Please wait a minute...
浙江大学学报(工学版)
Journal of ZheJiang University (Engineering Science)  2025, Vol. 59 Issue (11): 2293-2299    DOI: 10.3785/j.issn.1008-973X.2025.11.008
    
Experiment of heat generation behavior of automotive power aluminum-air fuel battery
Xiaodan TANG1(),Lei SHENG2,*(),Zhendong ZHANG2
1. School of Intelligent Manufacturing Engineering, Shanghai Vocational College of Science and Technology, Shanghai 201800, China
2. School of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
Download: HTML     PDF(1868KB) HTML
Export: BibTeX | EndNote (RIS)      

Abstract  

An in-situ thermal characterization theoretical model and method specifically designed for this battery type was proposed aiming at the characterization of heat-generating behaviors in aluminum-air fuel cells for automotive power applications. The influence mechanisms of operating temperature, electrolyte concentration, and current density on the battery's temperature rise during discharge, heat loss, heat generation rate, and discharge efficiency were analyzed. Results show that the aluminum-air battery's temperature-rise amplitude, heat loss, and heat generation rate increase with decreasing operating temperature and increasing electrolyte concentration. The battery’s heat generation rate gradually decreases over the discharge duration, while the discharge efficiency improves with increasing operating temperature and current density. Electrolyte concentration significantly impacts the battery’s discharge efficiency. The operational efficiency approaches 78% at a concentration of 3.0 mol/L. Efficiencies fall below 60% at concentrations of both 1.0 mol/L and 6.0 mol/L, indicating that excessively high or low concentrations detrimentally affect discharge efficiency.

Key wordsaluminum-air fuel battery      heat-generating behavior      discharge efficiency     
Received: 27 February 2025      Published: 30 October 2025
CLC:  TK124  
Fund:  国家自然科学基金资助项目(52472381);国家自然科学青年基金资助项目(52206276).
Corresponding Authors: Lei SHENG     E-mail: 2326147108@qq.com;shenglei369@163.com
Service
E-mail this article
Add to my bookshelf
Add to citation manager
E-mail Alert
RSS
Articles by authors
Xiaodan TANG
Lei SHENG
Zhendong ZHANG
Cite this article:

Xiaodan TANG,Lei SHENG,Zhendong ZHANG. Experiment of heat generation behavior of automotive power aluminum-air fuel battery. Journal of ZheJiang University (Engineering Science), 2025, 59(11): 2293-2299.

URL:

https://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2025.11.008     OR     https://www.zjujournals.com/eng/Y2025/V59/I11/2293


车用动力铝-空气燃料电池的产热行为实验

针对车用动力铝-空气燃料电池的产热行为表征问题,提出面向该型电池的原位热表征理论模型和方法. 研究工作温度、电解液浓度和电流密度对电池放电升温、热量损失、产热率和放电效率的影响机制. 结果表明,铝-空气电池的升温幅度、热损和发热率随着工作温度的降低和电解液浓度的增大而增大. 电池的发热率随着放电时间的增加而逐渐降低,放电效率随着工作温度、电流密度的增大而提升. 电解液浓度对电池的放电效率影响较大,当浓度为3.0 mol/L时电池的工作效率接近78%,当浓度为1.0和6.0 mol/L时工作效率低于60%,浓度过高和过低都会影响电池的放电效率.


