Başlık:
Design for safety
Yazar:
Gullo, Louis J., editor.
ISBN:
9781118974315
9781118974308
9781118974339
Fiziksel Tanımlama:
1 online resource
Seri:
Quality and reliability engineering series
İçerik:
Series Editor's Foreword xvii Preface xix Acknowledgments xxiii Introduction: What You Will Learn xxv 1 Design for Safety Paradigms 1; Dev Raheja, Louis J.
You Are Likely to Discover the Right Practices 13 1.4 Create Your Own Paradigms 13 1.5 Summary 14 References 14 2 The History of System Safety 17; Jack Dixon 2.1 Introduction 17 2.2 Origins of System Safety 18 2.2.1 History of System Safety 19 2.2.2 Evolution of System Safety and Its Definitions 21 2.2.3 The Growth of System Safety 23 2.3 Tools of the Trade 30 2.4 Benefits of System Safety 31 2.5 System Safety Management 34 2.6 Integrating System Safety into the Business Process 34 2.6.1 Contracting for System Safety 34 References 36 Suggestions for Additional Reading 38 3 System Safety Program Planning and Management 39; Louis J.
Gullo and Jack Dixon 3.1 Management of the System Safety Program 39 3.1.1 System Safety Management Considerations 40 3.1.2 Management Methods and Concepts 41 3.2 Engineering Viewpoint 44 3.2.1 Software Tools 45 3.2.2 Design Concepts and Strategy 45 3.2.3 System Development Process (SDP) 46 3.2.4 Systems Engineering V?]Model 46 3.2.5 Requirements Generation and Analysis 48 3.2.6 System Analysis 49 3.2.7 System Testing 49 3.2.8 Risk Management 50 3.3 Safety Integrated in Systems Engineering 50 3.4 Key Interfaces 51 3.5 Planning, Execution, and Documentation 52 3.5.1 System Safety Program Plan 52 3.5.2 Safety Assessment Report 58 3.5.3 Plans Related to System Safety 60 3.6 System Safety Tasks 61 References 61 Suggestions for Additional Reading 62 4 Managing Risks and Product Liabilities 63; Louis J.
Gullo and Jack Dixon 4.1 Introduction 63 4.2 Risk 68 4.3 Risk Management 69 4.4 What Happens When the Paradigms for Design for Safety Are Not Followed? 71 4.5 Tort Liability 72 4.6 An Introduction to Product Liability Law 73 4.7 Famous Legal Court Cases Involving Product Liability Law 75 4.8 Negligence 77 4.9 Warnings 79 4.10 The Rush to Market and the Risk of Unknown Hazards 80 4.11 Warranty 81 4.12 The Government Contractor Defense 83 4.13 Legal Conclusions Involving Defective and Unsafe Products 84 References 85 Suggestions for Additional Reading 86 5 Developing System Safety Requirements 87; Louis J.
Gullo 5.1 Why Do We Need Safety Requirements? 87 5.2 Design for Safety Paradigm 3 Revisited 89 5.3 How Do We Drive System Safety Requirements? 93 5.4 What Is a System Requirement? 94 5.4.1 Performance Specifications 96 5.4.2 Safety Requirement Specification (SRS) 98 5.5 Hazard Control Requirements 98 5.6 Developing Good Requirements 100 5.6.1 Recognize Bad Requirements 101 5.6.2 Requirements at the Top of the Issues List 102 5.6.3 Examples Good Requirements for System Safety 103 5.6.4 Negative versus Positive Requirements 104 5.7 Example of Certification and Validation Requirements for a PSDI 105 5.8 Examples of Requirements from STANAG 4404 111 5.9 Summary 113 References 114 6 System Safety Design Checklists 115; Jack Dixon 6.1 Background 115 6.2 Types of Checklists 116 6.2.1 Procedural Checklists 116 6.2.2.
