基于热传递仿真的热电池激活阶段热特性

doi:10.12382/bgxb.2021.0271

摘要/Abstract

摘要： 热电池激活依靠内部热源熔化绝缘固态电解质到高离子电导率熔融态。基于多物理场耦合分析软件（COMSOL）建立某热电池二维模型，进行激活阶段热传递仿真研究。以自定义热源函数模拟烟火系统放热过程，设置温度探针在电堆中部第7组单体电池及临近组件中，计算得到热电池温度分布、单体电池温度曲线和电解质熔化相变。以固态电解质熔化连接正负极作为热电池激活标志，预测最短激活时间，并对2个热电池进行激活测试以验证预测结果。建立引燃条内置式热电池模型以研究引燃条位置对激活时间的影响。研究结果表明：电堆端部温度较高，利于补偿放电期间的热耗散，集流片具有抵御热冲击的作用，探针温度短时维持在560 ℃；热电池激活时间预测值约为45 ms，实测值为42 ms和47 ms，表明模型和预测方法具有较高精度；引燃条内置式热电池激活时间缩短为30 ms。

关键词: 热电池激活, 热传递仿真, 温度分布, 相变, 激活时间

Abstract: The activation of a thermal battery (TB) depends on the internal heat source to melt insulating solid electrolyte to highly ionic conductive melten state. A 2D model of a thermal battery is developed to simulate the heat transfer during TB activation based on multiphysics coupling software COMSOL.The heat releasing process of a pyrotechnic system is simulated with the user-defined heat source function. The temperature probes are set in the seventh unit cell and adjacent components at the center of TB stack. Temperature distribution, temperature curves of unit cell, and melting phase change are calculated.The time when the solid electrolyte melts enough to connect the cathodes and anodes is taken as the symbol of TB's activation to predict the shortest activation time. Two TBs are tested to verify the predicted results. Furthermore, an igniting tape built-in TB model is developed to study the influence of igniting tape's position on the activation time. The results show that the temperatures at the ends of TB stack are higher to compensate for heat dissipation during discharge. The current collectors can withstand thermal impact. The probes maintain at 560 ℃ in a short time. The predicted activation time is about 45 ms, the test activation times are 42 ms and 47 ms，indicating the model and prediction method are of high accuracy. The activation time of the built-in TB reduces to 30 ms.

Key words: thermalbatteryactivation, heattransfersimulation, temperaturedistribution, phasechange, activationtime

中图分类号:

TM911.16

陈恒帅，朱艳丽，李伟，白杰. 基于热传递仿真的热电池激活阶段热特性[J]. 兵工学报, 2022, 43(5): 1194-1200.

CHEN Hengshuai， ZHU Yanli， LI Wei， BAI Jie. Thermal Characteristics of Thermal Batteries during Activation Based on Heat Transfer Simulation[J]. Acta Armamentarii, 2022, 43(5): 1194-1200.

参考文献

［1］ GUIDOTTI R A，MASSET P.Thermally activated (“thermal”) battery technology: Part I: an overview[J].Journal of Power Sources，2006，161(2): 1443-1449.
[2］ SMITH K，WANG C Y.Power and thermal characterization of a lithium-ion battery pack for hybrid-electric vehicles[J].Journal of Power Sources，2006，160(1): 662-673.
[3］ CHO J H，IM C N，CHOI C H，et al. Thermal stability characteristics of high-power，large-capacity，reserve thermal batteries with pure Li and Li(Si) anodes[J]. Electrochimica Acta，2020，353: 136612.
[4］冉岭，万伟华，陈志江，等.热电池激活及放电全过程传热仿真分析[J].电源技术，2020，44(10): 1466-1468.
RAN L，WAN W H，CHEN Z J，et al. Simulation research on heat transfer of thermal battery during activation and discharge [J]. Chinese Journal of Power Sources，2020，44(10): 1466-1468. (in Chinese)
[5］王超，刘波，兰伟，等.基于ANSYS的热电池激活过程模拟研究[J].电源技术，2018，42(1): 68-70.
WANG C，LIU B，LAN W，et al. Simulation investigation on activation of thermal battery based on ANSYS[J].Chinese Journal of Power Sources，2018，42(1): 68-70. (in Chinese)
[6］ LI Q，SHAO Y Q，SHAO X D，et al. Activation process modeling and performance analysis of thermal batteries considering ignition time interval of heat pellets[J]. Energy，2021，219: 119631.
[7］ FREITAS G C S，PEIXOTO F C，VIANNA A S. Simulation of a thermal battery using Phoenics[J]. Journal of Power Sources，2008，179(1): 424-429.
[8］叶丹宏，姜义田，胡冉，等.一种热电池用高精度快速仿真技术[J].电源技术，2020，44(4): 592-594.
YE D H，JIANG Y T，HU R，et al. A kind of high-accurate and fast simulation technology for thermal battery[J]. Chinese Journal of Power Sources，2020，44(4):592-594. (in Chinese)
[9］ PIEKOS E S，GRILLET A，INGERSOLL D T，et al. Modeling of thermal battery initiation using level sets[C]∥Proceedings of the 45th Power Sources Conference. Las Vegas，NV，US: Curran Associates，Inc.， 2012.
[10］郭靖宇，岳光，吕佳镁，等.基于流体动力学的热压罐框架式模具温度场优化[J].兵工学报，2022，43(1): 233-240.
GUO J Y，YUE G，L J M，et al.Optimization of temperature field of autoclave frame mold based on fluid dynamics[J].Acta Armamentarii，2022，43(1): 233-240. (in Chinese)
[11］ SCHOEFFERT S.Thermal batteries modeling， self-discharge and self-heating[J].Journal of Power Sources，2005，142(1):361-369.
[12］ GUIDOTTI R A，ODINEK J，REINHARDT F W.Characterization of Fe/KClO₄ heat powders and pellets [J].Journal of Energetic Materials， 2006， 24(4): 271-305.
[13］ MASSET P，GUIDOTTI R A.Thermal activated (thermal) battery technology:Part II.Molten salt electrolytes[J].Journal of Power Sources，2007， 164(1):397-414.
[14］王超，刘建青，兰伟，等.热电池材料热物理特性参数的测试与分析[J].电源技术，2018，42(2): 237-238.
WANG C，LIU J Q，LAN W，et al. Test and analysis of thermo-physical property of thermal battery materials [J]. Chinese Journal of Power Sources，2018，42(2): 237-238. (in Chinese)
[15］王超，杨兆堂，兰伟，等.热电池激活过程开路电压数值仿真方法[J].电源技术，2018，42(5):697-698.
WANG C，YANG Z T，LAN W，et al.Numerical simulation method for open-circuit voltage of thermal battery in activation process[J].Chinese Journal of Power Sources，2018，42(5): 697-698. (in Chinese)

