Vol. 2 No. 1 (2025), Review
Vol. 2 No. 1 (2025)

Sustainable site selection for biomass refineries: an analytic network process model for optimizing bioenergy production in Iran

Review
Published 2025-02-24
Zeynab Pashmi
Department of Industrial Engineering, Mazandaran University of Science and Technology, Babol, Iran
Maryam Chamehsara
Department of Industrial Engineering, College of Engineering, University of Tehran, Tehran, Iran
Sara Parsi
Faculty of Management and Economics, Tarbiat Modares University, Tehran, Iran
Abooali Golzary
School of Environment, College of Engineering, University of Tehran, P.O. Box 14155-6135, Tehran, Iran
PDF

Keywords

Biomass
refinery
supply chain optimization
microalgae
sustainability

Categories

Abstract

Biomass, with its abundant resources and versatility, is increasingly recognized as a sustainable alternative to fossil fuels for fuel and chemical production. However, establishing an efficient supply chain for microalgae-based biomass refineries poses challenges due to irregular production patterns and the dispersed distribution of resources. This study presents a framework for selecting an optimal location for a biomass refinery in Iran, chosen for its favorable conditions, including abundant sunlight, carbon dioxide, and saline water. Using a mathematical optimization model and network analysis, this framework evaluates potential refinery sites based on criteria such as infrastructure access, climate conditions, and algae growth suitability. Economic, environmental, social, and logistical indicators guide the decision-making process. The results identify Bushehr as the optimal location, primarily driven by transportation cost efficiency, which significantly impacts the overall supply chain costs. By optimizing transportation routes, this model not only reduces expenses but also maximizes the biomass energy potential, contributing to a more sustainable bioenergy infrastructure. The insights from this study support the transition toward sustainable energy production and offer a strategic approach to designing effective biomass refinery supply chains.

PDF

References

Yoro KO, Daramola MO. CO2 emission sources, greenhouse gases, and the global warming effect. In: Advances in carbon capture. Elsevier; 2020. p. 3-28.

McCoy AL, Jacobs KL, Vano JA, Wilson JK, Martin S, Pendergrass AG, et al. The Press and Pulse of Climate Change: Extreme Events in the Colorado River Basin. JAWRA Journal of the American Water Resources Association. 2022.

Goswami L, Kayalvizhi R, Dikshit PK, Sherpa KC, Roy S, Kushwaha A, et al. A critical review on prospects of bio-refinery products from second and third generation biomasses. Chemical Engineering Journal. 2022:137677.

Pourkarimi S, Hallajisani A, Alizadehdakhel A, Nouralishahi A, Golzary A. Factors affecting production of beta-carotene from Dunaliella salina microalgae. Biocatalysis and Agricultural Biotechnology. 2020;29:101771.

Kasani AA, Esmaeili A, Golzary A. Software tools for microalgae biorefineries: Cultivation, separation, conversion process integration, modeling, and optimization. Algal Research. 2022;61:102597.

Azari A, Tavakoli H, Barkdoll BD, Haddad OB. Predictive model of algal biofuel production based on experimental data. Algal Research. 2020;47:101843.

Saber M, Golzary A, Hosseinpour M, Takahashi F, Yoshikawa K. Catalytic hydrothermal liquefaction of microalgae using nanocatalyst. Applied energy. 2016;183:566-576.

Golzary A, Imanian S, Abdoli MA, Khodadadi A, Karbassi A. A cost-effective strategy for marine microalgae separation by electro-coagulation–flotation process aimed at bio-crude oil production: Optimization and evaluation study. Separation and Purification Technology. 2015;147:156-165.

Shahsavari A, Yazdi F, Yazdi H. Potential of solar energy in Iran for carbon dioxide mitigation. International Journal of Environmental Science and Technology. 2019;16:507-524.

Nascimento L, Kuramochi T, Wollands S, de Villafranca Casa M, Hans F, de Vivero G, et al. Greenhouse gas mitigation scenarios for major emitting countries Analysis of current climate policies and mitigation commitments: 2022 update. 2022.

