Analysis on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell When Operated in High Temperature Range 被引量：5

Analysis on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell When Operated in High Temperature Range

下载PDF

导出

摘要 This study is to understand the impact of operating condition, especially initial operation temperature （Tini） which is set in high temperature range, on the temperature profile of the interface between PEM （polymer electrolyte membrane） and catalyst layer at the cathode （i.e., the reaction surface） in a single PEFC （polymer electrolyte fuel cell）. A 1D multi-plate heat transfer model based on the temperature data of separator measured using thermograph in a power generation experiment was developed to evaluate the reaction surface temperature （Treact）. This study investigated the effects of flow rate, relative humidity and type of supply gas as well as Tini on the temperature distribution on reaction surface. The results obtained in 02 supply case show that, the temperature rise at the segments near the outlet of cell decreases with increasing Tini irrespective of relative humidity of supply gas （RH）, while it is not seen in air supply case. Regarding the segments except near the outlet in 02 supply case, Treact - Tini increases with increasing Tini for 40% RH. The temperature distribution on reaction surface in 02 supply case is wider with increasing Tini as well as decreasing RH, though that in air supply case is relatively even.

作者 Akira Nishimura Kotaro Osada Takuro Tsunoda Masato Yoshimura Masafumi Hirota Eric Hu

机构地区 Division of Mechanical Engineering School of Mechanical Engineering

出处《Journal of Energy and Power Engineering》 2016年第8期453-464,共12页 能源与动力工程（美国大卫英文）

关键词 PEFC heat transfer model temperature distribution high temperature operation. 聚合物电解质燃料电池表面温度分布单电池聚合物电解质膜 Tini 空气供应高温相对湿度

分类号 TM911.4 [电气工程—电力电子与电力传动] U463.341 [机械工程—车辆工程]

引文网络
相关文献

参考文献19

1Weber, A. Z., Darling, R. M., and Newman, J. 2004. "Modeling Two-Phase Behavior in PEFCs." Journal of Electrochemical Society 151 (10): A 1715-27.
2Wang, M., Guo, H., and Ma, C. 2006. "Temperature Distribution on the MEA Surface of a PEMFC with Serpentine Channel Flow Bed." Journal of Power Sources 157 (1): 181-7.
3Ito, K. 2008. "Temperature Distribution Measurement in Through-Plane Direction for PEFC." Japan Society of Mechanical Engineers 111 (1079): 42-4.
4Tsuji, K. 2008. "Domestic Fuel Cell Co-generation System Entering Real Commercial Stage." Hydrogen Energy System 33 (3): 93-6.
5Zhang, G., Shen, S., Guo, L., and Liu, H. 2012. "Dynamic Characteristics of Local Current Densities and Temperatures in Proton Exchange Membrane Fuel Cells during Reactant Starvations." International Journal Hydrogen Energy 37 (2): 1884-92.
6Lee, C. Y., Fan, W. Y., and Chang, C. P. 2011. "A Novel Method for In-situ Monitoring of Local Voltage, Temperature and Humidity Distributions in Fuel Cell Using Flexible Multi-functional Micro Sensors." Sensors 11 (2): 1418-32.
7Nishimura, A., Shibuya, K., Morimoto, A., Tanaka, S., Hirota, M., Nakamura, Y., Kojima, M., Narita, M., and Hu, E. 2012. "Dominant Factor and Mechanism of Coupling Phenomena in Single Cell of Polymer Electrolyte Fuel Cell." Applied Energy 90 (1): 73-9.
8Nishimura, A., Iio, K., Baba, M., Yamauchi, T., Hirota, M., and Hu, E. 2014. "Modeling of Heat Transfer in Single Cell of Polymer Electrolyte Fuel Cell by Means of Temperature Data Measured by Thermograph." Journal of Chemical Engineering of Japan 47 (7): 521-9.
9Nishimura, A., Fukuoka, T., Baba, M., Hirota, M., and Hu, E. 2015. "Clarification on Temperature Distribution in Single Cell of Polymer Electrolyte Fuel Cell under Different Operation Conditions by Means of 1D Multi-plate Heat-Transfer Model." Journal of Chemical Engineering of Japan 48 (10): 862-71.
10Khandelwal, M., and Mench, M. M. 2006. "Direct Measuremem of Through-Plane Thermal Conductivity and Contact Resistance in Fuel Cell Materials." Journal of Power Sources 161 (2): 1106-15.

同被引文献5

1Akira Nishimura,Kanji Patoriki Zamami,Masato Yoshimura,Masafumi Hirota,Mohan Lal Kolhe.Numerical Analysis of Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell when Operated in Elevated Temperature Range[J].Journal of Energy and Power Engineering,2017,11(6):393-408. 被引量：4
2Akira Nishimura,Masato Yoshimura,Satoru Kamiya,Masafumi Hirota,Eric Hu.Impact of Relative Humidity of Supply Gas on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell When Operated at High Temperature[J].Journal of Energy and Power Engineering,2017,11(11):706-718. 被引量：2
3Akira Nishimura,Yusuke Sato,Masato Yoshimura,Satoru Kamiya,Masafumi Hirota.Impact of Thickness of Polymer Electrolyte Membrane on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell Operated at High Temperature[J].Journal of Energy and Power Engineering,2018,12(2):80-92. 被引量：4
4Akira Nishimura,Yusuke Sato,Satoru Kamiya,Tatsuya Okado,Kouhei Yamamoto,Masafumi Hirota,Eric Hu.Impact of Thickness of Polymer Electrolyte Membrane and Gas Diffusion Layer on Temperature Distributions in Polymer Electrolyte Fuel Cell Operated at Temperature around 90℃[J].Journal of Energy and Power Engineering,2019,13(3):97-115. 被引量：2
5Akira Nishimura,Nozomu Kono,Kyohei Toyoda,Yuya Kojima,Mohan Lal Kolhe.Impact Analysis of MPL on a PEFC Cell’s Temperature Distribution with Thin PEM and GDL for Operating at Higher Temperature than Usual[J].Journal of Energy and Power Engineering,2021,15(2):39-51. 被引量：1

