Akademik Veri Yönetim Sistemi
Heat Transfer Research, cilt.53, sa.2, ss.29-44, 2022 (SCI-Expanded)
In the present study, the main purpose is to design flow channels with less pressure drop and higher performance
compared to single serpentine flow channels which are found in the literature for PEM fuel cells. Within the scope of
the present study, a numerical and experimental research was conducted on the design of the flow channels on bipolar
plates. The fuel cell with a serpentine flow field was experimentally tested under conditions of 70°C temperature, 1
atm pressure, 100% humidification, and 0.25 L/min anode/cathode flow rate, and analyzed numerically. This way, a
numerical model verified with experimental data was obtained. Four models (Models 1–4) with unique flow fields were
designed and numerically analyzed to compare with the verified numerical model. The flow field percentages (channel
to rib ratio) of the 5 models (1 serpentine-type model + 4 new models) designed were fixed at a value of approximately
55.4%. For all designs, the channel width was set to 1.5 mm and the channel depth was set to 1 mm. Results indicate
that the experimental data obtained were in accordance with the numerical results with an error margin of 5.3%. Based
on the numerical analysis results at 0.6 V, current density increased by 23.9% in Model 1, 26.9% in Model 2, and by
13.8% in Model 3 compared to the reference model while a 12% decrease was observed in Model 4.