Vahidi Ghazvini M, Noorpoor A. Improvement of the dust transfer system of an industrial unit using numerical solution. International Journal of Environmental Science and Technology. 2022:1-8.

Jena U, Das K, Kastner J. Effect of operating conditions of thermochemical liquefaction on biocrude production from Spirulina platensis. Bioresource technology. 2011;102(10):6221-6229.

Elgarahy AM, Hammad A, El-Sherif DM, Abouzid M, Gaballah MS, Elwakeel KZ. Thermochemical conversion strategies of biomass to biofuels, techno-economic and bibliometric analysis: A conceptual review. Journal of Environmental Chemical Engineering. 2021;9(6):106503.

Alper K, Tekin K, Karagöz S, Ragauskas AJ. Sustainable energy and fuels from biomass: a review focusing on hydrothermal biomass processing. Sustainable Energy & Fuels. 2020;4(9):4390-4414.

Barot S. Biomass and Bioenergy: Resources, Conversion and Application. Renewable Energy for Sustainable Growth Assessment. 2022:243-262.

Bakhtiari H, Ansari Tadi R, Golzari AA. An overview of microalgae harvest from aquatic environments using biological methods. Applied Biology. 2021;11(41):85-106.

Golzary A, Abdoli MA, Khodadadi A, Karbassi A, Imanian S. Investigation of Electro and Chemical Coagulation Processes for Marine Microalgae Separation. Nashrieh Shimi va Mohandesi Shimi Iran. 2016;35(1):39-52.

Sanaye Mozaffari Sabet N, Golzary A. CO2 biofixation at microalgae photobioreactors: hydrodynamics and mass transfer study. International Journal of Environmental Science and Technology. 2022;19(11):11631-11648.

Daliry S, Hallajisani A, Mohammadi Roshandeh J, Nouri H, Golzary A. Investigation of optimal condition for Chlorella vulgaris microalgae growth. Global Journal of Environmental Science and Management. 2017;3(2):217-230.

Dalirynezhad S, Hallajisani A, Nouri H, Golzary A. Effects of environmental factors on Chlorella sp. microalgae for biodiesel production purpose: enhanced lipid and biomass productivity. Recent Innovations in Chemical Engineering (Formerly Recent Patents on Chemical Engineering). 2017;10(2):119-126.

Golzary A, Tavakoli O, Rezaei Y, Karbassi A. Wastewater treatment by Azolla Filiculoides: A study on color, odor, COD, nitrate, and phosphate removal. Pollution. 2018;4(1):69-76.

Manzoor F, Karbassi A, Golzary A. Removal of heavy metal contaminants from wastewater by using Chlorella vulgaris Beijerinck: A review. Current Environmental Management (Formerly: Current Environmental Engineering). 2019;6(3):174-187.

Manzoor F, Karbassi A, Golzary A. A theoretical and experimental study on removal of nickel, lead, and zinc metals from wastewater using Chlorella vulgaris microalgae. International Journal of Environmental Engineering. 2020;10(4):350-373.

Martinkus N, Wolcott M. A framework for quantitatively assessing the repurpose potential of existing industrial facilities as a biorefinery. Biofuels, Bioproducts and Biorefining. 2017;11(2):295-306.

Marvin WA, Schmidt LD, Daoutidis P. Biorefinery location and technology selection through supply chain optimization. Industrial & Engineering Chemistry Research. 2013;52(9):3192-3208.

Ng RT, Maravelias CT. Design of biofuel supply chains with variable regional depot and biorefinery locations. Renewable Energy. 2017;100:90-102.

AlNouss A, McKay G, Al-Ansari T. Production of syngas via gasification using optimum blends of biomass. Journal of cleaner production. 2020;242:118499.

Deng Y, Gan VJ, Das M, Cheng JC, Anumba C. Integrating 4D BIM and GIS for construction supply chain management. Journal of construction engineering and management. 2019;145(4):04019016.

