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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 827Overview of Bio-Oil Upgrading via Catalytic...

Overview of Bio-Oil Upgrading via Catalytic Cracking

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Abstract:

Fast pyrolysis of biomass to produce bio-oil is an important technology to utilize lignocellulosic biomass, because the liquid bio-oil is regarded as a promising candidate of petroleum fuels. However, bio-oil is a low-grade liquid fuel, and required to be upgraded before it can be directly utilized in existing thermal devices. Catalytic cracking is an effective way to upgrade bio-oil, which can be performed either on the liquid bio-oil or the pyrolysis vapors. Various catalysts have been prepared and used for catalytic cracking, and they exhibited different catalytic capabilities. This paper will review the recent progress of the catalytic cracking of liquid bio-oil or pyrolysis vapors.

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Periodical:

Advanced Materials Research (Volume 827)

Pages:

25-29

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.827.25

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Online since:

October 2013

Authors:

Hang Tao Liao, Xiao Ning Ye, Qiang Lu, Chang Qing Dong

Keywords:

Biomass, Bio-Oil, Catalytic Cracking, Fast Pyrolysis, Upgrading

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© 2014 Trans Tech Publications Ltd. All Rights Reserved

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[1] A.V. Bridgwater and G.V.C. Peacocke: Renew. Sust. Energ. Rev. Vol. 4(1) (2000), p.1.

[2] A.V. Bridgwater: Biomass Bioenerg Vol. 38 (2012), p.68.

[3] Q. Lu, W.Z. Li and X.F. Zhu: Energ. Conv. Manage. Vol. 50 (2009), p.1376.

[4] D. Chiaramonti, A. Oasmaa and Y. Solantausta: Renew. Sust. Energ. Rev. Vol. 11 (2007), p.1056.

[5] A.K. Hossain and P.A. Davies: Renew. Sust. Energ. Rev. Vol. 21 (2013), p.165.

[6] A.V. Bridgwater: Catal. Today Vol. 29 (1996), p.285.

[7] J.D. Adjaye and N.N. Bakhsi: Fuel Process. Technol. Vol. 45 (1995), p.161.

[8] J.D. Adjaye and N.N. Bakhsi: Fuel Process. Technol. Vol. 45 (1995), p.185.

[9] J.D. Adjaye, S.P.R. Katikaneni and N.N. Bakshi: Fuel Process. Technol. Vol. 48 (1996), p.115.

[10] R.K. Sharma and N.N. Bakhshi: Biomass Bioenerg Vol. 5 (1993), p.445.

[11] S. Vitolo, M. Seggiani, P. Frediani, G. Ambrosini and L. Politi: Fuel Vol. 78 (1999), p.1147.

DOI: 10.1016/s0016-2361(99)00045-9

[12] S.T. Srinivas, A.K. Dalai and N.N. Bakhshi: Can. J. Chem. Eng. Vol. 78 (2000), p.343.

[13] K.L. Hew, A.M. Tamidi, S. Yusup, K.T. Lee and M.M. Ahmad: Bioresource Technol. Vol. 101 (2010), p.8855.

[14] B. Valle, A.G. Gayubo, A.T. Aguayo, M. Olazar and J. Bilbao: Energ Fuel Vol. 24 (2010), p. (2060).

[15] F. Gong, Z. Yang, C. Hong, W. Huang, S. Ning, Z. Zhang, Y. Xu and Q. Li: Bioresource Technol. Vol. 102 (2011), p.9247.

[16] M. Olazar, R. Aguado and J. Bilbao: Aiche J. Vol. 46 (2000), p.1025.

[17] E. Putun, B.B. Uzun and A.E. Putun: Bioresource Technol. Vol. 97 (2006), p.701.

[18] K. Murata, Y. Liu, M. Inaba and I. Takahara: J. Anal. Appl. Pyrol. Vol. 94 (2012), p.75.

[19] O.D. Mante, F.A. Agblevor and R. McClung: Fuel Vol. 108 (2013), p.451.

[20] P.T. Williams and P.A. Horne: J. Anal. Appl. Pyrol. Vol. 31 (1995), p.39.

[21] P.T. Williams and N. Nugranad: Energy Vol. 25 (2000), p.493.

[22] P.A. Horne and P.T. Williams: Fuel Vol. 75 (1996), p.1043.

[23] A.M. Azeez, D. Meier, J. Odermatt and T. Willner: J. Anal. Appl. Pyrol. Vol. 91 (2011), p.296.

[24] H.S. Choi and D. Meier: J. Anal. Appl. Pyrol. Vol. 100 (2013), p.207.

[25] M.I. Nokkosmaki, E.T. Kuoppala, E.A. Leppamaki and A.O.I. Krause: J. Anal. Appl. Pyrol. Vol. 55 (2000), p.119.

[26] Q. Lu, Z.F. Zhang, C.Q. Dong and X.F. Zhu: Energies Vol. 3 (2010), p.1805.

[27] L. Zhou, H. Yang, H. Wu, M. Wang and D. Cheng: Fuel Process. Technol. Vol. 106 (2013), p.385.

[28] J. Adam, M. Blazso, E. Meszaros, M. Stocker, Me.H. Nilsen, A. Bouzga, J.E. Hustad, M. Gronli and G. Oye: Fuel Vol. 84 (2005), p.1494.

DOI: 10.1016/j.fuel.2005.02.006

[29] E. Antonakou, A. Lappas, M.H. Nilsen, A. Bouzga and M. Stocker: Fuel Vol. 85 (2006), p.2202.

[30] Q. Lu, Z. Tang, Y. Zhang and X.F. Zhu: Ind. Eng. Chem. Res. Vol. 49 (2010), p.2573.

[31] K.S. Triantafyllidis, E.F. Iliopoulou, E.V. Antonakou, A.A. Lappas, H. Wang and T.J. Pinnavaia: Micropor. Mesopor. Mat. Vol. 99 (2007), p.132.

[32] A. Pattiya, J.O. Titiloye and A.V. Bridgwater: Fuel Vol. 89 (2010), p.244.