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Manuscript ID : IMJ-2306-1851 (R1) Visit : 165 Page: 54 - 69

10.30495/imj.2023.1988071.1851

Article Type: Original Research

Optimization of biomass supply chain network in four levels

Subject Areas : Industrial Management

Davod Dehghan 1 , Kiamars Fathi Hafshejani 2 , Jalal Haghighat Monfared 3

1 - Department of Industrial Management, Qom Branch, Islamic Azad University, Qom, Iran
2 - Assistant Professor, Department of Industrial Management, South Tehran Branch, Islamic Azad University, Tehran, Iran
3 - Assistant Professor, Department of Industrial Management, Central Tehran Branch, Islamic Azad University, Tehran, Iran

Received: 2023-06-07 Accepted : 2023-08-28 Published : 2023-09-23

Keywords: "biomass supply chain network", "desirable and undesirable outputs", "MOPSO algorithm‎", ‏ "genetic algorithm",

Abstract :

Pollution due to biomass burial, the possibility of producing clean energy from biomass and the high demand for ‎energy have made the optimization of the biomass supply chain network important and necessary. The purpose of ‎this article is to optimize biomass supply chain network at four levels in order to reduce economic and ‎environmental costs. The most important gap in research, resolved in this article, is the determination of the ‎desirable and undesirable outputs of the masses in the centers. Separating and considering the multi-period, multi-‎product mode with heterogeneous transport means. The research model is a two-objective linear programming of a ‎correct number mixed with uncertainty and disturbance, four scenarios were designed for this purpose. The model ‎was solved with genetic algorithm and MOPSO method and with Python software. Validation of the model was ‎investigated in a real case study in Fars province has been The proposed model has been able to implement ‎sustainability and resilience at the same time, which has reduced costs, reduced carbon emissions, and increased the ‎commercialization of energy production from biomass, thus increasing the willingness of investors to invest in this ‎network. It is supplied from the supply chain. The proposed model makes the amount of energy production 2.1% ‎lower than when the favorable and unfavorable outputs are not considered, which means it is much closer to reality. ‎By performing sensitivity analysis on real data, the efficiency of the model was proved

