• DocumentCode
    1828493
  • Title

    Experimental investigation of microgap cooling technology for minimizing temperature gradient and mitigating hotspots in electronic devices

  • Author

    Alam, Tamanna ; Lee, Poh Seng ; Yap, Christopher R. ; Jin, Liwen

  • Author_Institution
    Dept. of Mech. Eng., Nat. Univ. of Singapore, Singapore, Singapore
  • fYear
    2011
  • fDate
    7-9 Dec. 2011
  • Firstpage
    530
  • Lastpage
    535
  • Abstract
    Hotspots can be generated by non-uniform heat flux condition over the heated surface due to higher packaging densities and greater power consumption of high-performance computing technology in military systems designs. Because of this hotspot within a given chip, local heat generation rate exceed the average value on the chip and increase the peak temperature for a given total power generation which degrades the reliability and performance of equipments. Two phase microgap cooling technology is promising to minimization of temperature gradient and reduction of maximum temperature over the heated surface of the device because of unique boiling mechanism in microgap: confined flow and thin film evaporation. The present study aims to experimentally investigate the applicability of microgap cooling technology for minimizining temperature gradient and mitigating hotspots from the heated surface of electronic device. Experiments are performed in silicon based microgap heat sink having a range of gap dimension from 200 μm - 400 μm. Encouraging results have been obtained using microgap channel cooler for hotspots mitigation as it maintain uniform and low wall temperature over the heated surface.
  • Keywords
    cooling; electronics packaging; evaporation; heat sinks; thin films; electronic devices; heat generation; high-performance computing technology; hotspots mitigation; microgap channel cooler; microgap heat sink; military systems designs; non-uniform heat flux; power consumption; size 200 mum to 400 mum; thin film evaporation; two phase microgap cooling technology; Fluctuations; Heat sinks; Heat transfer; Microchannel; Temperature sensors; Water heating;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Electronics Packaging Technology Conference (EPTC), 2011 IEEE 13th
  • Conference_Location
    Singapore
  • Print_ISBN
    978-1-4577-1983-7
  • Electronic_ISBN
    978-1-4577-1981-3
  • Type

    conf

  • DOI
    10.1109/EPTC.2011.6184478
  • Filename
    6184478