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书名:可靠性工程(英文版)
定价:230.0
ISBN:9787030776679
作者:孙有超,李龙彪
版次:1
出版时间:2023-12
内容提要:
本书在作者多年从事可靠性理论、方法、工程和技术应用的教学与科学研究工作的基础上,阐述了可靠性理论、方法、工程及应用,涵盖可靠性数学、可靠性工程、可靠性物理等内容,强调基本理论与技术的系统性、融合性与前瞻性,反映了可靠性研究领域前沿的…新理论与方法,丰富和充实已有的可靠性理论与技术体系。
目录:
Contents
1 Introduction 1
1.1 Basic Concepts of Reliability Theory 1
1.2 Main Indicators of Reliability 4
1.2.1 Failure-Free Indicators 5
1.2.2 Durability Indicators 5
1.2.3 Indicators of Maintainability and Preservation 6
1.2.4 Complex Indicators 6
1.3 Base Dependencies of the Reliability Theory 6
1.4 Reliability During Regular Operation 9
1.5 Reliability During Gradual Failures 12
1.5.1 The Normal Distribution 12
1.5.2 The Truncated Normal Distribution 16
1.5.3 In a Log-Normal Distribution 17
1.5.4 The Weibull Distribution 19
1.6 Combined Action of Sudden and Gradual Failures 22
1.7 Features of the Reliability of Recoverable Products 23
1.8 Questions 24
References 25
2 Mathematical Basis of Reliability 27
2.1 Introduction 27
2.2 Random Events and Probabilities 27
2.3 Numerical Features and Distributions of Random Variables 30
2.3.1 Mathematical Expectation 30
2.3.2 Dispersion 31
2.3.3 Average Square-Law Deviation 32
2.3.4 Moments of Distribution 32
2.3.5 Asymmetry 33
2.3.6 Excess 34
2.3.7 Mode of Discrete Random Variable 34
2.3.8 Median of Random Variable 35
2.4 Distribution Functions of Random Variables 35
2.4.1 Distribution Functions for Discrete Random Variables 35
2.4.2 Distribution Functions for Continuous Random Variables 37
2.5 Questions 41
References 42
3 System Reliability Models 43
3.1 Introduction 43
3.2 Non-repair System Reliability Analysis 44
3.2.1 Classification of System Reliability Function 44
3.2.2 Analysis of the Reliability Function 45
3.2.3 Redundancy System Reliability 49
3.2.4 Methods of the Reliability Function 53
3.3 Repair System Reliability Analysis 57
3.3.1 General Information 57
3.3.2 System Reliability Function 63
3.3.3 Non-parametric Analysis Methods 75
3.3.4 Parametric Analysis Methods 85
3.3.5 Markov Chain and Its Application 100
3.4 Questions 122
References 123
4 Complex System Reliability Analysis Methods 125
4.1 Introduction 125
4.2 Failure Mode and Effect Critical Analysis 126
4.2.1 Basic Concepts 126
4.2.2 Types ofFMECA 127
4.2.3 Steps for FMECA 128
4.2.4 Criticality Assessment 131
4.2.5 FMEC A Application 135
4.3 Fault Tree Analysis 139
4.3.1 Basic Concepts 140
4.3.2 Basic Approach 142
4.3.3 Qualitative Analysis 145
4.3.4 Quantitative Analysis 147
4.3.5 Reliability Graph 156
4.3.6 FTA Application 157
4.4 Comparison FMEC A and FTA 159
4.5 Questions 160
References 161
5 Model-Based Reliability Analysis Methods 163
5.1 Introduction 163
5.2 Multi-Source Reliability Data Processing System for Mechanical Parts 1…
5.2.1 Comprehensive Reliability Assessment Model
Based on Multi-Source Data 165
5.2.2 Case Study 170
5.3 Multi-Phase Mission Reliability Analysis 174
5.3.1 PMS System Characteristics 174
5.3.2 PMS Reliability Modeling Process 175
5.3.3 Static Reliability Analysis Method Based on BDD 176
5.3.4 Dynamic Reliability Analysis Method Based
on Semi-Markov 182
5.3.5 Modular Analysis Method 185
5.3.6 Case Study 185
5.4 Conclusions 191
References 192
6 System Reliability Prediction and Allocation 193
6.1 Introduction 193
6.2 Reliability Prediction 194
6.2.1 Reliability Block Diagram 194
6.2.2 Series Systems 195
6.2.3 Parallel Systems 199