Broekmeulen RA, Sternbeck MG, van Donselaar KH, Kuhn H. Decision support for selecting the optimal product unpacking location in a retail supply chain. European Journal of Operational Research. 2017;259(1):84-99.

Hadi-Vencheh A, Niazi-Motlagh M. An improved voting analytic hierarchy process–data envelopment analysis methodology for suppliers selection. International Journal of Computer Integrated Manufacturing. 2011;24(3):189-197.

Perić T, Babić Z, Veža I. Vendor selection and supply quantities determination in a bakery by AHP and fuzzy multi-criteria programming. International Journal of Computer Integrated Manufacturing. 2013;26(9):816-829.

Kilincci O, Onal SA. Fuzzy AHP approach for supplier selection in a washing machine company. Expert systems with Applications. 2011;38(8):9656-9664.

Chamodrakas I, Batis D, Martakos D. Supplier selection in electronic marketplaces using satisficing and fuzzy AHP. Expert systems with Applications. 2010;37(1):490-498.

Lin R-H. An integrated FANP–MOLP for supplier evaluation and order allocation. Applied Mathematical Modelling. 2009;33(6):2730-2736.

Mokhtarian M, Hadi-Vencheh A. A new fuzzy TOPSIS method based on left and right scores: An application for determining an industrial zone for dairy products factory. Applied Soft Computing. 2012;12(8):2496-2505.

Kermani MAMA, Navidi H, Alborzi F. A novel method for supplier selection by two competitors, including multiple criteria. International Journal of Computer Integrated Manufacturing. 2012;25(6):527-535.

Basnet C, Leung JM. Inventory lot-sizing with supplier selection. Computers & Operations Research. 2005;32(1):1-14.

Ghodsypour SH, O’brien C. The total cost of logistics in supplier selection, under conditions of multiple sourcing, multiple criteria and capacity constraint. International journal of production economics. 2001;73(1):15-27.

Vaidya OS, Kumar S. Analytic hierarchy process: An overview of applications. European Journal of Operational Research. 2006;169(1):1-29.

Baykasoglu A. A review and analysis of “graph theoretical-matrix permanent” approach to decision making with example applications. Artificial intelligence review. 2014;42:573-605.

Parker N, Tittmann P, Hart Q, Nelson R, Skog K, Schmidt A, et al. Development of a biorefinery optimized biofuel supply curve for the Western United States. biomass and bioenergy. 2010;34(11):1597-1607.

Shabani N, Sowlati T. A mixed integer non-linear programming model for tactical value chain optimization of a wood biomass power plant. Applied energy. 2013;104:353-361.

Azadeh A, Rahimi-Golkhandan A, Moghaddam M. Location optimization of wind power generation–transmission systems under uncertainty using hierarchical fuzzy DEA: A case study. Renewable and Sustainable Energy Reviews. 2014;30:877-885.

Chatzimouratidis AI, Pilavachi PA. Multicriteria evaluation of power plants impact on the living standard using the analytic hierarchy process. Energy policy. 2008;36(3):1074-1089.

Lipošćak M, Afgan NH, Duić N, da Graça Carvalho M. Sustainability assessment of cogeneration sector development in Croatia. Energy. 2006;31(13):2276-2284.

Ertay T, Kahraman C, Kaya İ. Evaluation of renewable energy alternatives using MACBETH and fuzzy AHP multicriteria methods: the case of Turkey. Technological and economic development of economy. 2013;19(1):38-62.

Doukas HC, Andreas BM, Psarras JE. Multi-criteria decision aid for the formulation of sustainable technological energy priorities using linguistic variables. European Journal of Operational Research. 2007;182(2):844-855.

Lee AH, Chen HH, Kang H-Y. Multi-criteria decision making on strategic selection of wind farms. Renewable Energy. 2009;34(1):120-126.

Cavallaro F, Ciraolo L. A multicriteria approach to evaluate wind energy plants on an Italian island. Energy policy. 2005;33(2):235-244.

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Copyright (c) 2025 Zeynab Pashmi, Maryam Chamehsara, Sara Parsi, Abooali Golzary (Author)