[1]王定标,纪世博,王光辉,等.储能电池包液冷散热结构设计与性能分析[J].郑州大学学报(工学版),2027,48(XX):1-9.[doi:10.13705/j.issn.1671-6833.2026.06.011]
 Wang Dingbiao,Ji Shibo,Wang G uanghui,et al.Structural Design and Performance Analysis of Liquid Cooling for Energy Storage Cabinets[J].Journal of Zhengzhou University (Engineering Science),2027,48(XX):1-9.[doi:10.13705/j.issn.1671-6833.2026.06.011]
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储能电池包液冷散热结构设计与性能分析()
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《郑州大学学报(工学版)》[ISSN:1671-6833/CN:41-1339/T]

卷:
48
期数:
2027年XX
页码:
1-9
栏目:
出版日期:
2027-12-10

文章信息/Info

Title:
Structural Design and Performance Analysis of Liquid Cooling for Energy Storage Cabinets
作者:
王定标1,2, 纪世博1,2, 王光辉1,2, 秦怡滔1,2, 王 帅1,2
1.郑州大学 机械与动力工程学院,郑州450001;2.新能源清洁利用技术与节能装备河南省国际联合实验室,郑州450001
Author(s):
Wang Dingbiao1,2,Ji Shibo 1,2,Wang G uanghui1,2,Qin Yitao 1,2,Wang Shuai 1,2
1.School of Mechanical and Power Engineering, Zhengzhou University, Zhengzhou 450001, China2. Henan International Joint Laboratory of New Energy Clean Utilization Technology and Energy saving Equipment, Zhengzhou 450001, China
关键词:
液冷板 结构设计 储能电池 热管理散热
Keywords:
liquid cooling plate structural design battery for energy storage thermal management heat dissipation
分类号:
TM912;TK124
DOI:
10.13705/j.issn.1671-6833.2026.06.011
文献标志码:
A
摘要:
针对储能电池包底部液冷板存在的流量分配不均、流动阻力较大、散热与压降难以平衡和高温工况下电池包热量积累等问题,创新设计了新型对称菱网形流道液冷板( CASE4) ,并对高温环境下间歇放电工况提出预冷策略。 将新型液冷板与并行流道液冷板(CASE1) 、对称蛇形流道液冷板(CASE2) 和商用液冷板( CASE3) 的流动和传热特性进行对比研究,进一步分析了冷却液入口流量、入口温度和流道高度对液冷板冷却性能和系统功耗的影响,并验证高温工况下的液冷性能。 结果表明,在相同边界条件下,对称菱网流道液冷板在实现电池包温度最低的同时,相较于 3 种对比结构,压降分别降低 24. 40%、44. 41% 和 63. 93%;综合散热效果与压降平衡,得出入口流量7. 5 L / min、流道高度 4 mm 的最优参数。 在 40 ℃ 高温环境中,电池包最高温度在不同的冷却液入口温度下均保持适宜工作范围,当冷却液入口温度升高 10 ℃ ,电池包最高温度升高 7. 5 ℃ ;在高温环境的电池间歇放电工况下,采用预冷策略时,整个过程中电池包最高温度为 39. 97 ℃ ,满足安全工作要求。
Abstract:
Aimed at the problems of uneven flow distribution, excessive flow resistance, difficulty in balancing heatdissipation and pressure drop in the bottom liquid cooling plate for energy storage battery packs, as well as heat accumulation under high-temperature operating conditions. A novel liquid cooling plate with symmetric diamond-meshchannels was innovatively designed, and a pre-cooling strategy was proposed for intermittent discharge under hightemperature environments. The flow and heat transfer performances of the novel liquid cooling plate were comparedwith those of the parallel-channel liquid cooling plate, symmetric serpentine-channel liquid cooling plate and commercial liquid cooling plate. The results showed that under the same boundary conditions, the lowest battery packtemperature was obtained by using the symmetric diamond-mesh channel liquid cooling plate, and the system pressure drop was reduced by 24. 40%, 44. 41% and 63. 93% respectively compared with the other three structures.The influences of coolant inlet flow rate, inlet temperature and channel height on cooling performance and systempower consumption were further analyzed. On the basis of the balance between heat dissipation effect and pressuredrop, the optimal inlet flow rate of 7. 5 L / min and the channel height of 4 mm were determined. In the 40 ℃ hightemperature environment, the maximum temperature of the battery pack was kept within the suitable working rangeunder different coolant inlet temperatures. When the coolant inlet temperature was increased by 10 ℃ , the maximum temperature of the battery pack was increased by 7. 5 ℃ . Under the intermittent discharge condition in hightemperature environment, the maximum temperature of the battery pack was controlled at 39. 97 ℃ throughout thewhole process with the pre-cooling strategy applied, which met the requirements for safe operation.Keywords: liquid cooling plate; structural design; battery for energy storage; thermal management; heat dissipation

参考文献/References:

[1] Lyu Peizhao, Liu Xinjian, Qu Jie, et al. Recent advances of thermal safety of lithium ion battery for energy storage[J]. Energy Storage Materials, 2020, 31: 195 -220.

[2] Sun Hongguang, Dixon R. Development of cooling strategy for an air cooled lithium-ion battery pack[J]. Journal of Power Sources, 2014, 272: 404 -414.

[3] Guo Rong, Li Lu. Heat dissipation analysis and optimization of lithium-ion batteries with a novel parallel-spiral serpentine channel liquid cooling plate[J]. International Journal of Heat and Mass Transfer, 2022, 189: 122706.

