Related references
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Wen Yang et al.
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Flavia Barbosa et al.
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Pranjali R. Tete et al.
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R. Cagtay Sahin et al.
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Furen Zhang et al.
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Seokkan Ki et al.
Summary: Development of an effective battery thermal management system is crucial for increasing battery lifetime and reliable operation. Liquid cooling is a promising strategy due to its high heat transfer coefficient. However, conventional liquid cooling modules require high pumping power and induce high-temperature deviation. Researchers propose an energy-efficient liquid cooling module incorporating flow distributors connected to a porous metal layer.
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Jasim M. Mahdi et al.
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Maohua Li et al.
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Wen Yang et al.
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Thermodynamics
Huaqiang Liu et al.
Summary: A hybrid system combining PCM/copper foam with helical liquid channels was proposed and investigated numerically, showing more than 30 K temperature drop compared to natural convection. Various factors such as helical pitch, diameter, tube number, flow velocity, foam porosity, and pore density were studied to optimize battery temperature control.
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Lei Sheng et al.
Summary: The study found that interlaced flow directions can result in lower temperature standard deviation and more uniform thermal distribution, while increasing fluid flow rate and channel size can enhance the performance of the cellular cooling plate. Glycol aqueous solution is more effective in reducing temperature difference and standard deviation of the cells compared to liquid water.
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