[1]	赵敏, 曲兆明，王庆国，周星, 陈亚洲. 场致绝缘-金属相变材料的脉冲响应测试方法[J]. 兵工学报, 2022, 43(2): 401-409.
[2]	张海军，聂建新，王领，王栋，郭学永，闫石. 端羟基聚醚推进剂慢速烤燃尺寸效应[J]. 兵工学报, 2021, 42(9): 1858-1866.
[3]	郑克勤，张庆明，龙仁荣，薛一江，龚自正，武强，张品亮，宋光明. 超高速撞击波阻抗梯度材料形成的碎片云相变特性[J]. 兵工学报, 2021, 42(4): 773-780.
[4]	周捷，智小琦，刘子德，王雪，王帅. 24-二硝基苯甲醚基熔铸炸药慢速烤燃过程传热特征分析[J]. 兵工学报, 2019, 40(6): 1154-1160.
[5]	杨文忠，丁立波，张合. 基于地磁计转数的引信化学电池相对激活时间测试方法研究[J]. 兵工学报, 2017, 38(4): 810-816.
[6]	刘超，石艺娜，秦承森，梁仙红. 多晶铁冲击相变的离散元方法研究[J]. 兵工学报, 2014, 35(7): 1009-1015.
[7]	谢卫红，贾风辉，李顺才. 机场保障装备防热红外探测隔热毯设计与实验研究[J]. 兵工学报, 2014, 35(1): 55-61.
[8]	王柏秋，王聪，黄海龙，董磊，张嘉钟. 半球头模型空化流场非定常特性的数值模拟[J]. 兵工学报, 2012, 33(9): 1124-1130.
[9]	贾其，吕绪良，荣先辉，何超，汤雪峰. 添加相变材料的混凝土路面红外伪装应用研究[J]. 兵工学报, 2011, 32(8): 975-980.
[10]	张兴华，唐志平，郑航. 弹头冲击形状记忆合金悬臂梁实验的数值模拟[J]. 兵工学报, 2010, 31(4): 491-498.
[11]	叶宏，江利锋. 导热增强型相变材料模拟钢板红外特征的优化设计[J]. 兵工学报, 2007, 28(6): 692-699.
[12]	吕舒眉，张拴勤，连长春，黄长庚. 相变材料红外特征模拟的理论和实验研究[J]. 兵工学报, 2007, 28(4): 463-466.
[13]	叶宏，张栓勤，庄双勇，杨泰蓉，王西耀. 相变材料模拟金属板热特性的理论设计与实验验证[J]. 兵工学报, 2006, 27(3): 489-493.
[14]	王扬，邓宗全，齐立涛. 火炮身管内由表面激光先硬化处理的实验研究[J]. 兵工学报, 2003, 24(4): 476-478.
[15]	李文，支文，朴英锡. 间隙杂质对Ti-AI合金相变的影响[J]. 兵工学报, 2000, 21(1): 38-41.