Surface Structure Enhanced Microchannel Flow Boiling

Yangying Zhu; Dion S. Antao; Kuang Han Chu; Siyu Chen; Terry J. Hendricks; Tiejun Zhang; Evelyn N. Wang

doi:10.1115/1.4033497

Surface Structure Enhanced Microchannel Flow Boiling

Yangying Zhu
, Dion S. Antao
, Kuang Han Chu
, Siyu Chen
, Terry J. Hendricks
, Tiejun Zhang
, Evelyn N. Wang

Mechanical & Nuclear Engineering

Research output: Contribution to journal › Article › peer-review

157 Scopus citations

Abstract

We investigated the role of surface microstructures in two-phase microchannels on suppressing flow instabilities and enhancing heat transfer. We designed and fabricated microchannels with well-defined silicon micropillar arrays on the bottom heated microchannel wall to promote capillary flow for thin film evaporation while facilitating nucleation only from the sidewalls. Our experimental results show significantly reduced temperature and pressure drop fluctuation especially at high heat fluxes. A critical heat flux (CHF) of 969 W/cm² was achieved with a structured surface, a 57% enhancement compared to a smooth surface. We explain the experimental trends for the CHF enhancement with a liquid wicking model. The results suggest that capillary flow can be maximized to enhance heat transfer via optimizing the microstructure geometry for the development of high performance two-phase microchannel heat sinks.

Original language	British English
Article number	091501
Journal	Journal of Heat Transfer
Volume	138
Issue number	9
DOIs	https://doi.org/10.1115/1.4033497
State	Published - 1 Sep 2016

Keywords

critical heat flux
flow instabilities
Microchannel flow boiling
surface microstructures

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10.1115/1.4033497

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@article{498be9ad35564eefb9ff20ed3b563ab1,

title = "Surface Structure Enhanced Microchannel Flow Boiling",

abstract = "We investigated the role of surface microstructures in two-phase microchannels on suppressing flow instabilities and enhancing heat transfer. We designed and fabricated microchannels with well-defined silicon micropillar arrays on the bottom heated microchannel wall to promote capillary flow for thin film evaporation while facilitating nucleation only from the sidewalls. Our experimental results show significantly reduced temperature and pressure drop fluctuation especially at high heat fluxes. A critical heat flux (CHF) of 969 W/cm2 was achieved with a structured surface, a 57\% enhancement compared to a smooth surface. We explain the experimental trends for the CHF enhancement with a liquid wicking model. The results suggest that capillary flow can be maximized to enhance heat transfer via optimizing the microstructure geometry for the development of high performance two-phase microchannel heat sinks.",

keywords = "critical heat flux, flow instabilities, Microchannel flow boiling, surface microstructures",

author = "Yangying Zhu and Antao, \{Dion S.\} and Chu, \{Kuang Han\} and Siyu Chen and Hendricks, \{Terry J.\} and Tiejun Zhang and Wang, \{Evelyn N.\}",

note = "Funding Information: This work was partially funded by the Office of Naval Research (ONR) with Dr. Mark Spector as program manager (N00014-15-1-2483), the Cooperative Agreement between the Masdar Institute of Science and Technology (Masdar Institute), Abu Dhabi, UAE and the Massachusetts Institute of Technology (MIT), Cambridge, MA,-Reference 02/MI/MI/CP/11/07633/GEN/G/00, the Battelle Memorial Institute, the Air Force Office of Scientific Research (AFOSR) and the Singapore-MIT Alliance for Research and Technology (SMART). Publisher Copyright: {\textcopyright} 2016 by ASME.",

year = "2016",

month = sep,

day = "1",

doi = "10.1115/1.4033497",

language = "British English",

volume = "138",

journal = "Journal of Heat Transfer",

issn = "0022-1481",

publisher = "American Society of Mechanical Engineers (ASME)",

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TY - JOUR

T1 - Surface Structure Enhanced Microchannel Flow Boiling

AU - Zhu, Yangying

AU - Antao, Dion S.

AU - Chu, Kuang Han

AU - Chen, Siyu

AU - Hendricks, Terry J.

AU - Zhang, Tiejun

AU - Wang, Evelyn N.

N1 - Funding Information: This work was partially funded by the Office of Naval Research (ONR) with Dr. Mark Spector as program manager (N00014-15-1-2483), the Cooperative Agreement between the Masdar Institute of Science and Technology (Masdar Institute), Abu Dhabi, UAE and the Massachusetts Institute of Technology (MIT), Cambridge, MA,-Reference 02/MI/MI/CP/11/07633/GEN/G/00, the Battelle Memorial Institute, the Air Force Office of Scientific Research (AFOSR) and the Singapore-MIT Alliance for Research and Technology (SMART). Publisher Copyright: © 2016 by ASME.

PY - 2016/9/1

Y1 - 2016/9/1

N2 - We investigated the role of surface microstructures in two-phase microchannels on suppressing flow instabilities and enhancing heat transfer. We designed and fabricated microchannels with well-defined silicon micropillar arrays on the bottom heated microchannel wall to promote capillary flow for thin film evaporation while facilitating nucleation only from the sidewalls. Our experimental results show significantly reduced temperature and pressure drop fluctuation especially at high heat fluxes. A critical heat flux (CHF) of 969 W/cm2 was achieved with a structured surface, a 57% enhancement compared to a smooth surface. We explain the experimental trends for the CHF enhancement with a liquid wicking model. The results suggest that capillary flow can be maximized to enhance heat transfer via optimizing the microstructure geometry for the development of high performance two-phase microchannel heat sinks.

AB - We investigated the role of surface microstructures in two-phase microchannels on suppressing flow instabilities and enhancing heat transfer. We designed and fabricated microchannels with well-defined silicon micropillar arrays on the bottom heated microchannel wall to promote capillary flow for thin film evaporation while facilitating nucleation only from the sidewalls. Our experimental results show significantly reduced temperature and pressure drop fluctuation especially at high heat fluxes. A critical heat flux (CHF) of 969 W/cm2 was achieved with a structured surface, a 57% enhancement compared to a smooth surface. We explain the experimental trends for the CHF enhancement with a liquid wicking model. The results suggest that capillary flow can be maximized to enhance heat transfer via optimizing the microstructure geometry for the development of high performance two-phase microchannel heat sinks.

KW - critical heat flux

KW - flow instabilities

KW - Microchannel flow boiling

KW - surface microstructures

UR - https://www.scopus.com/pages/publications/84971407741

U2 - 10.1115/1.4033497

DO - 10.1115/1.4033497

M3 - Article

AN - SCOPUS:84971407741

SN - 0022-1481

VL - 138

JO - Journal of Heat Transfer

JF - Journal of Heat Transfer

IS - 9

M1 - 091501

ER -

Surface Structure Enhanced Microchannel Flow Boiling

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Keywords

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