Analysis of thermal performance and pressure loss of subcooled flow boiling in manifold microchannel heat sink

•A new solver involving S-CLSVOF method for two-phase flow is developed based on OpenFOAM.•Conjugate heat transfer between fluid and solid is taken into consideration.•A three-dimensional transient simulation of subcooled flow boiling in MMC heat sink unit cell model is performed.•Influence of micro...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2020-12, Vol.162, p.120362, Article 120362
Main Authors: Luo, Yang, Li, Wei, Zhang, Jingzhi, Minkowycz, W.J.
Format: Article
Language:English
Subjects:
Boiling
Flow velocity
Heat
Heat flux
Heat sinks
Heat transfer
Liquid-vapor interfaces
Manifold microchannel heat sink
Manifolds
Microchannels
Numerical simulation
Pressure drop
Pressure loss
S-CLSVOF method
Subcooled flow boiling
Thermal energy
Thermal resistance
Unit cell
Wall temperature
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Summary:•A new solver involving S-CLSVOF method for two-phase flow is developed based on OpenFOAM.•Conjugate heat transfer between fluid and solid is taken into consideration.•A three-dimensional transient simulation of subcooled flow boiling in MMC heat sink unit cell model is performed.•Influence of microchannel width and fin width on MMC heat sink thermal performance and pressure loss is studied. The manifold microchannel (MMC) heat sink for high-heat-flux removal in next-generation microelectronic system has received a significant attention recently. A numerical study is performed to analyze thermal performance and pressure loss of subcooled flow boiling in an MMC unit cell model. On the basis of OpenFOAM package, a new solver is developed for solving subcooled flow boiling and solid-fluid heat transfer. The simple coupled volume of fluid with level set (S-CLSVOF) method is used to capture the liquid-vapor interface during phase change. After validating the numerical approach with experimental data, effects of microchannel width wc and fin width wf on average chip wall temperature and inlet-to-outlet pressure drop are discussed. Seven MMC samples with different size of channel widths and fin widths are studied at inlet volume flow rates of 19, 31 and 42 mL/min as wall heat flux is fixed at 400 W/cm2. The results indicate that decreasing wc and wf will lead to low average wall temperature on the heated wall, but pressure drop between inlet and outlet surfaces will rise dramatically. When the total number of channels of the MMC heat sink remains unchanged, increasing wc leads to decreasing wf; the thermal resistance of the MMC heat sink is gradually increased while the pressure drop is reduced (e.g. +0.16 °C/W, -656 kPa at 42 mL/min).
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2020.120362