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Vol.55, No.5, 335 ~ 342, 2017
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| Title |
| Effects of the Air Flow Rate and Electrolyte Thickness on the Durability of Yttria-doped Barium Cerate (BCY)-based Solid Oxide Fuel Cells |
| 배선영 Seon Yeong Bae , 박미영 Mi Young Park , 이종규 Jong Gyu Lee , 임형태 Hyung-tae Lim |
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| Abstract |
| Anode-supported yttria-doped barium cerate (BCY) electrolyte cells are fabricated and durability tests are conducted as a function of the current density (cell voltage sign), air flow rate, and BCY electrolyte thickness. As the air flow rate increases and the current density decreases (from negative to positive cell voltage), the cell voltage drop rate is reduced during the constant current test. The thick (18 μm) electrolyte cell exhibits relatively stable performance in comparison with the thin (10 μm) electrolyte cell. Electrolyte/electrode delamination is not observed on the cells, even after the negative voltage operation, and this is attributed to sufficient electronic conduction inside the BCY electrolyte. Thus, the present work indicates that the durability of BCY-based cells can be improved with optimization of the air utilization and electrolyte thickness. †(Received September 20, 2016; Accepted November 18, 2016) |
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| Key Words |
| solid oxide fuel cell, proton conductor, barium cerate, degradation mechanism |
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