6.2.4 Combined Structure 201
6.2.5 ib-Out-of-n Systems 204
6.2.6 Redundant System 207
6.2.7 Reliability Evaluation of Complex Systems 212
6.2.8 Confidence Ranges for System Reliability 217
6.2.9 Component Importance 226
6.3 Reliability Allocation 232
6.3.1 Criteria for Reliability Allocation 233
6.3.2 Equal Allocation Approach 234
6.3.3 ARINC Approach 235
6.3.4 AGREE Allocation Approach 237
6.3.5 Customer-Driven Allocation Approach 240
6.3.6 Optimal Allocation Approaches 242
6.4 Questions 244
References 245
7 Mechanical Reliability Analysis 247
7.1 Introduction 247
7.2 Basic Concepts 248
7.2.1 Types of Operational Loads 248
7.2.2 Specifics of Static Load 249
7.2.3 Specifics of Cycling Loading 251
7.2.4 Specifics of Temperature Effect 255
7.2.5 Creep and Relaxation of Stresses 259
7.3 Factors Affect Mechanical Reliability 261
7.3.1 Corrosion 261
7.3.2 Chemical Medium 263
7.3.3 Fields Environment 2…
7.3.4 Space Medium 266
7.3.5 Structural Materials,Selection 267
7.4 Short Observe of Structural Elements 269
7.5 Probabilistic Calculations of Machinery Parts 272
7.5.1 Some Aspects of Probability Theory for Machinery Parts 273
7.5.2 Specifics of Probabilistic Strength Computing of Shafts and Axles 276
7.5.3 Computing Examples for Various Machinery Components 279
7.6 Civil Aircraft Jettison Fuel Subsystem Reliability Analysis 284
7.6.1 Background for the Computation 284
7.6.2 Risks and Challenges of Aircraft Fuel Jettison Subsystem 288
7.6.3 Function Hazard Assessment 289
7.6.4 Primary System Safety Assessment Facing
on Reliability Distribution 292
7.6.5 Reliability Analysis of Each Independent Fuel Tank for Dumping 298
7.6.6 Reliability Analysis of the Whole Fuel Jettison Subsystem 302
7.7 Conclusions 304
7.8 Questions 305
References 305
8 Reliability Tests 307
8.1 Introduction 307
8.1.1 Targets of Reliability and Life Tests 308
8.1.2 Specifics of Life Tests and Reliability 309
8.1.3 Test Types 310
8.1.4 Test Planning and Documentation 315
8.2 Reliability Tests Plan 317
8.2.1 Types of Tests 318
8.2.2 Test Samples 320
8.2.3 Test Stresses 320
8.2.4 Test Time 321
8.3 Zero-Failure Test 322
8.3.1 Binomial Zero-Failure Testing 323
8.3.2 Weibull Zero-Failure Testing 325
8.4 Lite Tests 32^
8.4.1 Theoretical Concept 329
8.4.2 Binomial Series Life Testing 332
8.4.3 Exponential Series Life Testing 337
8.4.4 Weibull Series Life Testing 339
8.5 Accelerated Tests 341
8.5.1 Principles for Accelerating Tests 341
8.5.2 Operational Cycles Compressing 342
8.5.3 Extrapolation in Time 343
8.5.4 Revision of Loading Range 344
8.5.5 Increased Frequency of Operational Cycles 345
8.5.6 Loading Extrapolation 345
8.5.7 Break Completely 347
8.5.8 Progressive Load Forcing 347
8.5.9 Alternating Modes Loading 350
8.5.10 Some Specifics of the Accelerated Tests 353
8.6 Verification of Reliability Based on Prior Information 354
8.7 Verification of Reliability by Means of Degradation Tests 356
8.8 Questions 358
References 359
9 Risk Analysis of Aircraft Structure and Systems 361
9.1 Introduction 361
9.2 Risk Assessment of Aeroengine Life-Limited Parts 362
9.2.1 ELLPS Airworthiness Regulations and AC Analysis 363
9.2.2 Determination Method of ELLPs Based on FMEA 368
9.2.3 Probabilistic Risk Assessment of ELLPs 373
9.2.4 Case Analysis 382
9.3 Risk Warning of Aircraft Bleed Air System 386
9.3.1 Risk Warning Method 387
9.3.2 Application of Risk Warning on the BAS 394
9.4 Conclusions 411
References 413
