Two-Phase Closed-Loop Thermosyphon Filled with a Dielectric Liquid for Electronics Cooling Applications

This paper investigates the thermal performance of a small two-phase closed-loop thermosyphon (TPCLT), with an inner tube diameter of 4.8 mm, filled with a dielectric liquid and intended for use in server cooling applications. The TPCLT is filled with a working dielectric fluid free of non-condensab...

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Published in2021 20th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (iTherm) pp. 74 - 80
Main Authors Ghaffari, Omidreza, Sayed, Chady Al, Vincent, Manuel, Larimi, Yaser Nabavi, Grenier, Francis, Jasmin, Simon, Frechette, Luc, Sylvestre, Julien
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.06.2021
Subjects
Boiling and condensation
Coatings
Cooling
Dielectric Liquid
Dielectric liquids
Electronic cooling
Filling
Liquids
Multi-scale porous coating
Servers
Thermal resistance
Two-Phase Closed-Loop Thermosyphon
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Summary:This paper investigates the thermal performance of a small two-phase closed-loop thermosyphon (TPCLT), with an inner tube diameter of 4.8 mm, filled with a dielectric liquid and intended for use in server cooling applications. The TPCLT is filled with a working dielectric fluid free of non-condensable gases, the Novec™ 7000 from the 3M corporation. We have studied two porous-coated copper heat spreaders , both with a surface area of 42 mm by 48 mm exposed to the liquid. The heat spreaders were attached to a 2.54 cm by 2.54 cm high-power heater. One of the heat spreaders was covered by a novel multi-scale electroplated porous coating (MuSEP). The other had a boiling enhancement coating that is commercially available from the 3M corporation. We studied the effect of the filling ratio (FR: liquid volume divided by the volume of the system) and of the cooling power on the system's thermal performance. Among the three tested FR (32%, 42%, and 52%), the MuSEP coating showed its best performance at a FR of 42%. The maximum applied heater power for the MuSEP coated evaporator was (315 ± 8.8) W at a heater temperature below 80°C (heater power density of 49 W/cm 2 ). The superior performance of the MuSEP coating was evident as the 3M boiling enhancement coating(BEC) could only remove (254 ±7.1) W at a heater temperature below 80°C. At a FR of 32%, the 3M BEC coating reached a dryout condition at (204 ±5.7) W, while the MuSEP coating kept the heater temperature at 64°C without dryout at the same power. Since we had a substantially subcooled liquid at the evaporator inlets with a liquid temperature in downcomers kept between 21 and 24°C, no pressure related instabilities were observed in the TPCLT loop that deteriorated its performances. The condenser thermal resistance was approximately 50% of the total heater-to-ambient thermal resistance in the TPCLT at (315 ±8.8) W, showing that condenser optimization is key to achieving better performance and higher power levels.
ISSN:2694-2135
DOI:10.1109/ITherm51669.2021.9503149