Gasification is an attractive pathway for valorizing waste and biomass as it can deal with a wide range of feedstocks yielding gaseous products that be converted further to valuable biofuels and chemicals. While many previous studies commonly discussed the effects of gasification operating parameters, such as operating conditions, biomass feedstocks and gasifying agents, on syngas compositions, fewer studies evaluated the effects of gasification process parameters on final products derived from syngas. Essentially, performing an integrated assessment of the biomass-to-product conversion gives a thorough understanding of the biomass processing and provides one with useful heuristics for the conversion of biomass to valuable chemicals. This study evaluates the effects of steam-to-biomass ratio (S/B = 0.3 – 0.7) and gasification temperature (T_gasif = 900℃ – 1,100℃) on the methanol production by performing simulations in the Aspen Plus v.11 process simulator. The kinetically controlled reactions model was considered in the methanol synthesis unit to mimic its actual process condition and to take into account the possibility of the side product formation. The outcome of this study recommends that the steam-to-biomass ratio gives more notable effects on the gasification distribution products and the conversion of syngas to methanol than those given by the gasification temperature. While, the reaction selectivity to methanol remains high, and it is not sensitive to the change of steam-to-biomass ratios and gasification temperatures.

Abdelouahed, L., Authier, O., Mauviel, G., Corriou, J.P., Verdier, G., Dufour, A. 2012. Detailed Modeling of Biomass Gasification in Dual Fluidized Bed Reactors under Aspen Plus. Energy & Fuels. 26(6): 3840–3855.

Ahmad, A.A., Zawawi, N.A., Kasim, F.H., Inayat, A., Khasri, A. 2016. Assessing the gasification performance of biomass: A review on biomass gasification process conditions, optimization and economic evaluation. Renewable and Sustainable Energy Reviews. 53: 1333–1347.

AlNouss, A., McKay, G., Al-Ansari, T. 2020. A comparison of steam and oxygen fed biomass gasification through a techno-economic-environmental study. Energy Conversion and Management. 208: 112612.

Al-Zareer, M., Dincer, I., Rosen, M.A. 2016. Effects of various gasification parameters and operating conditions on syngas and hydrogen production. Chemical Engineering Research and Design. 115: 1–18.

Begum, S., Rasul, M.G., Akbar, D., Cork, D. 2014. An Experimental and Numerical Investigation of Fluidized Bed Gasification of Solid Waste. Energies. 7: 43–61.

Cao, Y., Wang, Q., Du, J., Chen, J. 2019. Oxygen-enriched air gasification of biomass materials for high-quality syngas production. Energy Conversion and Management. 199: 111628.

Fajimi, L. I., Oboirien, B. O., Adams II, T. A. 2021. Simulation studies on the co-production of syngas and activated carbon from waste tyre gasification using different reactor configurations. Energy Conversion and Management: X. 11: 100105.

Gao, X., Zhang, Y., Li, B., Yu, X. 2016. Model development for biomass gasification in an entrained flow gasifier using intrinsic reaction rate submodel. Energy Conversion and Management. 108: 120–131.

Geng, A. 2013. Conversion of oil palm empty fruit bunch to biofuels. Liquid, Gaseous and Solid Biofuels-Conversion Techniques. InTech. Croatia.

Gutiérrez Ortiz, F.J., Serrera, A., Galera, S., Ollero, P. 2013. Methanol synthesis from syngas obtained by supercritical water reforming of glycerol. Fuel. 105: 739–751.

Haydary, J., Šuhaj, P., Husár, J. 2021. Waste biomass to methanol – optimization of gasification agent to feed ratio. Biomass Conversion and Biorefinery. 11: 419–428.

Hoo, K.K., Md Said, M.S. 2021. Air gasification of empty fruit bunch: An Aspen Plus model. Bioresource Technology Reports. 16: 100848.

Kiss, A.A., Pragt, J.J., Vos, H.J., Bargeman, G., de Groot, M.T. 2016. Novel efficient process for methanol synthesis by CO2 hydrogenation. Chemical Engineering Journal. 284: 260–269.

Manenti, F., Leon-Garzon, A.R., Ravaghi-Ardebili, Z., Pirola, C. 2014. Systematic staging design applied to the fixed-bed reactor series for methanol and one-step methanol/dimethyl ether synthesis. Applied Thermal Engineering. 70(2): 1228–1237.

Marulanda, V.A., Gutierrez, C.D.B., Alzate, C.A.C. 2019. Chapter 4 Thermochemical, Biological, Biochemical, and Hybrid Conversion Methods of Bio-derived Molecules into Renewable Fuels, in M. Hosseini (Ed.) Advanced Bioprocessing for Alternative Fuels, Biobased Chemicals, and Bioproducts. Woodhead Publishing. 59–81.

