Modelling and simulation study on cooling system for proton exchange membrane fuel cell

被引:0
|
作者
Sahoo, Dillip Kumar [1 ]
Sri Ram, Gowtham [1 ]
prasath, Sriram [1 ]
机构
[1] School of Mechanical Engineering, Sathyabama Institute of Science and Technology, Chennai, India
来源
International Journal of Ambient Energy | 2024年 / 45卷 / 01期
关键词
In this paper; a cooling channel was incorporated in the fuel cell to analyse the effect of cooling on fuel cell performance. Four different types of coolant combinations; namely DI100 (100% Deionised water); PG10 (90% DI water + 10% Propylene Glycol); PG20 (80% DI Water + 20% Propylene Glycol); and PG30 (70% DI Water + 30% Propylene Glycol) are used to analyse the fuel cell performance. A computational fluid dynamics model relying on a finite volume technique was used to assess efficiency. Performance evaluation was described as system temperature; operational parameters; coolant; and cooling channel geometry. The PEM fuel cell performance was good at PG30 combination; especially at high operating temperatures. The obtained results specify that the fuel cell performance was good at 356k. A decline in fuel cell performance was observed at temperatures between 362 and 371 k; obtained with the PG10 and PG20 conditions. © 2023 Informa UK Limited; trading as Taylor & Francis Group;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
相关论文
共 50 条
  • [31] Research on Parasitic Power of Cooling Balance of Plant System for Proton Exchange Membrane Fuel Cell
    Chang, Guofeng
    Xie, Chengyu
    Cui, Xian
    Wei, Pengnan
    JOURNAL OF THERMAL SCIENCE AND ENGINEERING APPLICATIONS, 2023, 15 (04)
  • [32] Design of a novel multizone cooling system for performance improvement in proton exchange membrane fuel cell
    Liu, Zhangda
    Pei, Houchang
    Sun, Liangbo
    Wang, Beihai
    Xing, Lu
    Tu, Zhengkai
    Cai, Shanshan
    APPLIED THERMAL ENGINEERING, 2024, 257
  • [33] A proton exchange membrane fuel cell with an airflow cooling system: Dynamics, validation and nonlinear control
    Sankar, K.
    Aguan, Koushik
    Jana, Amiya K.
    ENERGY CONVERSION AND MANAGEMENT, 2019, 183 : 230 - 240
  • [34] Modelling and simulation of a proton exchange membrane (PEM) electrolyser cell
    Abdin, Z.
    Webb, C. J.
    Gray, E. MacA
    INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2015, 40 (39) : 13243 - 13257
  • [35] Proton exchange membrane fuel cell system model for automotive vehicle simulation and control
    Paganelli, G
    Guezennec, YG
    Rizzoni, G
    Moran, MJ
    JOURNAL OF ENERGY RESOURCES TECHNOLOGY-TRANSACTIONS OF THE ASME, 2002, 124 (01): : 20 - 27
  • [36] Performance Simulation of Proton Exchange Membrane Fuel Cell System Based on Fuzzy Logic
    Huang, Zhiwei
    Zhou, Junbo
    Cui, Yuanshuai
    2020 IEEE CONFERENCE ON TELECOMMUNICATIONS, OPTICS AND COMPUTER SCIENCE (TOCS), 2020, : 382 - 384
  • [37] Modeling and dynamic simulation of air supply system in proton exchange membrane fuel cell
    Zhang, Li-Yan
    Pan, Mu
    Quan, Shu-Hai
    Xitong Fangzhen Xuebao / Journal of System Simulation, 2008, 20 (04): : 850 - 854
  • [38] DIRECT CONNECTION OF A PROTON EXCHANGE MEMBRANE FUEL CELL TO A LOAD AND MODELLING
    Zerhouni, Fatima Zohra
    Telidjane, Mohamed
    REVUE ROUMAINE DES SCIENCES TECHNIQUES-SERIE ELECTROTECHNIQUE ET ENERGETIQUE, 2015, 60 (04): : 387 - 396
  • [39] Optimization study of purge cycle in proton exchange membrane fuel cell system
    Nikiforow, K.
    Karimaki, H.
    Keranen, T. M.
    Ihonen, J.
    JOURNAL OF POWER SOURCES, 2013, 238 : 336 - 344
  • [40] Experimental Modelling of Proton Exchange Membrane Fuel Cell Voltage Losses
    Ondrejicka, Kristian
    Capkova, Romana
    Minar, Martin
    Huba, Mikulas
    PROCEEDINGS OF THE 2020 30TH INTERNATIONAL CONFERENCE CYBERNETICS & INFORMATICS (K&I '20), 2020,
12345