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基于液体冷却和加热的电动汽车电池热管理系统(英文) 被引量:41

Battery Thermal Management System with Liquid Cooling and Heating in Electric Vehicles
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摘要 电动汽车(EV)电池系统的性能和寿命受到温度的影响。为了把电池系统的平均温度控制在20℃到45℃范围内,同时把温度梯度控制在3℃内,该文设计了一种具有最优几何结构的液体冷却和加热板的电池热管理(BTM)系统。根据BTM系统的总体流量均衡,仿真模拟了不同结构参数的冷却板,研究其冷却效果。在电池系统加热实验中,利用红外热像仪检测了加热板的表面温升情况。试验结果与仿真结果显示出较好的一致性。研究发现:进出口在同一边的结构,流场均匀。利用联合优化仿真所得的进口速度和温度的最优组合,可以将加热板表面的温度标准差降低至2.61℃,使得电池系统获得均匀的加热。 The performance and life of electric-vehicle battery-systems are affected by the temperature. A liquid cooling/heating Battery Thermal Management (BTM) with an optimum geometric structure was designed to keep the average battery-system temperature in the range from 20℃ to 45℃ and the temperature gradient within 3 ℃. According to overall system flow balancing in a BTM, cooling/heating plates with different structure parameters were simulated to investigate cooling effects of the BTM. An infrared thermal imager monitored the cooling/heating plate temperature rises in battery-system heating experiments. Experimental and simulation results were shown to be the same. The results show that the structure with an inlet and an outlet on the same side has an even flow distribution. By combining the simulation and optimization, the obtained optimum combination of the inlet velocity and the temperature in the cooling/heating plate reduces the plate-surface- temperature standard-deviation to 2.61℃, and makes the battery system uniformly heated.
作者 袁昊 王丽芳 王立业
机构地区 中国科学院电工研究所 北京汽车新能源汽车有限公司
出处 《汽车安全与节能学报》 CAS 2012年第4期371-380,共10页 Journal of Automotive Safety and Energy
基金 The National 863 High Technology Research and Development Project~~
关键词 电动汽车(EV) 电池热管理(BTM) 电池模块 流量均衡 液体冷却加热板 联合优化仿真 electric vehicle (EV) battery thermal management (BTM) battery module flow balancing liquid cooling/heating plate combined simulation and optimization
分类号 U469.7 [机械工程—车辆工程] TM912.9 [电气工程—电力电子与电力传动]
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参考文献14

  • 1Pesaran A A. Thermal characterization of selected EV and HEV balteries [C]//Ann Battery Conf. Long Beach, CA Jan 9-12, 2001.
  • 2Duan X, Nalerer G F, Heat transfer in phase change materials for thermal management of electric vehicle battery modules [J] Int'l J Heat and Mass Transfer, 2010, 53: 5176-5182.
  • 3.lung D Y, Lee, B H, Kim S W, Development of battery management system for nickel-metal hydride batteries in electric vehicle applications [J] J Power Sources, 2002, 109: 1-10.
  • 4Dickinson B, Swan D. EV battery pack life: Pack degradation and solutions [C]//Proc Future Transportation Tech Conf and Expo, 1995.
  • 5Sato N. Thermal behavior analysis of lithium-ion batteries for electric and hybrid vehicles [J]. J Power Sources, 2001, 99 (1/2): 70-77.
  • 6Mahamud R, Park C. Reciprocating air flow for Li-ion battery thermal management to improve temperature uniformity [J]. J Power Sources, 2011,196: 5685-5696.
  • 7Kizilel R, Sabbah R, Selman J R, et al. An alternative cooling system to enhance the safety of Li-ion battery packs [J]. J Power Sources, 2009, 194:1105-1112.
  • 8Sabbah R, Kizilel R, Selman J R, et al. Active (air-cooled) vs.passive (phase change material) thermal management of high power lithium-ion packs: Limitation of temperature rise and uniformity of temperature distribution [J]. J Power Sources, 2008, 182:630 638.
  • 9Giuliano M R, Advani S G, Prasad A K, Thermal analysis and management of lithium-titanate batteries [J]. J Power Sources, 2011,196: 6517-6524.
  • 10Pesaran A A. Battery thermal management in EVs and HEV: Issues and solutions [C]//Adv Automotive Battery Conf, Las Vegas, Nevada, Feb 6-8, 2001.

同被引文献226

引证文献41

二级引证文献361

汽车安全与节能学报
2012年 第4期

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