定价:230.0
ISBN:9787030776679
作者:孙有超,李龙彪
版次:1
出版时间:2023-12
内容提要:
本书在作者多年从事可靠性理论、方法、工程和技术应用的教学与科学研究工作的基础上,阐述了可靠性理论、方法、工程及应用,涵盖可靠性数学、可靠性工程、可靠性物理等内容,强调基本理论与技术的系统性、融合性与前瞻性,反映了可靠性研究领域前沿的…新理论与方法,丰富和充实已有的可靠性理论与技术体系。
目录:
Contents
1 Introduction 1
1.1 Basic Concepts of Reliability Theory 1
1.2 Main Indicators of Reliability 4
1.2.1 Failure-Free Indicators 5
1.2.2 Durability Indicators 5
1.2.3 Indicators of Maintainability and Preservation 6
1.2.4 Complex Indicators 6
1.3 Base Dependencies of the Reliability Theory 6
1.4 Reliability During Regular Operation 9
1.5 Reliability During Gradual Failures 12
1.5.1 The Normal Distribution 12
1.5.2 The Truncated Normal Distribution 16
1.5.3 In a Log-Normal Distribution 17
1.5.4 The Weibull Distribution 19
1.6 Combined Action of Sudden and Gradual Failures 22
1.7 Features of the Reliability of Recoverable Products 23
1.8 Questions 24
References 25
2 Mathematical Basis of Reliability 27
2.1 Introduction 27
2.2 Random Events and Probabilities 27
2.3 Numerical Features and Distributions of Random Variables 30
2.3.1 Mathematical Expectation 30
2.3.2 Dispersion 31
2.3.3 Average Square-Law Deviation 32
2.3.4 Moments of Distribution 32
2.3.5 Asymmetry 33
2.3.6 Excess 34
2.3.7 Mode of Discrete Random Variable 34
2.3.8 Median of Random Variable 35
2.4 Distribution Functions of Random Variables 35
2.4.1 Distribution Functions for Discrete Random Variables 35
2.4.2 Distribution Functions for Continuous Random Variables 37
2.5 Questions 41
References 42
3 System Reliability Models 43
3.1 Introduction 43
3.2 Non-repair System Reliability Analysis 44
3.2.1 Classification of System Reliability Function 44
3.2.2 Analysis of the Reliability Function 45
3.2.3 Redundancy System Reliability 49
3.2.4 Methods of the Reliability Function 53
3.3 Repair System Reliability Analysis 57
3.3.1 General Information 57
3.3.2 System Reliability Function 63
3.3.3 Non-parametric Analysis Methods 75
3.3.4 Parametric Analysis Methods 85
3.3.5 Markov Chain and Its Application 100
3.4 Questions 122
References 123
4 Complex System Reliability Analysis Methods 125
4.1 Introduction 125
4.2 Failure Mode and Effect Critical Analysis 126
4.2.1 Basic Concepts 126
4.2.2 Types ofFMECA 127
4.2.3 Steps for FMECA 128
4.2.4 Criticality Assessment 131
4.2.5 FMEC A Application 135
4.3 Fault Tree Analysis 139
4.3.1 Basic Concepts 140
4.3.2 Basic Approach 142
4.3.3 Qualitative Analysis 145
4.3.4 Quantitative Analysis 147
4.3.5 Reliability Graph 156
4.3.6 FTA Application 157
4.4 Comparison FMEC A and FTA 159
4.5 Questions 160
References 161
5 Model-Based Reliability Analysis Methods 163
5.1 Introduction 163
5.2 Multi-Source Reliability Data Processing System for Mechanical Parts 1…
5.2.1 Comprehensive Reliability Assessment Model
Based on Multi-Source Data 165
5.2.2 Case Study 170
5.3 Multi-Phase Mission Reliability Analysis 174
5.3.1 PMS System Characteristics 174
5.3.2 PMS Reliability Modeling Process 175
5.3.3 Static Reliability Analysis Method Based on BDD 176
5.3.4 Dynamic Reliability Analysis Method Based
on Semi-Markov 182
5.3.5 Modular Analysis Method 185
5.3.6 Case Study 185
5.4 Conclusions 191
References 192
6 System Reliability Prediction and Allocation 193
6.1 Introduction 193
6.2 Reliability Prediction 194
6.2.1 Reliability Block Diagram 194
6.2.2 Series Systems 195
6.2.3 Parallel Systems 199
6.2.4 Combined Structure 201
6.2.5 ib-Out-of-n Systems 204
