee:
Sandia National Laboratories (Livermore, CA)
Patent Number(s):
US 6951243
Application Number:
10/683938
OSTI ID:
880227
Country of Publication:
United States
Language:
English

References (13)

Intermolecular forces in phase-change heat transfer: 1998 Kern award review journal October 1999
Capillary Flow in Triangular Grooves journal June 1974
Fabrication of microstructures with high aspect ratios and great structural heights by synchrotron radiation lithography, galvanoforming, and plastic moulding (LIGA process) journal May 1986
A steady state, one dimensional, model for boiling two phase flow in triangular micro-channel journal July 2000
Non-dimensional analysis for the heat transport capability of axially grooved heat pipes including liquid/vapor interaction conference February 2013
Film evaporation from a micro-grooved surface - An approximate heat transfer model and its comparison with experimental data journal October 1990
Experimental and theoretical study of axial dryout point for evaporation from V-shaped microgrooves journal March 2002
The Interline Heat Transfer of Evaporating Thin Films Along a Micro Grooved Surface journal August 1996
A Semi-Analytical Model to Predict the Capillary Limit of Heated Inclined Triangular Capillary Grooves journal February 2001
SLATEC Common Mathematical Subprogram Library: SNLA implementation report December 1980
Recent developments in deep x-ray lithography journal November 1998
Analysis of the heat transfer coefficient of grooved heat pipe evaporator walls journal February 1992
An Experimental Investigation of the Capillary Performance of Triangular Versus Sinusoidal Channels journal November 1997

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