Integrated reliability : condition monitoring and maintenance of equipment

 Content: Chapter 1: Overview for Condition Monitoring and Maintenance of Equipment in the Industries of the Future; Chapter 2: Integrated Reliability of Material-Part-Equipment System Life Cycle with the Technological Inheritance Technique; Chapter 3: Reliability Growth and Degradation of System Condition Monitoring with the Technological Inheritance Technique; Chapter 4: Role of Technological Inheritance Technique for Condition Monitoring and Maintenance of Industrial Equipment Chapter 5: Maximum Achievable Reliability Design for Critical Parts of Equipment with Technological Inheritance ModelChapter 6: Selection of Coating Materials, Parts, and Equipment System with the Technological Inheritance Technique; Chapter 7: Reliability Growth Condition of Coating Material and Deposition Process with a Technological Inheritance Model-Based Program; Chapter 8: Reliability Growth Condition of Machining and Grinding Processes of Hard-Coated Workpiece Surface; Chapter 9: Reliability Growth, Degradation, and Fatigue Failure of Nickel-Based Hard Alloy-Coated Part Surface Chapter 10: Reliability Degradation, Wear, and Competing Failure Modes of Nickel-Based Hard Alloy-Coated Part Mating SurfaceChapter 11: Integration of Reliability, Condition Monitoring, and Maintenance of Industrial Equipment; Chapter 12: Integrated Reliability of Equipment with a Technological Inheritance Model-Based Simulation Technique; Chapter 13: Integrated Reliability with a Technological Inheritance Model-Based Program in the Industries of the Future; Chapter 14: Integrated Reliability with a Technological Inheritance Model-Based Network Program in the Industries of the Future; Chapter 15: Integrated Reliability Management with a Technological Inheritance Model-Based Program in the Industries of the Future.
 Abstract:             "This text highlights the solutions to the common failures and reliability of equipment in major industries, through an integrated reliability condition monitoring, and maintenance with a technological inheritance model-based program. It relates all operating conditions of a critical cylindrical equipment part (shaft) throughout its life cycle, starting from design through manufacturing to actual equipment service application. The mathematical relationship of a desired operating manufacturing process and work-piece conditions is developed as a system multivariate quality model that relates with its part failure mechanism. "