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Issue
Korean Journal of Chemical Engineering,
Vol.33, No.9, 2567-2574, 2016
Parametric study of pyrolysis and steam gasification of rice straw in presence of K2CO3
Baloch HA, Yang T, Sun H, Li J, Nizamuddin S, Li R, Kou Z, Sun Y, Bhutto AW
A parametric study of pyrolysis and steam gasification of rice straw (RS) was performed to investigate the effect of the presence of K2CO3 on the behavior of gas evolution, gas component distribution, pyrolysis/gasification reactivity, the quality and volume of synthetic gas. During pyrolysis, with the increase in K2CO3 content in RS (i) the instantaneous CO2 concentration was increased while CO concentration was relatively stable; (ii) the yield of CO2 and H2 increased on the cost of CH4. During steam gasification of RS, with the increase in K2CO3 content in RS (i) the instantaneous concentration of CO2 and H2 increased while instantaneous concentration of CO and CH4 decreased; (ii) the yield of CO2 and H2 production and total yield increased; and (iii) yield of CO and CH4 production followed the order: 9% K2CO3 RS<6% K2CO3 RS
Keywords: Pyrolysis; Steam Gasification; Biomass; Rice Straw; K2CO3
[References]
  1. Muthayya S, Sugimoto JD, Montgomery S, Maberly GF, Annals of the New York Academy of Sciences, 1324(1), 7, 2014
  2. Kadam KL, Forrest LH, Jacobson WA, Biomass Bioenerg., 18(5), 369, 2000
  3. Nizamuddin S, Mubarak NM, Tiripathi M, Jayakumar NS, Sahu JN, Ganesan P, Fuel, 163, 88, 2016
  4. Nizamuddin S, Jayakumar NS, Sahu J, Ganesan P, Bhutto AW, Mubarak NM, Korean J. Chem. Eng., 32(9), 1789, 2015
  5. Chakma S, Ranjan A, Choudhury H, Dikshit P, Moholkar V, Clean Technol. Environ. Policy, 18(2), 373, 2016
  6. Savaliya M, Dhorajiya B, Dholakiya B, Res. Chem. Intermed., 41(2), 475, 2015
  7. Heidenreich S, Foscolo PU, Prog. Energy Combust. Sci., 46, 72, 2015
  8. Tang J, Wang J, Fuel Process. Technol., 142, 34, 2016
  9. Wannapeera J, Worasuwannarak N, Pipatmanomai S, Songklanakarin J. Science and Technology, 30(3), 393, 2008
  10. Jiang L, Hu S, Wang Y, Su S, Sun LS, Xu BY, He LM, Xiang J, Int. J. Hydrog. Energy, 40(45), 15460, 2015
  11. Hamad MA, Radwan AM, Heggo DA, Moustafa T, Renew. Energy, 85, 1290, 2016
  12. Thangalazhy-Gopakumar S, Al-Nadheri WMA, Jegarajan D, Sahu JN, Mubarak NM, Nizamuddin S, Bioresour. Technol., 178, 65, 2015
  13. Baloch HA, Yang T, Li R, Nizamuddin S, Kai X, Bhutto AW, Clean Technol. Environ. Policy, 18(4), 1031, 2016
  14. Franco C, Pinto F, Gulyurtlu I, Cabrita I, Fuel, 82(7), 835, 2003
  15. Ahmed T, Ahmad M, Lam H, Yusup S, Clean Technol. Environ. Policy, 15(3), 513, 2013
  16. Bhutto AW, Bazmi AA, Zahedi G, Prog. Energy Combust. Sci., 39(1), 189, 2013
  17. Sabzoi N, Yong EK, Jayakumar NS, Sahu JN, Ganesan P, Mubarak NM, Mazari SA, J. Oil Palm Res., 47(4), 339, 2015
  18. Mudge LK, Baker EG, Mitchell DH, Brown MD, J. Solar Energy Eng., 107(1), 88, 1985
  19. Lang RJ, Fuel, 65(10), 1324, 1986
  20. Li TC, Yan YJ, Ren ZW, Fuel Sci. Technol. Int., 14(7), 879, 1996
  21. Karimi A, Gray MR, Fuel, 90(1), 120, 2011
  22. McKee DW, Fuel, 62(2), 170, 1983
  23. Wood BJ, Sancier KM, Catal. Rev.-Sci. Eng., 26(2), 233, 1984
  24. McKee DW, Chem. Phys. Carbon, 16, 1, 1981
  25. Wang J, Jiang MQ, Yao YH, Zhang YM, Cao JQ, Fuel, 88(9), 1572, 2009
  26. Wu XT, Tang J, Wang J, Fuel, 165, 59, 2016
  27. Sutton D, Kelleher B, Ross JRH, Fuel Process. Technol., 73(3), 155, 2001
  28. Aznar MP, Caballero MA, Sancho JA, Frances E, Fuel Process. Technol., 87(5), 409, 2006
  29. Tada Y, Yasunishi A, KAGAKU KOGAKU RONBUNSHU, 14(4), 552, 1988
  30. Tan H, Wang S, Luo Z, Yu C, Cen K, J. Engineering Thermophysics, 26(5), 742, 2005
  31. Yang C, Yao J, Lu X, Yang X, Lin W, Acta Energiae Solars Thermophysics, 27(5), 496, 2006
  32. Nishimura M, Iwasaki S, Horio M, J. Taiwan Institute of Chemical Engineers, 40(6), 630, 2009
  33. Cao Y, Gao ZY, Jin J, Zhou HC, Cohron M, Zhao HY, Liu HY, Pan WP, Energy Fuels, 22(3), 1720, 2008
  34. Abuadala A, Dincer I, Thermochim. Acta, 507-508, 127, 2010
  35. Karimipour S, Gerspacher R, Gupta R, Spiteri RJ, Fuel, 103, 308, 2013
  36. Canabarro N, Soares J, Anchieta C, Kelling C, Mazutti M, Sustainable Chemical Processes, 1(1), 22, 2013
  37. Jenkins BM, Bakker RR, Wei JB, Biomass Bioenerg., 10(4), 177, 1996
  38. Li Y, Yang HP, Hu JH, Wang XH, Chen HP, Fuel, 117, 1174, 2014
[Cited By]
  1. Zhao S, Liu M, Zhao L, Lu J, Korean Journal of Chemical Engineering, 34(12), 3077, 2017
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