International Journal of Renewable Energy Research-IJRER

Depletion of petroleum and environmental problem have led to look for alternative fuel sources. In many ways, biomass is a potential renewable source. Among the many forms of biomass, empty fruit bunch (EFB) of palm oil is very attractive feedstock due to its abundance, low price and non-competitiveness with the food chain. EFB can be converted into bio-oil by pyrolysis process, but this product can not be used directly as a transportation fuel, as it needs to undergo a process of an upgrade to bio-oil. Co-pyrolysis is a biomass pyrolysis process with solid material that has a high hydrogen index at atmospheric pressure. One of the materials that have a higher hydrogen index than biomass is polymer, such as solid tire waste. The objectives of this research are to study the treatment effects on EFB, the influence ratio of solid tire waste with EFB, and temperature of the yield and composition of the product. EFB that had been treated was mixed with the waste tire, wihh a weight ratio of (100: 0, 75:25, 50: 50.25: 75 and 0: 100) between EFB and waste tire. The mixed raw material was put into the co-pyrolysis reactor and heated at 400 – 600 ^oC with nitrogen gas flowing for 45 minutes. The results showed that the treatment of EFB as the raw material of pyrolysis could increase the yield of bio-oil and improve the quality of bio-oil. With the addition of 75% waste tire in the co-pyrolysis raw material, the composition of hydrocarbons in bio-oil became 59.55% with a bio-oil heating value of 33.1 MJ/kg.

Bio-oil; co-pyrolysis; empty fruit bunch; solid tire waste

R. French, and S. Czernik, “Catalytic pyrolysis of biomass for biofuels productionâ€, Fuel Processing Technology, 91, 25-32, 2010.

J. Payormhorm, K. Kangvansaichol, P. Reubroycharoen, P. Kunchonthara, and N. Hinchiranan, “Pt/Al2O-catalytic deoxygenation for upgrading of Leucaena leucocephala-pyrolysis oilâ€, Bioresource Technol., vol.139, pp.128-135, 2013.

D.R.Wicakso, Rochmadi, Sutijan, and A. Budiman, “Effect of temperature on catalytic decomposition of tar using Indonesian iron ore as catalystâ€, Int. J. Renew. Energy Res., vol. 8, no 1, pp. 414-420, 2018.

L. Jilkova, K. Ciahotny, and J. Kusy, “Pyrolysis of brown coal using a catalyst based on W-Niâ€, Acta Polytechnica, 55, 5, 319-323, 2015

Sunarno, Rochmadi, Mulyono, P., and Budiman, A., “Silica-alumina based catalytic cracking of bio-oil using double series reactorâ€, Int. J. Renew. Energy Res., vol. 8, no 1, pp. 414-420, 2018.

L.J.R. Nunes, J.C.O. Matias, and J.P.S. Catalao, “Application of biomass for the production of energy in the Portuguese textile industryâ€, 2013 International Conference on Renewable Energy Research and Applications (ICRERA), Madrid, 2013, pp. 336-341; doi:10.1109/ICRERA.2013.6749776.

S. Jamilatun, A. Budiman, Budhijanto, and Rochmadi, “Non-catalytic slow pyrolysis of spirulina platensis residue for production of liquid biofuelâ€, Int. J. Renew. Energy Res., vol. 7, no. 4, pp. 1901-1908, 2017.

N. Abdullah, and H. Gerhauser,â€Bio-oil Derived from Empty Fruit Bunchesâ€, Fuel, 87, 2606-2613, 2008.

M. Mailin, H. Roslindawati, A.K. Fadhzir, S. A. Aishah, “Pretreatment of empty palm fruit bunch for production of chemicals via catalytic pyrolysisâ€, Bioresour. Technol., vol.100, 2867-2873, 2009.

Y.S. Pradana and A. Budiman, “Bio-syngas derived from Indonesian oil palm empty fruit bunch (EFB) using middle-scala gasification,†JESTEC, vol. 10, no.8, pp. 1-8, 2015.

D.A. Bulushev, and J.R.H. Ross, “ Catalysis for conversion of biomass to fuels via pyrolysis and gasificationâ€, Catal. Today, vol. 171 , pp.1 – 13, 2011.

S. Bahri, Sunarno, Muhdarina, and R.D. Anugra, “Catalytic pyrolysis using catalyst nickel natural zeolite (Ni/NZA) on conversion of biomass to bio-oilâ€,Proceeding of the 2011 International Conference and Utility Exhibition on Power and Energy Systems Issue and Prospects for Asia, ICUE, 2011,IEEE Explore, pp.1-4, 2012.

Sunarno, Rochmadi, P. Mulyono, and A. Budiman, “Kinetic study of catalytic cracking of bio-oil over silica-alumina catalystâ€, Bioresources, vol.13, No. 1, pp. 1917-1929, 2018.

P.M. Mortensen, J.D. Grunwaldt, P.A . Jensen, K.G. Knudsen, , and A. D. Jensen, , “A Review of Catalytic Upgrading of Bio-oil to Engine Fuelsâ€, Appl. Catal. A , vol. 407, 1-19, 2011.

X. Zhu, Y. Zhang, H. Ding, L. Huang, X. Zhu, “Comprehensive study on pyrolysis and co-pyrolysis of walnut shell and bio oil distillation residueâ€, Energy Conversion and Management , vol. 168, 178-187, 2018.

K.G. Burra and A.K. Gupta, “Kinetics of synergistic effects in co-pyrolysis of biomass with plastic wastesâ€, Applied Energy, vol. 220, 408-418, 2018

C. Johansson, L. Sandström, O. Öhrman and H. Jilvero, “Co-pyrolysis of woody biomass and plastic waste in both analytical and pilot scaleâ€, Journal of Analytical and Applied Pyrolysis, 134, 102-113, 2018.

H. Zhao, Q. Song, S. Liu, Y. Li, X. Wang and X. Shu, “Study on catalytic co-pyrolysis of physical mixture/staged pyrolysis characteristics of lignite and straw over an catalytic beds of char and its mechanismâ€, Energy Conversion and Management, 161, 13-26, 2018.

M.S Hossain, M.R, Islam, M.S Rahman, M.A. Kadera, and H. Haniu, “Biofuel from co-pyrolysis of solid tire waste and rice huskâ€, Energi Procedia, 110, 453-458, 2017.

J. Alvarez , M. Amutio, G. Lopez, L. Santamaria, J. Bilbao, M. Olazar, “Improving bio-oil properties through the fast co-pyrolysis of lignocellulosic biomass and waste tyresâ€, Waste Management, 85, pp. 385-395, 2019.