Production control problem integrating overhaul and subcontracting strategies for a quality deteriorating manufacturing system

Rivera-Gómez, Héctor; Gharbi, Ali; Kenné, Jean‐Pierre; Montaño-Arango, Oscar; Gress, Eva Selene Hernández

doi:10.1016/j.ijpe.2015.10.008

Cited by 40 publications

(13 citation statements)

References 35 publications

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“…The given studies focused on the importance of IT in the control of demand of consumer goods in a market. Many researchers have considered a deteriorating production system with deterministic demand rates in existing literature as mentioned in [32,59]. An unreliable manufacturing system with random demand rate is examined by [60] for a paper manufacturing process.…”

Section: Technology Dependent Demandmentioning

confidence: 99%

An Automated Smart EPQ-Based Inventory Model for Technology-Dependent Products under Stochastic Failure and Repair Rate

Asghar

Kim

2020

Symmetry

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With the ever-growing technology development, high-tech products such as mobile phones, computers, electromagnetic devices and smart devices are facing high design and production modification requirements with relatively shorter life cycles. For instance, every forthcoming smart phone goes out of production in a shorter period after its launch, followed by its next generation. The design of high-tech products requires high investments in smart and automated manufacturing technology to ensure higher production efficiency. For high-tech products with short life spans, the manufacturing performance-quality variable is an important design parameter that affects system reliability, production efficiency and manufacturing costs. Major performance-quality factors of a manufacturing system which affect productivity and reliability of the manufacturing process are discussed in this research. The study investigates an integrated smart production maintenance model under stochastic manufacturing reliability for technology dependent demand and variable production rate. The smart unit production cost is a function of manufacturing reliability and controllable production rate, as a manufacturing system can be operated at different production rates within designed limits μ ϵ [ μ m i n , μ m a x ] . Manufacturing reliability is increased through investment in smart manufacturing technology and resources. The integrated smart production maintenance model is formulated under general failure and repair time distributions and the optimal production maintenance policy is investigated under specific failure and repair time distributions. A mathematical model is developed to optimize the manufacturing quality-performance parameter, variable production rate, per unit technology investment and production lot size. The total cost function is optimized through the Khun–Tucker method. The mathematical model is also validated with numerical analysis, comparative study, and sensitivity analysis for model key parameters.

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Section: Technology Dependent Demandmentioning

confidence: 99%

An Automated Smart EPQ-Based Inventory Model for Technology-Dependent Products under Stochastic Failure and Repair Rate

Asghar

Kim

2020

Symmetry

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“…where φ (•) is the function that making v (α, x) attain its maximum at x = x 0 in a neighborhood N (x 0 ). In order to prove that v is a viscosity supersolution, one can suppose v is not viscosity supersolution first, i.e., there exist x 0 and δ 0 > 0 such that (28) in a neighborhood N 0 (x 0 ), where ϕ (•) is the function that making v (α, x) attain its minimum at x = x 0 in a neighborhood N 0 (x 0 ). And then, one can derive a contradiction v (α, x) ≥ v (α, x) + η with η > 0 to show that v is a viscosity supersolution.…”

Section: Elementary Properties Of Value Functionmentioning

confidence: 99%

Optimization of Boiler Soot Blowing Based on Hamilton-Jacobi-Bellman Equation

et al. 2019

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In this paper, the optimization of the boiler soot blowing is investigated based on the Hamilton-Jacobi-Bellman (HJB) equation and from the standpoint of the equipment health management. The mathematical model of the boiler soot blowing is built by a Markov process with two modes: soot deposition mode and soot blowing mode. In order to obtain the optimal soot blowing strategies via the HJB method, a cost function is constructed according to the proposed boiler soot blowing model. Considering the solution's existence of the HJB equation, the elementary properties of the value function are described and proved. It is difficult to solve the HJB equation analytically, so Kushner's method is applied to get the numerical solution of the HJB equation. Moreover, the sensitivity analyses for the effects of different parameters are shown via a set of numerical simulations.

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“…Discrete event simulation is an important tool used in different fields for modeling, analyzing, and solving real problems that are generally complex, large size, dynamic, and stochastic. In particular, simulation, characterized by its high flexibility and speed, has been embedded with different robust tools to support optimization in a variety of applications, including supply chain, 1,2 manufacturing systems, 3,4 and operations scheduling. 5,6 Simulation-based optimization is used when seeking different input decision variables, to produce a desired output objective function.…”

Section: Introductionmentioning

confidence: 99%

Performance optimization of a flexible manufacturing system using simulation: the Taguchi method versus OptQuest

et al. 2019

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The Taguchi method is widely used in the field of manufacturing systems performance simulation and improvement. On the other hand, Arena/OptQuest is one of the most efficient contemporary simulation/optimization software tools. The objective of this paper is to evaluate and compare these two tools applied to a flexible manufacturing system performance optimization context, based on simulation. The principal purpose of this comparison is to determine their performances based on the quality of the obtained results and the gain in the simulation effort. The results of the comparison, applied to a flexible manufacturing system mean flow time optimization, show that the Arena/OptQuest optimization platform outperforms the Taguchi optimization method. Indeed, the Arena/OptQuest permits one, through the lowest experimental effort, to reliably minimize the mean flow time of the studied flexible manufacturing system more than the Taguchi method.

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Production control problem integrating overhaul and subcontracting strategies for a quality deteriorating manufacturing system

Cited by 40 publications

References 35 publications

An Automated Smart EPQ-Based Inventory Model for Technology-Dependent Products under Stochastic Failure and Repair Rate

An Automated Smart EPQ-Based Inventory Model for Technology-Dependent Products under Stochastic Failure and Repair Rate

Optimization of Boiler Soot Blowing Based on Hamilton-Jacobi-Bellman Equation

Performance optimization of a flexible manufacturing system using simulation: the Taguchi method versus OptQuest

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