Methanol at different mass concentrations (1, 6, 11, 16, 21 wt %) was added into crude bio-oil to upgrade oil properties. Indexes including pH value, water content and viscosity were measured regularly during a storage period of 91 days. GC-MS analysis was conducted before and after storage. An addition of 21 wt % methanol was found to improve the pH value from 2.97 to 3.88, and decrease the water content and viscosity after storage by 35.02% and 81.35%, respectively. The GC-MS analysis result convincingly showed that methanol could inhibit aging reactions such as polymerization and esterification which created new compounds in the oil. The FTIR and NMR analysis showed that methanol caused some structural changes in bio-oil.
Keywords: bio-oil, pyrolysis, stability, methanol
DOI: 10.3965/j.ijabe.20140703.010

Citation: Fei W T, Liu R H, Zhou W Q, Mei Y F, Yin R Z. Influence of methanol additive on bio-oil stability. Int J Agric & Biol Eng, 2014; 7(3): 83－92.

bio-oil, pyrolysis, stability, methanol

Zhang Q, Chang J, Wang T J. Upgrading bio-oil over different solid catalysts. Energy and Fuels, 2006; 20: 2717－2720.

Mohan D, Pittman C U, Jr H, Steele P. Pyrolysis of

wood/biomass for bio-oil: a critical review. Energy and Fuels, 2006; 20: 848－889.

Oasmaa A, Czernik S. Fuel Oil Quality of biomass pyrolysis oils—state of the art for the end users. Energy and fuels, 1999; 13: 914－921.

Bridgwater A V, Meier D, Radlein D. An overview of fast pyrolysis of biomass. Organic Geochemistry, 1999; 30: 1479－1493.

Li W, Pan C Y, Zhang Q J, Liu Z, Peng J, Chen P, Lou H, Zheng X M. Upgrading of low-boiling fraction of bio-oil in supercritical methanol and reaction network. Bioresource Technology, 2011; 102: 4884－4889.

Diebold J P. A Review of the chemical and physical mechanisms of the storage stability of fast pyrolysis bio-oils, Colorado. 2000; NREL/SR-570-27613.

Wan X H, Chen H P, Luo K, Yang H P, Zhang S H. Methods to improve the stability of bio-oil, Chemical Industry and Engineering Progress, 2006; 25: 765－769.

Diebold J P, Czernik S. Additives to lower and stabilize the viscosity of pyrolysis oils during storage. Energy and Fuels, 1997; 11: 1081－1091.

Scholze B. Long-term stability, catalytic upgrading, and application of pyrolysis oils- Improving the properties of a potential substitute for fossil fuels. Dissertation, 2002.

Wu X W. Effects of different kinds of additives and storage methods on the stability of bio-oil. Master Degree thesis, 2011.

Morris K M. Fast pyrolysis of bagasse to produce Bio-oil fuel for power generation. International Sugar Journal, 2001; 103: 259－263.

Soltes E J, Li J-C K. Hydroprocessing of Biomass tars for Liquid engine Fuels. Progress in Biomass Conversion, 1984.

Oasmaa A, Leppamaki E, Koponene P. Physical characterization of biomass-based pyrolysis liquid: application of standard fuel oil analyses, Technical Research Centre of Finland, VTT Publications, Espoo, Finland, 1997; 306.

Chen T J, Deng C J, Liu R H. Effect of Selective condensation on the characterization of bio-oil from pine sawdust fast pyrolysis using a fluidized-bed reactor. Energy and Fuels, 2010; 24, 6616－6623.

Oasmaa A, Kuoppala E, Solantausta Y. Fast Pyrolysis of Forestry Residue. 2. Physicochemical Composition of Product Liquid. Energy and Fuels, 2003; 17, 433－443.

Shen C J, Liu R H, Chen T J. Influence of storage temperature on stability of physicochemical properties of sawdust pyrolysis bio-oil. Transactions of the CSAE, 2011; 27: 276－281.

Czernik S, Johnson D K, Black S. Stability of wood fast pyrolysis oil. Biomass and Bioenergy, 1994; 7: 187－192.

Wang H. An experimental study on determination of the water content in bio-oil by karl-fischer titration. Renewable Energy Resources, 2005; 3: 17－20.

Oasmaa A, Kuoppala E, Selin J-F, Gust S, Solantausta Y. Fast Pyrolysis of Forestry Residue and Pine. 4. Improvement of the Product Quality by Solvent Addition. Energy and Fuels, 2004; 18: 1578－1583.

Boucher M E, Chaala A, Roy C. Bio-oils obtained by vacuum pyrolysis of softwood bark as a liquid fuel for gas turbines. Part I: Properties of bio-oil and its blends with methanol and a pyrolytic aqueous phase. Biomass and Bioenergy, 2000; 19: 337－350.

Hilten R N, Das K C. Comparison of three accelerated aging procedures to assess bio-oil stability. Fuel, 2010; 89: 2741-2749.

Liu R, Deng C, Wang J. Fast pyrolysis of corn straw for bio-oil production in a bench-scale fluidized bed reactor. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2009; 32: 10.

Putun A E, Ozcan A, Putun E. Pyrolysis of hazelnut shells in a fixed-bed tubular reactor: yields and structural analysis of bio-oil. Journal of Analytical and Applied Pyrolysis, 1999; 52: 33－49.

Williams E A, Williams P T. Analysis of products derived from the fast pyrolysis of plastic waste. Journal of Analytical and Applied Pyrolysis, 1997, 40-41: 347－363.

Ates F, Putun E, Putun A E. Fast pyrolysis of sesame stalk: yields and structural analysis of bio-oil. Journal of Analytical and Applied Pyrolysis, 2004; 71: 779－790.

Mullen C A, Strahan G D, Boatent A A. Characterization of various fast-pyrolysis bio-oils by NMR spectroscopy. Energy an d Fuels, 2009; 23: 2707－2718.

Wisniewski Jr A, Wiggers V R, Simionatto E L, Meier H F, Barros A A C, Madureira L A S. Biofuels from waste fish oil pyrolysis: Chemical composition. Fuel, 2010; 89: 563－568.

Xu J M, Jiang J C, Sun Y J. Bio-oil upgrading by means of ethyl ester production in reactive distillation to remove water and to improve storage and fuel characteristics. Biomass and Bioenergy, 2008; 11: 1056－1061.

Ben H, Ragauskas A J. In situ NMR characterization of pyrolysis oil during accelerated aging. Chem Sus Chem, 2012; 5, 1687－1693.

Yu F, Deng S, Chen P, Liu Y, Wan Y, Olson A, et al. Physical and chemical properties of bio-oils from microwave pyrolysis of corn stover. Applied Biochemistry and Biotechnology, 2007; 137-140: 957－970.