Study on the Liquid Cooling Method of Longitudinal Flow through Cell Gaps Applied to Cylindrical Close-Packed Battery

IF 2.1 Q2 ENGINEERING, MULTIDISCIPLINARY Inventions Pub Date : 2023-08-11 DOI:10.3390/inventions8040100
Wei Li, W. Shi, S. Xiong, Hai Huang, Guodong Chen
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Abstract

The increasing popularity of electric vehicles presents both opportunities and challenges for the advancement of lithium battery technology. A new longitudinal-flow heat dissipation theory for cylindrical batteries is proposed in order to increase the energy density and uniform temperature performance of cylindrical lithium-ion battery packs while also shrinking their size by roughly 10%. First, a genetic algorithm is used to identify a single cell’s thermal properties. Based on this, modeling and simulation are used to examine the thermal properties of the longitudinal-flow-cooled battery pack. It is found that the best coolant flow scheme has one inlet and one outlet from the end face, taking into account the cooling effect of the battery pack and engineering viability. Lastly, thermal dummy cells (TDCs) are used to conduct a validation test of the liquid cooling strategy. Additionally, the simulation and test results demonstrate that the liquid cooling solution can restrict the battery pack’s maximum temperature rise under the static conditions of a continuous, high-current discharge at a rate of 3C to 20 °C and under the dynamic conditions of the New European Driving Cycle (NEDC) to 2 °C. In applications where the space requirements for the battery pack are quite strict, the longitudinal-flow cooling method has some advantages.
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圆柱密装电池槽隙纵向流动液体冷却方法研究
电动汽车的日益普及给锂电池技术的发展带来了机遇和挑战。为了提高圆柱形锂离子电池组的能量密度和均匀温度性能,同时将圆柱形锂离子电池组的尺寸缩小约10%,提出了一种新的圆柱形锂离子电池组的纵向流动散热理论。首先,使用遗传算法来识别单个细胞的热特性。在此基础上,对纵向流冷电池组的热特性进行了建模和仿真研究。研究发现,考虑到电池组的冷却效果和工程可行性,最佳的冷却液流动方案为端面各有一个入口和一个出口。最后,利用热虚拟电池(tdc)进行了液体冷却策略的验证测试。此外,仿真和测试结果表明,在以3C速率连续大电流放电的静态条件下,液冷溶液可以将电池组的最大温升限制在20°C,在新欧洲驾驶循环(NEDC)的动态条件下,该液体冷却溶液可以将电池组的最大温升限制在2°C。在对电池组空间要求相当严格的应用中,纵向流冷却方法具有一定的优势。
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来源期刊
Inventions
Inventions Engineering-Engineering (all)
CiteScore
4.80
自引率
11.80%
发文量
91
审稿时长
12 weeks
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