In-Situ Measurement of In-Plane Temperature Distribution in a Single-Cell Polymer Electrolyte Fuel Cell Using Thermograph 1st Report: Impacts of Gas Flow Rate at Inlet and Gas Channel Pitch of Separator on In-Plane Temperature Distribution and Power Generation Performance

• Published in: Journal of Environment and Engineering Vol. 6; no. 1; pp. 1 - 16
• Main Authors: NISHIMURA, Akira, SHIBUYA, Kenichi, MORIMOTO, Atsushi, TANAKA, Shigeki, HIROTA, Masafumi, NAKAMURA, Yoshihiro, KOJIMA, Masashi, NARITA, Masahiko
• Format: Journal Article
• Language: English
• Published: The Japan Society of Mechanical Engineers 2011
• Subjects: Energy Conversion; Gas Channel Pitch; Gas Flow Rate; Heat Transfer; In Plane Temperature Distribution; In Situ Measurement; PEFC; Thermograph
• ISSN: 1880-988X; 1880-988X
• DOI: 10.1299/jee.6.1

To clarify the mechanism of combined phenomena of heat, mass and electric charge transfers in a single-cell polymer electrolyte fuel cell (PEFC), it is necessary to measure in-plane temperature distribution of a single-cell PEFC when it is run, i.e., generating power. The measurement by thermograph assists to investigate the influence of gas flow rate at inlet and gas channel pitch of separator on in-plane temperature distribution and power generation performance. As a result, the higher temperature region is observed near the outlet of cell when the excess ratio of gas flow is set due to the convective heat transfer by excess oxygen flow in gas channel at the cathode. When the gas flow is set at stoichiometric, in-plane temperature distribution becomes even and high power generation performance can be achieved. The other observation is that the total voltage is increased and temperature in observation area is dropped with decreasing gas channel pitch of separator irrespective of gas flow rate.