Observational Checklists 118 6.2.3 Design Checklists 119 6.3 Use of Checklists 122 References 123 Suggestions for Additional Reading 124 Additional Sources of Checklists 124 7 System Safety Hazard Analysis 125; Jack Dixon 7.1 Introduction to Hazard Analyses 125 7.1.1 Definition of Terms 126 7.2 Risk 126 7.3 Design Risk 127 7.3.1 Current State of the Art of Design Risk Management 127 7.3.2 Expression of Risk 127 7.3.3 Risk Management 128 7.4 Design Risk Management Methods and Hazard Analyses 135 7.4.1 Role of Hazard Analysis 135 7.5 Hazard Analysis Tools 136 7.5.1 Preliminary Hazard List 136 7.5.2 Preliminary Hazard Analysis 138 7.5.3 Subsystem Hazard Analysis (SSHA) 140 7.5.4 System Hazard Analysis (SHA) 143 7.5.5 Operating & Support Hazard Analysis (O & SHA) 145 7.5.6 Health Hazard Analysis (HHA) 148 7.6.
Hazard Tracking 150 7.7 Summary 152 References 152 Suggestions for Additional Reading 152 8 Failure Modes, Effects, and Criticality Analysis for System Safety 153; Louis J.
Improvement Actions 180 8.5.5 Performing PFMECA and Reporting Results 181 8.6 Conclusion 182 Acknowledgments 182 References 182 Suggestions for Additional Reading 183 9 Fault Tree Analysis for System Safety 185; Jack Dixon 9.1 Background 185 9.2 What Is a Fault Tree? 186 9.2.1 Gates and Events 187 9.2.2 Definitions 187 9.3 Methodology 189 9.4 Cut Sets 193 9.5 Quantitative Analysis of Fault Trees 198 9.6 Automated Fault Tree Analysis 199 9.7 Advantages and Disadvantages 200 9.8 Example 200 9.9 Conclusion 207 References 207 Suggestions for Additional Reading 208 10 Complementary Design Analysis Techniques 209; Jack Dixon 10.1 Background 209 10.2 Discussion of Less Used Techniques 210 10.2.1 Event Tree Analysis 210 10.2.2 Sneak Circuit Analysis 213 10.2.3 Functional Hazard.
Özet:
A one-stop reference guide to design for safety principles and applications Design for Safety (DfSa) provides design engineers and engineering managers with a range of tools and techniques for incorporating safety into the design process for complex systems. It explains how to design for maximum safe conditions and minimum risk of accidents. The book covers safety design practices, which will result in improved safety, fewer accidents, and substantial savings in life cycle costs for producers and users. Readers who apply DfSa principles can expect to have a dramatic improvement in the ability to compete in global markets. They will also find a wealth of design practices not covered in typical engineering books--allowing them to think outside the box when developing safety requirements. Design Safety is already a high demand field due to its importance to system design and will be even more vital for engineers in multiple design disciplines as more systems become increasingly complex and liabilities increase. Therefore, risk mitigation methods to design systems with safety features are becoming more important. Designing systems for safety has been a high priority for many safety-critical systems--especially in the aerospace and military industries. However, with the expansion of technological innovations into other market places, industries that had not previously considered safety design requirements are now using the technology in applications.
Design for Safety: Covers trending topics and the latest technologies Provides ten paradigms for managing and designing systems for safety and uses them as guiding themes throughout the book Logically defines the parameters and concepts, sets the safety program and requirements, covers basic methodologies, investigates lessons from history, and addresses specialty topics within the topic of Design for Safety (DfSa) Supplements other books in the series on Quality and Reliability Engineering Design for Safety is an ideal book for new and experienced engineers and managers who are involved with design, testing, and maintenance of safety critical applications. It is also helpful for advanced undergraduate and postgraduate students in engineering. Design for Safety is the second in a series of "Design for" books. Design for Reliability was the first in the series with more planned for the future.
Notlar:
John Wiley and Sons
Elektronik Erişim:
https://onlinelibrary.wiley.com/doi/book/10.1002/9781118974339Kopya:
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