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_||_

  1. Abdi, A., & Hajiaghaei-Keshteli, M. (2019). Multi-Objective Closed-loop Supply Chain Considering Vehicles and Solving by New Approaches in Metaheuristics. Journal of Modeling in Engineering17(59), 67-85.
    2.
  2. Akdogan, A. A., & Demirtas, O. (2014). Managerial role in strategic supply chain management. Procedia-Social and Behavioral Sciences150, 1020-1029.
    3.
  3. Al-Hakimi, M. A., & Borade, D. B. (2020). The impact of entrepreneurial orientation on the supply chain resilience. Cogent Business & Management7(1), 1847990.
    4.
  4. Aranguren, M., Castillo-Villar, K. K., & Aboytes-Ojeda, M. (2021). A two-stage stochastic model for co-firing biomass supply chain networks. Journal of Cleaner Production319, 128582.
    5.
  5. Christopher, M.and Peck, H. (2004), "Building the Resilient Supply Chain", The International Journal of Logistics Management,15 (2), 1-14. https://doi.org/10.1108/09574090410700275
    6.
  6. Ebrahim Qazvini, Z., Haji, A., & Mina, H. (2021). A fuzzy solution approach to supplier selection and order allocation in green supply chain considering the location-routing problem. Scientia Iranica28(1), 446-464.
    7.
  7. Ehmann, A., Thumm, U., & Lewandowski, I. (2018). Fertilizing potential of separated biogas digestates in annual and perennial biomass production systems. Frontiers in Sustainable Food Systems2, 12.
    8.
  8. Ferronato, N., Alarcón, G. P. P., Lizarazu, E. G. G., & Torretta, V. (2021). Assessment of municipal solid waste collection in Bolivia: Perspectives for avoiding uncontrolled disposal and boosting waste recycling options. Resources, Conservation and Recycling167, 105234.
    9.
  9. Fritz, M., Ruel, S., Kallmuenzer, A. & Harms, R. (2021). Sustainability Management in Supply Chain: The Role of Familiness. Technological Forecasting & Social Change, 173(2021)121078 https://doi.org/10.1016/j.techfore.2021.121078
    10.
  10. Ghaderi, H., Pishvaee, M. S., & Moini, A. (2016). Biomass supply chain network design: An optimization-oriented review and analysis. Industrial crops and products94, 972-1000.
    11.
  11. Gholami, A., Bonakdari, H., Ebtehaj, I., & Khodashenas, S. R. (2020). Reliability and sensitivity analysis of robust learning machine in prediction of bank profile morphology of threshold sand rivers. Measurement153, 107411.
    12.
  12. Guo, C., Hu, H., Wang, S., Rodriguez, L. F., Ting, K. C., & Lin, T. (2022). Multiperiod stochastic programming for biomass supply chain design under spatiotemporal variability of feedstock supply. Renewable Energy186, 378-393.
    13.
  13. Kamalahmadi, M., & Parast, M. M. (2016). A review of the literature on the principles of enterprise and supply chain resilience: Major findings and directions for future research. International journal of production economics171, 116-133.
    14.
  14. Khalifehzadeh, S., Fakhrzad, M. B., Mehrjerdi, Y. Z., & Hosseini_Nasab, H. (2019). Two effective metaheuristic algorithms for solving a stochastic optimization model of a multi-echelon supply chain. Applied Soft Computing76, 545-563.
    15.
  15. Lambert, Douglas M. (2008). A Global View of Supply Chain Management. University of Auckland Business Review, 10(2), 30-35.
    16.
  16. Liu, X., Tian, G., Fathollahi-Fard, A. M., & Mojtahedi, M. (2020). Evaluation of ship’s green degree using a novel hybrid approach combining group fuzzy entropy and cloud technique for the order of preference by similarity to the ideal solution theory. Clean Technologies and Environmental Policy22, 493-512.
    17.
  17. Lo, S. L. Y., How, B. S., Leong, W. D., Teng, S. Y., Rhamdhani, M. A., & Sunarso, J. (2021). Techno-economic analysis for biomass supply chain: A state-of-the-art review. Renewable and Sustainable Energy Reviews135, 110164.
    18.
  18. Menesy, A. S., Sultan, H. M., Habiballah, I. O., Masrur, H., Khan, K. R., & Khalid, M. (2023). Optimal Configuration of a Hybrid Photovoltaic/Wind Turbine/Biomass/Hydro-Pumped Storage-Based Energy System Using a Heap-Based Optimization Algorithm. Energies16(9), 3648.
    19.
  19. Mohammed, A., Harris, I., Soroka, A., & Nujoom, R. (2019). A hybrid MCDM-fuzzy multi-objective programming approach for a G-resilient supply chain network design. Computers & Industrial Engineering127, 297-312.
    20.
  20. Mousavi Ahranjani, P., Ghaderi, S. F., Azadeh, A., & Babazadeh, R. (2020). Robust design of a sustainable and resilient bioethanol supply chain under operational and disruption risks. Clean technologies and environmental policy22, 119-151.
    21.
  21. Nasiri, M. M., Mousavi, H., & Nosrati-Abarghooee, S. (2023). A green location-inventory-routing optimization model with simultaneous pickup and delivery under disruption risks. Decision Analytics Journal6, 100161.
    22.
  22. Nilsson, F., & Göransson, M. (2021). Critical factors for the realization of sustainable supply chain innovations-model development based on a systematic literature review. Journal of Cleaner Production296, 126471.
    23.
  23. Pakzad-Moghaddam, S. H., Mina, H., & Mostafazadeh, P. (2019). A novel optimization booster algorithm. Computers & Industrial Engineering136, 591-613.
    24.
  24. Prado, A., Chiquier, S., Fajardy, M., & Mac Dowell, N. (2023). Assessing the impact of carbon dioxide removal on the power system. Iscience26(4).
    25.
  25. Rasekh, A., Hamidzadeh, F., Sahebi, H., & Pishvaee, M. S. (2023). A sustainable network design of a hybrid biomass supply chain by considering the water–energy–carbon nexus. Energy Science & Engineering11(3), 1107-1132.
    26.
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    27.
  27. Saghaei, M., Ghaderi, H., & Soleimani, H. (2020). Design and optimization of biomass electricity supply chain with uncertainty in material quality, availability and market demand. Energy197, 117165.
    28.
  28. Toba, A. L., Paudel, R., Lin, Y., Mendadhala, R. V., & Hartley, D. S. (2023). Integrated Land Suitability Assessment for Depots Siting in a Sustainable Biomass Supply Chain. Sensors23(5), 2421.
    29.
  29. Veland, S., Howitt, R., Dominey-Howes, D., Thomalla, F., & Houston, D. (2013). Procedural vulnerability: Understanding environmental change in a remote indigenous community. Global Environmental Change23(1), 314-326.
    30.
  30. Yahya, N. S. M., Ng, L. Y., & Andiappan, V. (2021). Optimisation and planning of biomass supply chain for new and existing power plants based on carbon reduction targets. Energy237, 121488.
    31.
  31. Zarei, M., Shams, M. H., Niaz, H., Won, W., Lee, C. J., & Liu, J. J. (2022). Risk-based multistage stochastic mixed-integer optimization for biofuel supply chain management under multiple uncertainties. Renewable Energy200, 694-705.‏
    32.
  32. Zeinodin Zadeh, S., Amiri, M., Olfat, L., & Pishvaee, M. S. (2023). Modelling a routing-location-inventory problem in the sustainable poultry and livestock medicine supply chain under uncertainty, considering discount. Production and Operations Management14(1), 39-64.
    33.

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