A two-stage coupled algorithm for an integrated maintenance planning and flowshop scheduling problem with deteriorating machines

Bajestani, Maliheh Aramon; Beck, J. Christopher

doi:10.1007/s10951-015-0416-2

Cited by 19 publications

(6 citation statements)

References 65 publications

(93 reference statements)

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“…In the third stage, goal programming is applied and the optimal positions and the frequencies of the maintenance activities are determined. Simultaneous consideration of deteriorating jobs and resource constraints is also addressed for the flow shop environment in the study by Aramon Bajestani & Beck (2015) . A finite planning horizon is considered, which is composed of K discrete time periods, each T time units long.…”

Section: Resources and Maintenancementioning

confidence: 99%

Production, maintenance and resource scheduling: A review

Geurtsen

Didden

Adan

et al. 2023

European Journal of Operational Research

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Section: Resources and Maintenancementioning

confidence: 99%

Production, maintenance and resource scheduling: A review

Geurtsen

Didden

Adan

et al. 2023

European Journal of Operational Research

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“…k ← 0, feasible ← false; repeat if master problem ( 5) is infeasible then stop; original problem (2) is infeasible; end let x k be an optimal solution of ( 5) with value z k ; solve subproblem (7)…”

Section: Fundamentals Of Lbbdmentioning

confidence: 99%

“…LBBD applications to shop and factory scheduling include aircraft repair shop scheduling [6], job shop scheduling with human resurce constraints [51], permutation flowshop scheduling with time lags [52,53], one-machine scheduling problems [22,104,105], and flowshop planning and scheduling with deteriorating machines [7]. There is also an application to feature-based assembly planning [71].…”

Section: Shop Factory and Employee Schedulingmentioning

confidence: 99%

Logic-Based Benders Decomposition for Large-Scale Optimization

Hooker

2019

Springer Optimization and Its Applications

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Logic-based Benders decomposition (LBBD) is a substantial generalization of classical Benders decomposition that, in principle, allows the subproblem to be any optimization problem rather than specifically a linear or nonlinear programming problem. It is amenable to a wide variety large-scale problems that decouple or otherwise simplify when certain decision variables are fixed. This chapter presents the basic theory of LBBD and explains how classical Benders decomposition is a special case. It also describes branch and check, a variant of LBBD that solves the master problem only once. It illustrates in detail how Benders cuts and subproblem relaxations can be developed for some planning and scheduling problems. It then describes the role of LBBD in three large-scale case studies. The chapter concludes with an extensive survey of the LBBD literature, organized by problem domain, to allow the reader to explore how Benders cuts have been developed for a wide range of applications.

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“…the subassemblies/components must be available for an assembly process to take place. Bajestani and Beck (2015) / / / / Hadidi et al (2015) / / / Hedjazi (2015) / / / Nie, Xu, and Tu (2015) / / Qi, Wan, and Yan (2015) / Von Hoyningen-Huene and Kiesmuller (2015 The objective of this work was to find an optimal schedule which minimised total costs (including penalty costs caused by tardiness and earliness, holding costs due to work-in-process and costs due to assembly, setup, production, transfer, production idle time and maintenance).…”

Section: Problem Description and Model Developmentmentioning

confidence: 99%

A mixed-integer linear programming model for integrated production and preventive maintenance scheduling in the capital goods industry

Chansombat

Pongcharoen

Hicks

2018

International Journal of Production Research

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Newcastle University ePrints | eprint.ncl.ac.uk Chansombat S, Pongcharoen P, Hicks C. A mixed-integer linear programming model for integrated production and preventive maintenance scheduling in the capital goods industry. AbstractThe scheduling literature is extensive, but much of this work is theoretical and does not capture the complexity of real world systems. Capital goods companies produce products with deep and complex product structures, each of which requires the coordination of jobbing, batch, flow and assembly processes. Many components require numerous operations on multiple machines. Integrated scheduling problems simultaneously consider two or more simultaneous decisions. Previous production scheduling research in the capital goods industry has neglected maintenance scheduling and used metaheuristics with stochastic search that cannot guarantee an optimal solution. This paper presents a novel mixed integer linear programming (MILP) model for simultaneously solving the integrated production and preventive maintenance scheduling problem in the capital goods industry, which was tested using data from a collaborating company. The objective was to minimise total costs including: tardiness and earliness penalty costs; component and assembly holding costs; preventive maintenance costs; and setup, production, transfer and production idle time costs. Thus, the objective function and problem formulation were more extensive than previous research. The tool was successfully tested using data obtained from a collaborating company. It was found that the company's total cost could be reduced by up to 63.5%.

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A two-stage coupled algorithm for an integrated maintenance planning and flowshop scheduling problem with deteriorating machines

Cited by 19 publications

References 65 publications

Production, maintenance and resource scheduling: A review

Production, maintenance and resource scheduling: A review

Logic-Based Benders Decomposition for Large-Scale Optimization

A mixed-integer linear programming model for integrated production and preventive maintenance scheduling in the capital goods industry

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