Abstract
Machine workshops generate high scrap rates, causing non-compliance with timely delivery and high production costs. Due to their natural characteristics of a low volume, high-mix production batches, and serial and parallel configurations, generally the causes of their failure are not well documented. Thus, to reduce the scrap rate, and evaluate and improve their reliability, their system characteristics must be considered. Based on them, our proposed methodology allows us to evaluate the system, subsystem, and component–subsystem relationship by using either the Weibull and/or the exponential distribution. The strategy to improve the system performance includes reliability tools, expert interviews, cluster analysis, and root-cause analysis. In the application case, the failure sources were found to be mechanical and human errors. The component maintenance/setup, institutional conditions/attitude, and subsystem process/operation were the machine factors that presented the lowest reliability indices. The improved activities were monitored based on the Weibull β and η parameters that affect the system reliability. Finally, by using a life–effort analysis, and the method of comparative analysis of two sequential periods, we identified the causes that generated a change in the Weibull parameters. The contribution of this methodology lies in the grouping of the tools in the proposed application context.
Highlights
Monitoring the reliability of components and subsystems and probability distribution parameters improves the reliability of the man–machine system of the machining area if it is complemented with tools for the identification of failure modes, such as the Failure Mode and Effects Analysis (FMEA), and actions are taken based on it
The failure analysis of a man–machine system is flexible because it allows us to include any quantity of components, systems, and component–subsystem relationships for the analyzed period
Parallel system approach proposed to assess the reliability of the man–machine system turned out to be efficient
Summary
Reliability theory allows us to analyze failures that occur in the components of a system over time; its application crosses diverse areas of knowledge, including health sciences [1,2,3], social sciences [4,5], engineering and technology [6,7,8], and industry in general [9]. The concept of reliability is used in maintenance, where it is necessary to keep machines in good working condition, under statistical control, and even avoiding variation. In manufacturing where computer numerical control (CNC) equipment plays an essential role in production, high reliability is desirable. Li et al [11] investigated the early failure of the Main Drive
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