6.2.6 Redundant System 207
6.2.7 Reliability Evaluation of Complex Systems 212
6.2.8 Confidence Ranges for System Reliability 217
6.2.9 Component Importance 226
6.3 Reliability Allocation 232
6.3.1 Criteria for Reliability Allocation 233
6.3.2 Equal Allocation Approach 234
6.3.3 ARINC Approach 235
6.3.4 AGREE Allocation Approach 237
6.3.5 Customer-Driven Allocation Approach 240
6.3.6 Optimal Allocation Approaches 242
6.4 Questions 244
References 245
7 Mechanical Reliability Analysis 247
7.1 Introduction 247
7.2 Basic Concepts 248
7.2.1 Types of Operational Loads 248
7.2.2 Specifics of Static Load 249
7.2.3 Specifics of Cycling Loading 251
7.2.4 Specifics of Temperature Effect 255
7.2.5 Creep and Relaxation of Stresses 259
7.3 Factors Affect Mechanical Reliability 261
7.3.1 Corrosion 261
7.3.2 Chemical Medium 263
7.3.3 Fields Environment 2…
7.3.4 Space Medium 266
7.3.5 Structural Materials,Selection 267
7.4 Short Observe of Structural Elements 269
7.5 Probabilistic Calculations of Machinery Parts 272
7.5.1 Some Aspects of Probability Theory for Machinery Parts 273
7.5.2 Specifics of Probabilistic Strength Computing of Shafts and Axles 276
7.5.3 Computing Examples for Various Machinery Components 279
7.6 Civil Aircraft Jettison Fuel Subsystem Reliability Analysis 284
7.6.1 Background for the Computation 284
7.6.2 Risks and Challenges of Aircraft Fuel Jettison Subsystem 288
7.6.3 Function Hazard Assessment 289
7.6.4 Primary System Safety Assessment Facing
on Reliability Distribution 292
7.6.5 Reliability Analysis of Each Independent Fuel Tank for Dumping 298
7.6.6 Reliability Analysis of the Whole Fuel Jettison Subsystem 302
7.7 Conclusions 304
7.8 Questions 305
References 305
8 Reliability Tests 307
8.1 Introduction 307
8.1.1 Targets of Reliability and Life Tests 308
8.1.2 Specifics of Life Tests and Reliability 309
8.1.3 Test Types 310
8.1.4 Test Planning and Documentation 315
8.2 Reliability Tests Plan 317
8.2.1 Types of Tests 318
8.2.2 Test Samples 320
8.2.3 Test Stresses 320
8.2.4 Test Time 321
8.3 Zero-Failure Test 322
8.3.1 Binomial Zero-Failure Testing 323
8.3.2 Weibull Zero-Failure Testing 325
8.4 Lite Tests 32^
8.4.1 Theoretical Concept 329
8.4.2 Binomial Series Life Testing 332
8.4.3 Exponential Series Life Testing 337
8.4.4 Weibull Series Life Testing 339
8.5 Accelerated Tests 341
8.5.1 Principles for Accelerating Tests 341
8.5.2 Operational Cycles Compressing 342
8.5.3 Extrapolation in Time 343
8.5.4 Revision of Loading Range 344
8.5.5 Increased Frequency of Operational Cycles 345
8.5.6 Loading Extrapolation 345
8.5.7 Break Completely 347
8.5.8 Progressive Load Forcing 347
8.5.9 Alternating Modes Loading 350
8.5.10 Some Specifics of the Accelerated Tests 353
8.6 Verification of Reliability Based on Prior Information 354
8.7 Verification of Reliability by Means of Degradation Tests 356
8.8 Questions 358
References 359
9 Risk Analysis of Aircraft Structure and Systems 361
9.1 Introduction 361
9.2 Risk Assessment of Aeroengine Life-Limited Parts 362
9.2.1 ELLPS Airworthiness Regulations and AC Analysis 363
9.2.2 Determination Method of ELLPs Based on FMEA 368
9.2.3 Probabilistic Risk Assessment of ELLPs 373
9.2.4 Case Analysis 382
9.3 Risk Warning of Aircraft Bleed Air System 386
9.3.1 Risk Warning Method 387
9.3.2 Application of Risk Warning on the BAS 394
9.4 Conclusions 411
References 413
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