Abstract
In this article, we study machine repair problems (MRP) consisting of the finite number of operating machines with the provisioning of the finite number of warm standby machines under the care of a single unreliable server. For the machining system’s uninterrupted functioning, an operating machine is immediately replaced with the available warm standby machine in negligible switchover time whenever it fails. The concept of threshold vacation policy: N-policy is also considered. Under this vacation policy, the server starts to serve the failed machines on the accumulation of a pre-specified number of failed machines in the system. The server continues until the system is empty from the failed machines; after that, the server goes for vacation. The notion of an organizational delay, server breakdown, and repair in multiple phases is also conceptualized to build the studied model more realistic. The recursive matrix method is used to find steady-state queue size distribution, and subsequently, various system performance measures are also developed to validate the studied model. The optimal analysis has been performed to identify the critical design parameters for the governing model. The state-of-the-art of the present study is its mathematical modeling of the multi-machine stochastic problem with varied limitations and strategies. The methodology to obtain queue size distribution, optimal design parameters, is beneficial for dealing with other complex and sophisticated real-time machining problems in the service system, computer and communication system, manufacturing and production system, etc. The present problem is limited to fewer machines, which can be extended to more machines with different topologies with high computational facilities.
Highlights
IntroductionThe machine is an integral part of all industries, modernizations, and techno-socio advances, and it is subject to random failure
This paper differs from earlier published articles on machine repair problem in: (i) The present study considers the standby provisioning MRP with repair in phases and organizational delay; (ii) the varied reliability characteristics are observed and parametric analysis has been done; (iii) the expected total cost function has been formulated, and Newton-quasi method has been employed to get optimal parameters value
We investigate a machine repair problem (MRP) with the unreliable server having
Summary
The machine is an integral part of all industries, modernizations, and techno-socio advances, and it is subject to random failure. Machine repair problem (MRP) is the most worrying issue in manufacturing industries, computer networks, communication systems, production systems, transportation systems, flexible manufacturing systems, etc. Due to the unpredictable machine breakdown, there is a loss in production and a loss in time, resources, and cause inconvenience. To achieve optimal efficiency and reduce the production capacity’s loss, the system usually maintains standby machines in spare. At the time of a failure of any operating machine, the available standby machine automatically replaces perfectly in negligible switchover time. We study a machine repair problem having a finite number of operating and warm standby machines. The failure rate of the warm standby machine in the spare is less than that of the operating machine
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