Title :
Performance of a MEMS based micro capillary pumped loop for chip-level temperature control
Author :
Pettigrew, K. ; Kirshberg, J. ; Yerkes, K. ; Trebotich, D. ; Liepmann, D.
Author_Institution :
Berkeley Sensor & Actuator Centre, California Univ., Berkeley, CA, USA
Abstract :
To provide direct cooling to electronics and microelectromechanical systems, a three port micro-capillary pumped loop (CPL) was designed, fabricated and tested using current MEMS technology. The two wafer design consists of a silicon and a borofloat glass wafer. An evaporator, condenser, reservoir, and liquid and vapor lines were etched into the silicon wafer, while the glass wafer serves as a cover plate into which grooves were etched for capillary pumping. The geometry of the components of the device were determined via an analytical study. A finished device was run near steady state using laser spot heating and water as the working fluid. It was determined that a 1 mm/spl times/2 mm evaporator operates at a constant 100 /spl deg/C until wick dry-out at a laser power of 7.5 W (+/-2 W). Furthermore, with the same laser power the micro-CPL resulted in a backside cooling of at least 7 degrees C.
Keywords :
capillarity; cooling; integrated circuit packaging; micropumps; 100 degC; 7.5 W; MEMS based micro capillary pumped loop; MEMS technology; backside cooling; capillary pumping; chip-level temperature control; condenser; cover plate; direct cooling; evaporator; laser power; laser spot heating; micro-CPL; reservoir; two wafer design; wick dry-out; Electronic equipment testing; Electronics cooling; Etching; Glass; Microelectromechanical systems; Micromechanical devices; Power lasers; Silicon; System testing; Water heating;
Conference_Titel :
Micro Electro Mechanical Systems, 2001. MEMS 2001. The 14th IEEE International Conference on
Conference_Location :
Interlaken, Switzerland
Print_ISBN :
0-7803-5998-4
DOI :
10.1109/MEMSYS.2001.906569
