Description
Reliability, Maintainability and Risk (10th Ed.)
Practical Methods for Engineers
Author: Smith David J.
Language: English
Subjects for Reliability, Maintainability and Risk:
Keywords
Active redundancy; Age replacement; Aircraft impact; ALARP; Allocation; AND; anecdotal; Appraisal; availability; Binomial; Block diagram; burn-in; Capability; chi-square; Common cause; Competence; complexity; Confidence; Consumer; continuous process; Contractual; Cost per life saved; CUSUM; Cutest; Dangerous; Data; Definitions; Demonstration; demonstration; Dependent; Design feature; Diagnostic coverage; Discard; discrimination; Earthquake; environment; error; event driven; Facilities; Failure; failure; Failure rate; failure rate; Fault; fault tolerance; Fault tree; Feasibility; FMEA; formal methods; Generic; Geometric mean; Growth; Guidelines; handbooks; Hazardous failure; HAZOP; Health and safety; HEART; human error; Industry-specific; Inference; Least replacement; Liability; Life-cycle; Lightning; location parameter; manuals; manufacturer; Manufacturer's; Markov; Maximum tolerable; mean down time; mean repair time
516 p. · 19x23.4 cm · Paperback
Description
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Reliability, Maintainability and Risk: Practical Methods for Engineers, Tenth Edition has taught reliability and safety engineers techniques to minimize process design, operation defects and failures for over 40 years. For beginners, the book provides tactics on how to avoid pitfalls in this complex and wide field. For experts in the field, well-described, realistic and illustrative examples and case studies add new insights and assistance. The author uses his more than 40 years of experience to create a comprehensive and detailed guide to the field, while also providing an excellent description of reliability and risk computation concepts.
The book is organized into many parts, covering reliability parameters and costs, the history of reliability and safety technology, a cost-effective approach to quality, reliability and safety, how to interpret failure rates, a focus on the prediction of reliability and risk, a discussion of design and assurance techniques, and much more.
1. The History of Reliability and Safety Technology 2. Understanding Terms and Jargon 3. A Cost-Effective Approach to Quality, Reliability and Safety 4. Realistic Failure Rates and Prediction Confidence 5. Interpreting Data and Demonstrating Reliability 6. Variable Failure Rates and Probability Plotting 7. Basic Reliability Prediction Theory 8. Methods of Modelling 9. Quantifying the Reliability Models 10. Risk Assessment (QRA) 11. Design and Assurance Techniques 12. Design Review, Test and Reliability Growth 13. Field Data Collection and Feedback 14. Factors Influencing Down Time 15. Predicting and Demonstrating Repair Times 16. Quantified Reliability Centred Maintenance 17. Systematic Failures, Especially Software 18. Project Management and Competence 19. Contract Clauses and Their Pitfalls 20. Product Liability and Safety Legislation 21. Major Incident Legislation 22. Integrity of Safety Related Systems 23. A Case Study: The Datamet Project 24. A Case Study: Gas Detection System 25. A Case Study: Pressure Control System 26. A Case Study: Helicopter Incidents and Risk Assessment
- Covers models for partial valve stroke test, fault tree logic and quantification difficulties
- Includes more detail on the use of tools such as FMEDA and programming standards like MISRA
- Presents case studies on the Datamet Project, Gas Detection System, Pressure Control System, and Helicopter Incidents and Risk Assessment
- Provides user exercises and answers