Mohammed, M.A.A., Salmiaton, A., Wan Azlina, W.A.K.G., Mohammad Amran, M.S., Fakhru’l-Razi, A. 2011. Air gasification of empty fruit bunch for hydrogen-rich gas production in a fluidized-bed reactor. Energy Conversion and Management. 52(2): 1555–1561.

Molino, A., Larocca, V., Chianese, S., Musmarra, D. 2018. Biofuels Production by Biomass Gasification: A Review. Energies. 11(4): 811.

Mutlu, Ö.Ç., Zeng, T. 2020. Challenges and Opportunities of Modeling Biomass Gasification in Aspen Plus: A Review. Chemical Engineering & Technology. 43(9): 1674–1689.

Nyári, J., Magdeldin, M., Larmi, M., Järvinen, M., Santasalo-Aarnio, A. 2020. Techno-economic barriers of an industrial-scale methanol CCU-plant. Journal of CO2 Utilization. 39: 101166.

Pairon, M.S., Ali, F., Ahmad, F., Anuar, H., Abdul Rahman, N.A., Saeed Mirghani, M.E., Suhr, J., Thomas, S. 2022. Review on Solvent Extraction Methods of Lignin from Oil Palm Empty Fruit Bunches (OPEFB). Journal of Natural Fibers. 19(15): 11507–11523.

Panwar, N.L., Kothari, R., Tyagi, V.V. 2012. Thermo chemical conversion of biomass – Eco friendly energy routes. Renewable and Sustainable Energy Reviews. 16(4): 1801–1816.

Peng, W.X., Wang, L.S., Mirzaee, M., Ahmadi, H., Esfahani, M.J., Fremaux, S. 2017. Hydrogen and syngas production by catalytic biomass gasification. Energy Conversion and Management. 135: 270–273.

Puig-Arnavat, M., Bruno, J.C., Coronas, A. 2010. Review and analysis of biomass gasification models. Renewable and Sustainable Energy Reviews. 14: 2841–2851.

Puig-Gamero, M., Argudo-Santamaria, J., Valverde, J.L., Sánchez, P., Sanchez-Silva, L. 2018. Three integrated process simulation using aspen plus®: Pine gasification, syngas cleaning and methanol synthesis. Energy Conversion and Management. 177: 416–427.

Ramzan, N., Ashraf, A., Naveed, S., Malik, A. 2011. Simulation of hybrid biomass gasification using Aspen plus: A comparative performance analysis for food, municipal solid and poultry waste. Biomass and Bioenergy. 35(9): 3962–3969.

Shahbaz, M., Al-Ansari, T., Inayat, M., Sulaiman, S.A., Parthasarathy, P., McKay, G. 2020. A critical review on the influence of process parameters in catalytic co-gasification: Current performance and challenges for a future prospectus. Renewable and Sustainable Energy Reviews. 134: 110382.

Vu, H. P., Nguyen, L. N., Vu, M. T., Johir, M. A. H., McLaughlan R., Nghiem, L. D. 2020. A comprehensive review on the framework to valorise lignocellulosic biomass as biorefinery feedstocks. Science of the Total Environment. 743: 140630.

Xiong, X., Yu, I.K.M., Cao, L., Tsang, D.C.W., Zhang, S., Ok, Y.S. 2017. A review of biochar-based catalysts for chemical synthesis, biofuel production, and pollution control. Bioresource Technology. 246: 254–270.

Watson, J., Zhang, Y., Si, B., Chen, W.-T., de Souza, R. 2018. Gasification of biowaste: A critical review and outlooks. Renewable and Sustainable Energy Reviews. 83: 1–17.

Yan, L., Li, Y., Li, J., Gao, W. 2017. Steam gasification of biomass for biomethanol production: Model development and analysis. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. 39(13): 1410–1415.

You, S., Ok, Y.S., Tsang, D.C.W., Kwon, E.E., Wang, C.-H. 2018. Towards practical application of gasification: a critical review from syngas and biochar perspectives. Critical Reviews in Environmental Science and Technology. 48(22-24): 1165–1213.

Zhang, Y., Xiao, J., Shen, L. 2009. Simulation of methanol production from biomass gasification in interconnected fluidized beds. Industrial & Engineering Chemistry Research. 48(11): 5351–5359.

Zhang, L., Xu, C., Champagne, P. 2010. Overview of recent advances in thermo-chemical conversion of biomass. Energy Conversion and Management. 51(5): 969–982.