화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Chemical Engineering, Vol.33, No.10, 2891-2897, October, 2016
DOI10.1007/s11814-016-0144-0  Export Citation
Thermo-catalytic decomposition of waste lubricating oil over carbon catalyst
Yongjae Lee, Jong Tak Jang, Jong Wook Bae, Ki June Yoon, and Gui Young Han
  • School of Chemical Engineering, Sungkyunkwan University, Suwon 16419, Korea
E-mail:
The thermo-catalytic decomposition of waste lubricating oil over a carbon catalyst was investigated in an I.D. of 14.5mm and length of 640mm quartz tube reactor. The carbon catalysts were activated carbon and rubber grade carbon blacks. The decomposition products of waste lubricating oil were hydrogen, methane, and ethylene in a gas phase, carbon in a solid phase and naphthalene in a liquid phase occurring within the temperature ranges of 700 ℃-850 ℃. The thermo-catalytic decomposition showed higher hydrogen yield and lower methane yield than that of a non-catalytic decomposition. The carbon black catalyst showed higher hydrogen yield than the activated carbon catalyst and maintained constant catalytic activity for hydrogen production, while activated carbon catalyst showed a deactivation in catalytic activity for hydrogen production. As the operating temperature increased from 700 ℃ to 800 ℃, the hydrogen yield increased and was particularly higher with carbon black catalyst than activated carbon. As a result, carbon black catalyst was found to be an effective catalyst for the decomposition of waste lubricating oil into valuable chemicals such as hydrogen and methane.
Keywords:Catalytic Decomposition;Waste Lubricating Oil;Carbon Black;Hydrogen
  1. Kogan A, Int. J. Hydrog. Energy, 23(2), 89 (1998)
  2. Cho DL, Kim HN, Lee M, Cho E, Korean J. Chem. Eng., 32(12), 2519 (2015)
  3. Kwak JH, Han GY, Bae JW, Yoon KJ, Korean J. Chem. Eng., 31(6), 961 (2014)
  4. Shah N, Panjala D, Huffman GP, Energy Fuels, 15(6), 1528 (2001)
  5. Lee EK, Lee SY, Han GY, Lee BK, Lee TJ, Jun JH, Yoon KJ, Carbon, 42, 2641 (2004)
  6. Muradov N, Catal. Commun., 2, 89 (2001)
  7. Shah N, Wang YG, Panjala D, Huffman GP, Energy Fuels, 18(3), 727 (2004)
  8. Muradov N, J. Power Sources, 118(1), 320 (2003)
  9. Wang Y, Shah N, Panjala D, Huffman GP, Catal. Today, 99(3), 359 (2005)
  10. Takenaka S, Kawashima K, Matsune H, Kishida M, Appl. Catal. A: Gen., 321, 165 (2007)
  11. Permsubscul A, Vitidsant T, Damronglerd S, Korean J. Chem. Eng., 24(1), 37 (2007)
  12. Lazaro M, Suelves I, Moliner R, Environ. Sci. Technol., 39, 6871 (2005)
  13. Kim MH, Lee EK, Jun JH, Kong SJ, Han GY, Lee BK, Lee TJ, Yoon KJ, Int. J. Hydrog. Energy, 29(2), 187 (2004)
  14. Lee SY, Ryu BH, Han GY, Lee TJ, Yoon KJ, Carbon, 46, 1978 (2008)
  15. Lee SY, Kim MS, Kwak JH, Han GY, Park JH, Lee TJ, Yoon KJ, Carbon, 48, 2030 (2010)
  16. Yun YH, Lee SC, Jang JT, Yoon KJ, Bae JW, Han GY, Int. J. Hydrog. Energy, 39(27), 14800 (2014)
  17. Yoon SH, Park NK, Lee TJ, Yoon KJ, Han GY, Catal. Today, 146, 202 (2009)
  18. Lee SY, Kwak JH, Han GY, Lee TJ, Yoon KJ, Carbon, 46, 342 (2008)
  19. Kim SS, Kim SH, Fuel, 79, 1943 (2000)
  20. Wojciechowski BW, Corma A, Catalytic cracking, Marcel Dekker, New York (1986).
  21. Muradov N, Thermocatalytic CO2-free production of hydrogen from hydrocarbon fuels, Department of Energy hydrogen program review, NREL/CP-570-30535 (2001).
  22. Plehiers PM, Froment GF, Oil Gas J., 85(33), 41 (1987)