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Issue
Korean Journal of Chemical Engineering,
Vol.22, No.3, 406-411, 2005
Comparative Studies of a Single Cell and a Stack of Direct Methanol Fuel Cells
Lee S, Kim D, Lee J, Chung ST, Ha HY
Comparative studies have been conducted to observe the characteristics of a single cell and a stack of direct methanol fuel cells (DMFC) at ambient conditions. The maximum power density of a single cell was about 70 mW/cm2 at 2M methanol (CH3OH) of 3.75 cc/min and dry air of 250 cc/min at room temperature and atmospheric pressure. In a stack, on the other hand, the maximum power density of the stack was 85mW/cm2 which was about a 20% higher value. This could be attributed to higher internal temperature than that of the single cell: the temperature of single cell increased up to 35 ℃, while the highest temperature of the stack was 69 ℃. This is because the cell temperature in DMFC was autonomously increased by exothermal reaction such as chemical oxidation of CH3OH and oxygen reduction. The temperature was strongly dependent on the number of unit cells in a stack and the amount of electric load applied. In DMFC stacks, the performance of an individual cell showed uneven distribution when the electric load was increased and it was mostly influenced by different local concentration of reactants and non-uniform temperature.
Keywords: DMFC; Single Cell; Stack; Durability; Temperature Distribution
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[Cited By]
  1. Lue SJ, Shih TS, Wei TC, Korean Journal of Chemical Engineering, 23(3), 441, 2006
  2. Danilov V, Lim J, Moon I, Choi KH, Korean Journal of Chemical Engineering, 23(5), 753, 2006
  3. Kim KH, Yu JK, Lee HS, Choi JH, Noh SY, Yoon SK, Lee CS, Hwang TS, Rhee YW, Korean Journal of Chemical Engineering, 24(3), 518, 2007
  4. Joo JB, Kim YJ, Kim W, Kim ND, Kim P, Kim Y, Lee YW, Yi J, Korean Journal of Chemical Engineering, 25(3), 431, 2008
  5. Im SJ, Patel R, Shin SJ, Kim JH, Min BR, Korean Journal of Chemical Engineering, 25(4), 732, 2008
  6. Joo JB, Kim YJ, Kim W, Kim ND, Kim P, Kim Y, Yi J, Korean Journal of Chemical Engineering, 25(4), 770, 2008
  7. Jeon MK, Lee KR, Woo SI, Korean Journal of Chemical Engineering, 26(4), 1028, 2009
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