Abstract—
The problem of optimal flow production planning at the operational scheduling stage is being studied, using the example of the out-of-furnace department of a converter-based steel-making production in the iron metallurgy industry. To solve this problem, a linear integer programming model is proposed, which fully describes the specifics of the investigated technological processes. A major advantage of this approach is its scalability for solving related optimization problems in the industry of plant logistics, as well as flexibility in adapting to changes and fine-tuning the system of constraints and objective function. The software implementation of the developed model forms the basis of the operational scheduling module of the optimal flow production planning system, which is used for a large-scale computational experiment on real-world data.
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The paper was supported by the Russian Science Foundation (project no. 23-21-00293).
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This paper was recommended for publication A.A. Lazarev, a member of the Editorial Board
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Kibzun, A.I., Rasskazova, V.A. Linear Integer Programming Model as Mathematical Ware for an Optimal Flow Production Planning System at Operational Scheduling Stage. Autom Remote Control 84, 529–542 (2023). https://doi.org/10.1134/S0005117923050065
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DOI: https://doi.org/10.1134/S0005117923050065