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Decision Science Letters

ISSN 1929-5812 (Online) - ISSN 1929-5804 (Print)
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Volume 13 Issue 4 pp. 1007-1026 , 2024

A simultaneous time and fuel minimization robust possibilistic multiobjective programming approach for truck-sharing scheduling in container terminals Pages 1007-1026 Right click to download the paper Download PDF

Authors: Farnaz Fereidoonian, Seyed Jafar Sadjadi, Mehdi Heydari, Seyed Mohammad Javad Mirzapour Al-e-hashem

DOI: 10.5267/j.dsl.2024.6.002

Keywords: Container terminal, Operation scheduling, Multi-objective, Robust optimization, Time parameters uncertainty, Fuel consumption reduction, Epsilon-constraint

Abstract: The issue of integrated scheduling and sequencing operation of unloading and loading equipment in container ports has been one of the most important issues concerning time efficiency. In addition, with the emergence of green harbor concepts, the inclusion of criteria for minimizing energy consumption, fuel and emission reduction are among the other issues that have been noticed by planners in the field of energy efficiency. Furthermore, due to the complexity and scope of activities of a container terminal, uncertainty in operational parameters such as transportation time, time of readiness and entry of work into the system and the velocity of the transportation fleet are inevitable in this operational environment. Therefore, this research with the aim of sharing trucks among loading and unloading equipment, proposes a robust multi-objective integer programming model for the synchronized scheduling of truck operations with other handling equipment to decrease the fuel consumption of trucks and the flow time of containers, considering the uncertainty in operational parameters as fuzzy numbers. To find the Pareto solutions for this model, the ε-Constraint technique is employed. Finally, the performance of the model in deterministic and uncertain modes is evaluated, compared and analyzed employing the inputs gathered from Shahid Rajaei port. The findings demonstrate that using this model will result in a substantial decrease in both fuel consumption and flow time of containers in comparison to the current procedure. Additionally, results will demonstrate the extent to which the terminal's fuel and time consumption will increase under conditions of uncertainty in operational parameters when the optimal plans derived from the robust model are implemented.



How to cite this paper
Fereidoonian, F., Sadjadi, S., Heydari, M & Al-e-hashem, S. (2024). A simultaneous time and fuel minimization robust possibilistic multiobjective programming approach for truck-sharing scheduling in container terminals.Decision Science Letters , 13(4), 1007-1026.

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Journal: Decision Science Letters | Year: 2024 | Volume: 13 | Issue: 4 | Views: 116 | Reviews: 0

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