Hoboken, New Jersey : , : Wiley, , 2014

©2014

1-118-84171-9

1-118-84179-4

1-118-84168-9

1 online resource (514 p.)

Wiley Series in Systems Engineering and Management

620/.00452

Reliability (Engineering)

Inglese

Includes index.

Includes bibliographical references and index.

Cover; Title page; Copyright page; Contents; Preface; 1: Reliability Engineering in the Twenty-First Century; 1.1 What Is Quality?; 1.2 What Is Reliability?; 1.2.1 The Ability to Perform as Intended; 1.2.2 For a Specified Time; 1.2.3 Life-Cycle Conditions; 1.2.4 Reliability as a Relative Measure; 1.3 Quality, Customer Satisfaction, and System Effectiveness; 1.4 Performance, Quality, and Reliability; 1.5 Reliability and the System Life Cycle; 1.6 Consequences of Failure; 1.6.1 Financial Loss; 1.6.2 Breach of Public Trust; 1.6.3 Legal Liability; 1.6.4 Intangible Losses

1.7 Suppliers and Customers1.8 Summary; Problems; 2: Reliability Concepts; 2.1 Basic Reliability Concepts; 2.1.1 Concept of Probability Density Function; 2.2 Hazard Rate; 2.2.1 Motivation and Development of Hazard Rate; 2.2.2 Some Properties of the Hazard Function; 2.2.3 Conditional Reliability; 2.3 Percentiles Product Life; 2.4 Moments of Time to Failure; 2.4.1 Moments about Origin and about the Mean; 2.4.2 Expected Life or Mean Time to Failure; 2.4.3 Variance or the Second Moment about the Mean; 2.4.4 Coefficient of Skewness; 2.4.5 Coefficient of Kurtosis; 2.5 Summary; Problems

3: Probability and Life Distributions for Reliability Analysis3.1 Discrete Distributions; 3.1.1 Binomial Distribution; 3.1.2 Poisson Distribution; 3.1.3 Other Discrete Distributions; 3.2 Continuous Distributions; 3.2.1

Weibull Distribution; 3.2.2 Exponential Distribution; 3.2.3 Estimation of Reliability for Exponential Distribution; 3.2.4 The Normal (Gaussian) Distribution; 3.2.5 The Lognormal Distribution; 3.2.6 Gamma Distribution; 3.3 Probability Plots; 3.4 Summary; Problems; 4: Design for Six Sigma; 4.1 What Is Six Sigma?; 4.2 Why Six Sigma?; 4.3 How Is Six Sigma Implemented?

4.3.1 Steps in the Six Sigma Process4.3.2 Summary of the Six Sigma Steps; 4.4 Optimization Problems in the Six Sigma Process; 4.4.1 System Transfer Function; 4.4.2 Variance Transmission Equation; 4.4.3 Economic Optimization and Quality Improvement; 4.4.4 Tolerance Design Problem; 4.5 Design for Six Sigma; 4.5.1 Identify (I); 4.5.2 Characterize (C); 4.5.3 Optimize (O); 4.5.4 Verify (V); 4.6 Summary; Problems; 5: Product Development; 5.1 Product Requirements and Constraints; 5.2 Product Life Cycle Conditions; 5.3 Reliability Capability; 5.4 Parts and Materials Selection

5.5 Human Factors and Reliability5.6 Deductive versus Inductive Methods; 5.7 Failure Modes, Effects, and Criticality Analysis; 5.8 Fault Tree Analysis; 5.8.1 Role of FTA in Decision-Making; 5.8.2 Steps of Fault Tree Analysis; 5.8.3 Basic Paradigms for the Construction of Fault Trees; 5.8.4 Definition of the Top Event; 5.8.5 Faults versus Failures; 5.8.6 Minimal Cut Sets; 5.9 Physics of Failure; 5.9.1 Stress Margins; 5.9.2 Model Analysis of Failure Mechanisms; 5.9.3 Derating; 5.9.4 Protective Architectures; 5.9.5 Redundancy; 5.9.6 Prognostics; 5.10 Design Review; 5.11 Qualification

5.12 Manufacture and Assembly

Using the authors' extensive experience in both industry and academia, this book presents an integrated approach for design, engineering and management of the reliability activities throughout the life cycle of a product which includes concept, research and development, design, manufacturing, assembly, sales and service. The coverage explains how to integrate reliability methods and techniques in the Six Sigma Process and Design for Six Sigma. It also discusses relationships between warranty and reliability, as well as legal and liability issues. This useful guide teaches readers how to effect