화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Journal of Industrial and Engineering Chemistry, Vol.12, No.1, 149-155, January, 2006
Export Citation
Cogeneration of a Synthesis Gas and Electricity Through Internal Reforming of Methane by Carbon Dioxide in a Solid Oxide Fuel Cell System
Dong Ju Moon, Jong-Min Park, Jung Shik Kang, Kye Sang Yoo, and Suk-In Hong1
  • Reaction Media Research Center, Korea Institute of Science & Technology, Seoul, Korea
  • 1Department of Chemical & Biological Engineering, Korea University, Seoul 136-709, Korea
E-mail:
The electrocatalytic internal reforming of CH4 by CO2 was carried out in a solid oxide fuel cell (SOFC) system to produce a syngas and electricity. To develop a high-performance anode catalyst for the electrocatalytic internal reforming, the anode catalyst was investigated in the reforming of CH4 by CO2. It was found that the NiO-YSZ-CeO2 catalyst showed a higher activity htan did the NiO-YSZ-MgO catalyst in the temperature range 650~850 ℃. The CO2 conversion was 100% above 800 ℃ and the yield of H2 was 50%. The reaction rates of CO2 and CH4 under the closed-circuit conditions were moere stable than those of the open circuit. The anode catalyst prepared with CeO2 showed particularly significant electrochemical performances. The performance of electrochemical reforming is significantly increased by improving the contact between the cell and the current collector. The open circuit voltage (OCV) over a single cell (NIO-YSZ-CeO2 lYSZl (La,Sr)MnO3) was 1.1 V, a power density of 54 mW/cm2 was obtained at a current density of 100 mA/cm2.
Keywords:SOFC;CH4;CO2;Internal reforming;NiO-YSZ based catalyst
  1. Claridge JB, York APE, Brungs AJ, Marquez-Alvarez C, Sloan J, Tsang SC, Green MLH, J. Catal., 180(1), 85 (1998)
  2. Rostrup-Nielsen JR, Catal. Today, 71(3-4), 243 (2002)
  3. Seo HJ, Yu EY, J. Ind. Eng. Chem., 11(5), 681 (2005)
  4. Ruckenstein E, Wang HY, J. Catal., 205(2), 289 (2002)
  5. Erdohelyi A, Cserenyi J, Solymosi F, J. Catal., 141, 287 (1993)
  6. Qin D, Lapszewicz J, Catal. Today, 21, 551 (1994)
  7. Mark MF, Maier WF, J. Catal., 164(1), 122 (1996)
  8. Wang SB, Lu GQ, Energy Fuels, 12(2), 248 (1998)
  9. Xu Z, Li YM, Zhang JY, Chang L, Zhou RQ, Duan ZT, Appl. Catal. A: Gen., 210(1-2), 45 (2001)
  10. Kroll VC, Swaan HM, Mirodatos C, J. Catal., 161(1), 409 (1996)
  11. Seo HJ, Yu EY, J. Ind. Eng. Chem., 3(2), 85 (1997)
  12. Roh HS, Jun KW, Park SE, J. Ind. Eng. Chem., 9(3), 261 (2003)
  13. Bradford MCJ, Vannice MA, Catal. Today, 50, 87 (1990)
  14. Tang SB, Qiu FL, Lu SJ, Catal. Today, 24(3), 253 (1995)
  15. Park SD, Vohs JM, Gorte RJ, Nature, 404, 265 (2002)
  16. Ishihara T, Yamada T, Akbay T, Takita Y, Chem. Eng. Sci., 54(10), 1535 (1999)
  17. Moon DJ, Ryu JW, Catal. Today, 87(1-4), 255 (2003)
  18. Moon DJ, Ryu JW, Lee SD, Stud. Surf. Sci. Catal., 153, 149 (2004)
  19. Moon DJ, Ryu JW, Kang DM, Lee BK, Ahn BS, Stud. Surf. Sci. Catal., 153, 193 (2004)
  20. Yoo JY, Moon DJ, Park JM, Lee SD, Nam SW, Lee DJ, Theor. Appl. Chem. Eng., 9, 1138 (2003)
  21. Moon DJ, Ryu JW, Park JM, Lee BG, Lee SD, US Patent No. 10830225 (2004)
  22. Moon DJ, Ryu JW, Kim TY, Park JM, Kang DM, Lee SD, Lee BG, Korea Patent 2003-0074934 (2003)
  23. Moon DJ, Ryu JW, Nam SW, Ahn BS, Korea Patent 0003564 (2004)