Title :
Silicon heat pipes used as thermal spreaders
Author :
Gillot, C. ; Avenas, Y. ; Cézac, N. ; Poupon, G. ; Schaeffe, C. ; Fournier, Etienne
Author_Institution :
Lab d´´Electron. et de Technol. de l´´Inf., CEA, Centre d´´Etudes Nucleaires de Grenoble, France
Abstract :
An increase in power densities in electronic devices is a direct consequence of their miniaturization and performance improvements. We propose the use of flat miniature heat pipes with micro capillary grooves to spread heat flux across a beat sink. Models of the structure were developed to calculate heat transfer limitations and temperature drops. A brass/water prototype was fabricated to demonstrate the feasibility of heat spreading using this type of heat pipe. Simulation and experimental results obtained with the prototype are described. The dissipated power reached 110 W/cm2 without heat transfer limitations. The results are then extended to the design of this type of heat pipe in silicon. Thermal performance was calculated. Simulation, experimental results and the fabrication process are presented.
Keywords :
boiling; capillarity; cooling; elemental semiconductors; heat pipes; heat sinks; packaging; silicon; thermal resistance; Si; Si heat pipes; beat sink; boiling limit; brass/water prototype; capillary limit; dissipated power; electronic device power densities; flat miniature heat pipes; heat flux spreading; heat transfer limitations; micro capillary grooves; miniaturization; performance improvements; simulation; temperature drops; thermal spreaders; Heat sinks; Heat transfer; Hydraulic diameter; Silicon; Space heating; Surface resistance; Temperature; Thermal conductivity; Thermal resistance; Water heating;
Conference_Titel :
Thermal and Thermomechanical Phenomena in Electronic Systems, 2002. ITHERM 2002. The Eighth Intersociety Conference on
Print_ISBN :
0-7803-7152-6
DOI :
10.1109/ITHERM.2002.1012574