引证文献5

1Akira Nishimura,Yusuke Sato,Masato Yoshimura,Satoru Kamiya,Masafumi Hirota.Impact of Thickness of Polymer Electrolyte Membrane on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell Operated at High Temperature[J].Journal of Energy and Power Engineering,2018,12(2):80-92. 被引量：4
2Akira Nishimura,Yusuke Sato,Satoru Kamiya,Tatsuya Okado,Kouhei Yamamoto,Masafumi Hirota,Eric Hu.Impact of Thickness of Polymer Electrolyte Membrane and Gas Diffusion Layer on Temperature Distributions in Polymer Electrolyte Fuel Cell Operated at Temperature around 90℃[J].Journal of Energy and Power Engineering,2019,13(3):97-115. 被引量：2
3Akira Nishimura,Hiroya Fukuoka,Kohei Yamamoto,Tatsuya Okado,Yuya Kojima,Masafumi Hirotaand,Mohan Lal Kolhe.Numerical Analysis of Temperature Distributions in Single Cell of PEFC by Heat Transfer Model Considering Vapor Transfer[J].Journal of Energy and Power Engineering,2020,14(1):1-15.
4Akira Nishimura,Nozomu Kono,Kyohei Toyoda,Yuya Kojima,Mohan Lal Kolhe.Impact Analysis of MPL on a PEFC Cell’s Temperature Distribution with Thin PEM and GDL for Operating at Higher Temperature than Usual[J].Journal of Energy and Power Engineering,2021,15(2):39-51. 被引量：1
5Akira Nishimura,Daiki Mishima,Nozomu Kono,Kyohei Toyoda,Mohan Lal Kolhe.Impact of Separator Thickness on Temperature Distribution in Single Polymer Electrolyte Fuel Cell Based on 1D Heat Transfer[J].Energy and Power Engineering,2022,14(7):248-273.

二级引证文献4

1Akira Nishimura,Yusuke Sato,Satoru Kamiya,Tatsuya Okado,Kouhei Yamamoto,Masafumi Hirota,Eric Hu.Impact of Thickness of Polymer Electrolyte Membrane and Gas Diffusion Layer on Temperature Distributions in Polymer Electrolyte Fuel Cell Operated at Temperature around 90℃[J].Journal of Energy and Power Engineering,2019,13(3):97-115. 被引量：2
2Akira Nishimura,Hiroya Fukuoka,Kohei Yamamoto,Tatsuya Okado,Yuya Kojima,Masafumi Hirotaand,Mohan Lal Kolhe.Numerical Analysis of Temperature Distributions in Single Cell of PEFC by Heat Transfer Model Considering Vapor Transfer[J].Journal of Energy and Power Engineering,2020,14(1):1-15.
3Akira Nishimura,Nozomu Kono,Kyohei Toyoda,Yuya Kojima,Mohan Lal Kolhe.Impact Analysis of MPL on a PEFC Cell’s Temperature Distribution with Thin PEM and GDL for Operating at Higher Temperature than Usual[J].Journal of Energy and Power Engineering,2021,15(2):39-51. 被引量：1
4Akira Nishimura,Daiki Mishima,Nozomu Kono,Kyohei Toyoda,Mohan Lal Kolhe.Impact of Separator Thickness on Temperature Distribution in Single Polymer Electrolyte Fuel Cell Based on 1D Heat Transfer[J].Energy and Power Engineering,2022,14(7):248-273.

1Akira Nishimura,Masashi Baba,Kotaro Osada,Takenori Fukuoka,MasafumiHirota,Eric Hu.Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell Simulated by an 1D Multi-plate Heat-Transfer Model and a 3D Numerical Simulation Model[J].Journal of Energy and Power Engineering,2015,9(8):687-704.
2梅报春,梅欣丽.基于TINI的电力监控互联系统[J].电子元器件应用,2004,6(8):53-55.
3卓振星.拖拉机功率下降的诊断与排除[J].福建农机,2009(2):39-40. 被引量：1
4郑凯军,孙小立.拖拉机节油措施[J].农村科技,2008(6):94-94.
5高小芹.利用大用户自有宽带网络实现电能监测[J].电力信息化,2006,4(12):46-49.
6赵思臣,李龙,王奔,韩明,贾俊波.空冷型质子交换膜燃料电池实验研究[J].电源技术,2015,39(1):65-67. 被引量：4
7杨祥,丁岳伟,陈尚松.嵌入式网站家庭测控系统开发[J].电子测量与仪器学报,2004,18(z1):613-616.
8汪茂海,郭航,马重芳,刘璿,俞坚,王朝阳.质子交换膜燃料电池表面温度分布的测量[J].电源技术,2004,28(12):764-766. 被引量：6
9惠怀兵,孟仙雅,冯修成,陈果.电池结构对锂离子电池功率性能影响[J].电池工业,2014,19(5):297-299. 被引量：3
10正确的使用方法可以让发动机更“长寿”[J].汽车零部件,2013(5):77-77.

Journal of Energy and Power Engineering

2016年第8期

浏览历史

内容加载中请稍等...

Analysis on Temperature Distributions in Single Cell of Polymer Electrolyte Fuel Cell When Operated in High Temperature Range 被引量：5

参考文献19

同被引文献5

引证文献5

二级引证文献4

相关作者

相关机构

相关主题

浏览历史