关键词: 铝-空气燃料电池,  产热行为,  放电效率 
Fig.1 Working principle and heat generation analysis of aluminum-air battery
Fig.2 Experimental system of aluminum-air battery
Fig.3 Temperature change and surface heat flux density of aluminum-air battery under different ambient temperature
Fig.4 Temperature change and surface heat flux density of aluminum-air battery under different electrolyte concentration
Fig.5 Temperature change and surface heat flux density of aluminum-air battery under different current density
Fig.6 Heat generation of aluminum-air battery
Fig.7 Operating voltage of aluminum-air battery
Fig.8 Discharge efficiency of aluminum-air battery
[1]   SHENG L, FU L, ZHANG Z, et al Method to characterize thermal performances of an aluminum-air battery[J]. Energy, 2024, 301: 131757
doi: 10.1016/j.energy.2024.131757
[2]   朱奎, 韩基泰, 李昊 铝空气电池固态和准固态电解质研究进展[J]. 电池, 2023, 53 (5): 568- 571
ZHU Kui, HAN Jitai, LI Hao Research progress on solid and quasi solid electrolytes for aluminum-air battery[J]. Battery, 2023, 53 (5): 568- 571
[3]   沈虹宁, 方奕栋, 胡天恩, 等 低温下电解液浓度对铝-空气电池的影响[J]. 电池, 2019, 49 (6): 470- 473
SHEN Hongning, FANG Yidong, HU Tian’en, et al Influence of electrolyte concentration on aluminum-air battery under lower temperatures[J]. Battery, 2019, 49 (6): 470- 473
[4]   HU T, LI K, FANG Y, et al Experimental research on temperature rise and electric characteristics of aluminum air battery under open-circuit condition for new energy vehicle[J]. International Journal of Energy Research, 2019, 43: 1099- 1110
doi: 10.1002/er.4329
[5]   WEN H, LIU Z, QIAO J, et al Ultrahigh voltage and energy density aluminum-air battery based on aqueous alkaline-acid hybrid electrolyte[J]. International Journal of Energy Research, 2020, 44 (13): 1- 10
[6]   吴佳佳, 吴广泽, 李萱苡, 等 铝空气电池的热特性及其研究方法[J]. 中国金属通报, 2021, 1 (6): 114- 115
WU Jiajia, WU Guangze, LI Xuanyi, et al Thermal characteristics and research methods of aluminum air batteries[J]. China Metal Bulletin, 2021, 1 (6): 114- 115
doi: 10.3969/j.issn.1672-1667.2021.06.056
[7]   刘春梅, 顾家明, 赖高强 棉布基铝空气电池性能研究[J]. 河南科技大学学报: 自然科学版, 2024, 45 (5): 32- 40
LIU Chunmei, GU Jiaming, LAI Gaoqiang Study on the performance of cotton based aluminum air battery[J]. Journal of Henan University of Science and Technology: Natural Science Edition, 2024, 45 (5): 32- 40
[8]   CHEN B, LENG D, XUAN J, et al A high specific capacity membraneless aluminum-air cell operated with an inorganic/organic hybrid electrolyte[J]. Journal of Power Sources, 2016, 336 (1): 19- 26
[9]   张清扬. 铝空气电池电解液循环及热管理系统研究[D]. 哈尔滨: 哈尔滨工业大学, 2020.
ZHANG Qingyang. Research on electrolyte circulation and thermal management system of aluminum air battery [D]. Harbin: Harbin Institute of Technology, 2020.
[10]   REVEL R, AUDICHON T, GONZALEZ S Non-aqueous aluminum–air battery based on ionic liquid electrolyte[J]. Journal of Power Sources, 2014, 272 (1): 415- 421
[11]   DOCHE M, NOVEL-CATTIN F, DURAND R, et al Characterization of different grades of aluminum anodes for aluminum/air batteries[J]. Journal of Power Sources, 1997, 65 (1/2): 197- 205
[12]   陈云超, 齐敏杰, 李焙, 等. 一种铝空气电池散热结构: CN202211386507.6 [P]. 2023-02-28.
[13]   张昭. 全固态聚合物铝空气电池研究 [D]. 长春: 吉林大学, 2014.
ZHANG Zhao. Research on all solid-state polymer aluminum air battery [D]. Changchun: Jilin University, 2014.
[14]   RANI B, KUMAR J, SAINI P, et al Aluminum-air batteries: current advances and promises with future directions[J]. RSC Advances, 2024, 17 (25): 17628- 17663
[15]   LIU Y, SUN Q, LI W, et al A comprehensive review on recent progress in aluminum-air batteries[J]. Green Energy and Environment, 2017, 2 (3): 246- 277
doi: 10.1016/j.gee.2017.06.006
[1] Dandan XU,Enke JIANG,Jun ZHU,Yu GUO. Experimental investigation on dynamics and mixing of flexible biomass particles[J]. Journal of ZheJiang University (Engineering Science), 2025, 59(11): 2285-2292.
[2] MOU Lin-wei, ZHANG Yu-hong, LI Jia-qi, ZHANG Jia-yi, JIANG Ping, FAN Li-wu. Surface wicking effect on boiling heat transfer during quenching[J]. Journal of ZheJiang University (Engineering Science), 2018, 52(5): 960-965.
[3] YANG Ji-hu, SUN Zhi-jian, YUAN Rui-feng, HUANG Hao, CHEN Tian-yu, HU Ya-cai. Study on heat transfer and ash deposit characteristics of fluoroplastic steel air-preheater in power plant[J]. Journal of ZheJiang University (Engineering Science), 2018, 52(3): 577-583.
[4] DAI Chao, JI Xian-bing, ZHOU Dong-dong, WANG Ye, XU Jin-liang. Behavioral characteristics of droplet collision to different wettability surfaces[J]. Journal of ZheJiang University (Engineering Science), 2018, 52(1): 36-42.
[5] ZHONG Xun, SHU Xiao-Chi, TUN Dun, JIANG Beng-Zao. Experimental investigation on alumina nanofluids in vehicle heat exchanger[J]. Journal of ZheJiang University (Engineering Science), 2010, 44(4): 761-764.
[6] LI Guan-Qiu, LI Wei, ZHANG Zheng-Jiang, ZHANG Wei, XU Zhi-Meng. Modeling particulate fouling in internal helicalrib tubes by VonKarman analogy[J]. Journal of ZheJiang University (Engineering Science), 2010, 44(3): 494-498.