Joint optimization of inspection, maintenance, and spare ordering policy considering defective products loss

doi:10.23919/JSEE.2021.000100

Journal of Systems Engineering and Electronics ›› 2021, Vol. 32 ›› Issue (5): 1167-1179.doi: 10.23919/JSEE.2021.000100

• SYSTEMS ENGINEERING • Previous Articles Next Articles

Joint optimization of inspection, maintenance, and spare ordering policy considering defective products loss

Mengying HAN^1,^2,³(), Jianhua YANG^1,^2,*(), Xiao ZHAO^1,²()

¹ School of Economics and Management, University of Science and Technology Beijing, Beijing 100083, China
² Beijing Enterprise Low-Carbon Operation Strategy Research Base, University of Science and Technology Beijing, Beijing 100083, China
³ School of Business, Hebei University of Economics and Business, Shijiazhuang 050061, China

Received:2020-10-12 Online:2021-10-18 Published:2021-11-04
Contact: Jianhua YANG E-mail:hanmengying1010@163.com;yangjh@ustb.edu.cn;617382194@qq.com
About author:|HAN Mengying was born in 1990. She is a Ph.D. candidate in the Department of Management Science and Engineering at the School of Economics and Management, University of Science and Technology Beijing. She obtained her M.S. degree in the Department of Management Science and Engineering of the University of Science and Technology Beijing in 2016. Her research focuses on reliability for complex system, preventive maintenance, and support engineering and management. E-mail: hanmengying1010@163.com||YANG Jianhua was born in 1965. He is a professor at the School of Economics and Management of University of Science and Technology Beijing, and currently the dean of the Department of Management Science and Engineering. He received his Ph.D. degree in Nanjing University of Science and Technology. His main research interests include quality management, operations and supply chain management, reliability for complex system, and support engineering and management. E-mail: yangjh@ustb.edu.cn||ZHAO Xiao was born in 1989. She is a Ph.D. candidate in the Department of Management Science and Engineering at the School of Economics and Management, University of Science and Technology Beijing. She obtained her M.S. degree in the University of Birmingham, U.K. Her main research interests include product quality, reliability for complex system, and preventive maintenance. E-mail: 617382194@qq.com
Supported by:
This work was supported by the National Natural Science Foundation of China (71471015) and the Social Science Fund Base Project of Beijing (19JDGLA001)

Abstract

Abstract:

This paper proposes a joint inspection-based maintenance and spare ordering optimization policy that considers the problem of integrated inspection, preventive maintenance, spare ordering, and quality control for a four-state single-unit manufacturing system. When an inspection detects a minor defect, a second phase inspection is initiated and a regular order is placed. Product quality begins to deteriorate when the system undergoes a severe defect. To counter this, an advanced replacement of the minor defective system is carried out at the $J{\rm{th}}$ second phase inspection. If a severe defect is recognized prior to the $J{\rm{th}}$ inspection, or if system failure occurs, preventive or corrective replacement is executed. The timeliness of replacement depends on the availability of spare. We adopt two modes of ordering: a regular order and an emergency order. Meanwhile, a threshold level is introduced to determine whether an emergency order is preferred even when the regular order is already ordered but has not yet arrived. The optimal joint inspection-based maintenance and spare ordering policy is formulated by minimizing the expected cost per unit time. A simulation algorithm is proposed to obtain the optimal two-phase inspection interval, threshold level and advanced replacement interval. Results from several numerical examples demonstrate that, in terms of the expected cost per unit time, our proposed model is superior to some existing models.

Key words: maintenance, two-phase inspection, spare ordering, three-stage failure process, delay-time model

Mengying HAN, Jianhua YANG, Xiao ZHAO. Joint optimization of inspection, maintenance, and spare ordering policy considering defective products loss[J]. Journal of Systems Engineering and Electronics, 2021, 32(5): 1167-1179.

Figures/Tables 17

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References 31

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X, Y, Z	Random variable representing the duration of the normal, minor defective, and defective states
x, y, z	Respective durations of the normal, minor defective and severe defective states
f_G(g)	Probability density function (PDF) of G (G= X, Y, Z; g = x, y, z)
T	The initial inspection interval
J, θ	Threshold level as decision variables
P	Production rate
L_r,L_e	Lead times of the regular order and the emergency (L_r > L_e)
C_in	Unit inspection cost
C_r,C_e	Replacement cost by a regular ordered spare and an emergency ordered spare (C_e > C_r)
C_f	Economic loss caused by a failure
C_h	Holding cost per unit time
C_w	Shortage cost per unit time
C_s	Unit loss of a defective item

Parameter	C_in	C_r	C_e	C_f	C_h	C_w	C_s	L_r	L_e
Value	5	50	80	400	0.2	4	0.5	30	3

Parameter	β₀	η	λ	γ
Value	0.004	0.08	10	4

Case	C_in	L_e	γ
Case 1	5	3	4
Case 2	10	3	4
Case 3	15	3	4
Case 4	5	9	4
Case 5	5	18	4
Case 6	5	3	3
Case 7	5	3	5

Case	Optimal result of Model 1				Optimal result of Model 2			Optimal result of Model 3
Case	T^*	J^*	θ^*	EC(T^, J^, θ^*)	T^*	θ^*	EC(T^,θ^)	T^*	J^*	EC(T^, J^)
Case 1	10	6	16	1.731 7	10	10	1.774 7	10	7	1.780 3
Case 2	12	5	23	2.227 5	11	16	2.335 3	12	5	2.273 7
Case 3	13	3	28	2.650 9	12	18	2.813 4	13	2	2.668 2
Case 4	9	7	19	1.744 6	10	18	1.778 8	10	8	1.807 8
Case 5	10	6	27	1.781 6	10	23	1.821 2	10	6	1.813 1
Case 6	10	4	16	1.845 0	9	17	1.910 8	9	6	1.880 2
Case 7	11	5	18	1.684 6	10	18	1.710 7	11	6	1.725 7

Joint optimization of inspection, maintenance, and spare ordering policy considering defective products loss

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