Provide a hybrid model of two production scheduling objectives, with limited resources with a preventive maintenance approach

Sharifzadegan, Mohamad; Sohrabi, Tahmourth; Jafarnejad Chaghoshi,, Ahmad

doi:10.22105/dmor.2021.278207.1343

Document Type : Original Article

Authors

¹ Department of Management, Central Tehran Branch, Islamic Azad University, Tehran, Iran.

² Department of Industrial Management, University of Tehran, Tehran, Iran.

https://doi.org/10.22105/dmor.2021.278207.1343

Abstract

Purpose: The complex conditions prevailing in the industries and the increasing costs of production equipment and machinery and competitiveness in gaining market share, show the role and importance of production planning and maintenance with other parts of the industry. Integrating such decisions can take fundamental steps to reduce costs and increase quality. Maintaining and creating the continuity of production activities depends on accurate and correct planning of production, maintenance activities and how to support these processes. The need for integration and coherence in the simultaneous planning of such activities causes a lack of rework and parallel work and obstacles and delays and inconsistencies at different levels of production.
Methodology: In this research, a two-objective mathematical model of production planning and repairs with limited resources is presented in conditions of uncertainty.
Findings: The results of comparing accurate and meta-innovative solutions show the improvement in the company's products and the optimal use of material and human resources. Sensitivity analysis also shows that the failure rate of the machine before and after preventive maintenance has a great impact on the value of the objective function of the mathematical model. The results show that the average error of the ant algorithm is only 3%. This is while the average solving time in GAMZ is 45,000 seconds, while the average solving time of the ant algorithm is about 354 seconds.
Originality/Value: This shows that the ant algorithm has a very small amount of error with much less time and therefore the efficiency of this solution method can be well explained.

Keywords

Main Subjects

stochastic/Probabilistic/fuzzy/dynamic modeling

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Journal of Decisions and Operations Research

Provide a hybrid model of two production scheduling objectives, with limited resources with a preventive maintenance approach

References

References

Volume 6, Special Issue
January 2022
Pages 1-17

Provide a hybrid model of two production scheduling objectives, with limited resources with a preventive maintenance approach

References

References

Volume 6, Special IssueJanuary 2022Pages 1-17

Volume 6, Special Issue
January 2022
Pages 1-17