Abstract
This paper studies the selective maintenance problem for a multi-state system (MSS) performing consecutive production missions with scheduled intermission breaks. To improve the reliability of the system successfully performing the next mission, all maintenance actions need to be carried out during maintenance breaks. However, it may not be feasible to repair all components due to the limited maintenance resources (such as time, costs, and manpower). Hence, a selective maintenance model was established to identify a subset of maintenance actions to perform on the repairable components. We extend the original model in several ways. First, we consider the role of degradation interaction in determining the state transition probability of each component. Back-propagation (BP) neural network is employed to predict the transition matrix since it is not practicable to analyze the degradation processes of all components using the traditional probability model. Second, a selective maintenance optimization model for an MSS is established based on the prediction results of the BP neural network and solved by a genetic algorithm (GA). Finally, an example is illustrated to verify the effectiveness and superiority of the proposed method.
Highlights
Many systems are required to perform a series of production missions separated by scheduled breaks
A selective maintenance optimization model for an multi-state system (MSS) with degradation interaction was investigated in this paper
The concept of degradation interaction is introduced to describe the relationship of state transition probability between components
Summary
Many systems are required to perform a series of production missions separated by scheduled breaks. Pandey et al [5] considered effective age in the selective maintenance model and included imperfect repair as a maintenance option In all these studies, the systems and components were assumed to be in only two possible functioning states: completely failed or perfect functioning. We focused on selective maintenance modeling based on the prediction results given by the Back-Propagation (BP) neural network (see [26]). We extend the selective maintenance model presented in Pandey et al [16] by considering the degradation interaction between components. The final objective of the selective maintenance optimization problem is to determine the best maintenance plan to maximize the MSS reliability in the production mission subject to the maintenance time and costs allotted to the break constraints.
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