Aluminum Heat Sink Assisted Air-Cooling Thermal Management System for High Current Applications in Electric Vehicles

H. Behi, D. Karimi, J. Jaguemont, F. H. Gandoman, S. Khaleghi, J. Van Mierlo, M. Berecibar
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引用次数: 22

Abstract

Lithium-ion (Li-ion) batteries are preferred energy storage systems for vehicular applications due to the high capacity, long life, and power density. This paper offers the concept of a hybrid thermal management system (TMS), including a prismatic cell embedded fin heat sink (CHS) for high current applications. The experimental tests and numerical simulations are done to investigate the thermal characteristic of the utilized battery and CHS in natural and forced convection in 8C discharging rate (184 A). Results indicate that the maximum cell temperature in natural convection (NC) reaches 56 °C. Moreover, the temperature of the CHS in natural and forced convection reaches 51.5 °C and 31.1 °C. For further investigation, the optimization, including three cases, is done for the geometry of the forced convection cooling box. Results indicate that the maximum temperature of the CHS compared with NC reduced by 39.6%, 40.9%, and 38.4% for cases A, B, and C, respectively. In addition, there is an improvement of 6%, 28%, and 36% in the cell temperature uniformity for cases A, B, and C, respectively. It is also found that the inlet velocity of 3 m/s preserves the CHS in a safe temperature zone, which decreases the fan power consumption by 50%.
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用于电动汽车大电流应用的铝散热器辅助风冷热管理系统
锂离子(Li-ion)电池因其高容量、长寿命和功率密度而成为汽车应用的首选储能系统。本文提出了一种混合热管理系统(TMS)的概念,包括用于大电流应用的棱镜电池嵌入式散热片(CHS)。在8C放电速率(184 A)条件下,采用自然对流和强制对流对电池和CHS的热特性进行了实验测试和数值模拟。结果表明,自然对流(NC)条件下电池的最高温度可达56℃。自然对流和强迫对流下CHS温度分别达到51.5℃和31.1℃。为了进一步研究,对强制对流冷却箱的几何形状进行了三种情况下的优化。结果表明:A、B、C病例的最高温度较NC分别降低了39.6%、40.9%和38.4%;此外,在A、B和C三种情况下,电池温度均匀性分别提高了6%、28%和36%。研究还发现,3 m/s的进口速度使CHS保持在安全温度范围内,使风机功耗降低50%。
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