[4] Close J, Barnard J E, John Chew Y M, et al. A holistic approach to improving safety for battery energy storage systems[J]. Journal of Energy Chemistry, 2024, 92: 422-439.

[5] Guo Chaxiu, Wei Jinyu. Influence of different arrangement on phase change thermal management system of 21700 lithium battery[J]. Journal of Zhengzhou University (Engineering Science), 2023, 44(2): 91-97. [郭茶秀, 魏金宇. 电池排布方式对21700锂电池相变热管理系统的影响[J]. 郑州大学学报(工学版), 2023, 44( 2): 91-97.]

[6] Pan Zhenfei, Huang Peifeng, Luo Yimo, et al. Research progress on indirect cold plate and immersion cooling for lithium-ion battery thermal management [J]. Energy Storage Science and Technology, 2026, 15(3): 1023-1038. [潘振飞, 黄沛丰, 罗伊默, 等. 间接冷板与浸没式液冷在锂离子电池中的研究进展[J]. 储能科学与工程, 202 6, 15(3): 1023-1038.]

[7] Guo Yu, Qiu Yishu, Lei Bo, et al. Modeling and analysis of liquid-cooling thermal management of an in-house developed 100 kW/500 kWh energy storage container consisting of lithium-ion batteries retired from electric vehicles[J]. Applied Thermal Engineering, 2023, 232: 121111.

[8] Gan Haolin, Tian Jianan, Qiu Huiran, et al. Thermal performance of symmetrical double-spiral channel liquid cooling plate based battery thermal management for energy storage system[J]. Applied Thermal Engineering, 2025, 263: 125399.

[9] Lin Xiangwei, Shi Mingyu, Zhou Zhifu, et al. Multi-objective topology optimization design of liquid-based cooling plate for 280 Ah prismatic energy storage battery thermal management[J]. Energy Conversion and Management, 2025, 325: 119440.

[10] Chen Zhaoliang, Yang Shu, Pan Minqiang, et al. Experimental investigation on thermal management of lithium-ion battery with roll bond liquid cooling plate[J]. Applied Thermal Engineering, 2022, 206: 118106.

[11] Shuai Changjun. Design of liquid cooling container energy storage system[J]. Henan Science and Technology, 2022, 41(12): 91-94. [帅昌俊. 液冷集装箱式储能系统设计开发研究[J]. 河南科技, 2022, 41(12): 91-94.]

[12] Hu Shuntao, Lü Xinli, Li Yifei. Heat dissipation simulation and optimization of thermal management system for serpentine channel liquid cooling battery[J]. Chinese Journal of Power Sources, 2023, 47(11): 1414-1418. [胡顺涛, 吕心力, 李一飞. 蛇形通道液冷电池热管理系统散热仿真与优化[J]. 电源技术, 2023, 47(11): 1414 -1418.]

[13] Cao Xi, Shi Qianlei, Liu Qian, et al. Full-scale simulation of a 372 kW/372 kWh whole-cluster immersion cooling lithium-ion battery cluster and battery thermal management system design[J]. Case Studies in Thermal Engineering, 2024, 63: 105377.

[14] He Chuang, Zhao Qinxin, Liang Zhiyuan. Performance optimization of air-cooled lithium battery pack thermal management system with turbulence structure[J]. Journal of Zhengzhou University (Engineering Science), 2025, 46(1): 90-97. [何闯, 赵钦新, 梁志远. 具有扰流结构的风冷型锂电池包热管理系统优化[J]. 郑州大学学报(工学版), 2025, 46(1): 90-97.]

[15] Bernardi D, Pawlikowski E, Newman J. A general energy balance for battery systems[J]. Journal of the Electrochemical Society, 1985, 132(1): 5-12.

[16] Liu Shujun, Wang Yao, Liu Qi, et al. Thermal equalization design for the battery energy storage system (BESS) of a fully electric ship[J]. Energy, 2024, 312: 133611.

[17] Zhang Yansen, Zhang Weikuo, Kong Wenjun. Numerical and experimental study on thermal behavior of prismatic lithium-ion battery for large-capacity energy storage[J]. Journal of Energy Storage, 2024, 83: 110620.

[18] Lin Xiangwei, Zhou Zhifu, Li Mingxuan, et al. Exploration on the liquid-based energy storage battery system from system design, parametric optimization, and control strategy[J]. Renewable Energy, 2024, 237: 121904.

[19] Yang Chaoran, Liu Qian, Liu Mingyi, et al. Investigation of the immersion cooling system for 280Ah LiFePO4 batteries: effects of flow layouts and fluid types[J]. Case Studies in Thermal Engineering, 2024, 61: 104922.

[20] Zou Jinsheng, Li Wenjie, Wang Yuanbing, et al. Thermal design and optimization of liquid-cooling energy storage battery module[J]. Energy Engineering, 2025, 45(3): 28-35. [邹金生, 李文杰, 王元兵, 等. 液冷储能电池模组散热设计与优化[J]. 能源工程, 2025, 45( 3): 28-35.]

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备注/Memo

备注/Memo:
收稿日期:2026-04-16;修订日期:2026-05-16基金项目:国家自然科学基金资助项目(22578427) ;河南省重点研发专项(261111242000)作者简介:王定标(1967— ) ,男,浙江杭州人,郑州大学教授,博士,博士生导师,主要从事传热强化节能技术及先进装备研究,E-mail:wangdb@ zzu. edu. cn。通信作者:王光辉(1989— ) ,男,河南商丘人,郑州大学副教授,博士,主要从事先进装备强化及拓扑优化算法研究,Email:ghwang@ zzu. edu. cn。
更新日期/Last Update: 2026-06-03