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9780470907566

Risk and Safety Analysis of Nuclear Systems

by ;
  • ISBN13:

    9780470907566

  • ISBN10:

    0470907568

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 2011-07-05
  • Publisher: Wiley
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Summary

The book has been developed in conjunction with NERS 462, a course offered every year to seniors and graduate students in the University of Michigan NERS program.The first half of the book covers the principles of risk analysis, the techniques used to develop and update a reliability data base, the reliability of multi-component systems, Markov methods used to analyze the unavailability of systems with repairs, fault trees and event trees used in probabilistic risk assessments (PRAs), and failure modes of systems. All of this material is general enough that it could be used in non-nuclear applications, although there is an emphasis placed on the analysis of nuclear systems.The second half of the book covers the safety analysis of nuclear energy systems, an analysis of major accidents and incidents that occurred in commercial nuclear plants, applications of PRA techniques to the safety analysis of nuclear power plants (focusing on a major PRA study for five nuclear power plants), practical PRA examples, and emerging techniques in the structure of dynamic event trees and fault trees that can provide a more realistic representation of complex sequences of events. The book concludes with a discussion on passive safety features of advanced nuclear energy systems under development and approaches taken for risk-informed regulations for nuclear plants.

Author Biography

John C. Lee, PhD, has been Professor of Nuclear Engineering at the University of Michigan since 1974, following five years of employment at Westinghouse Electric Corporation and General Electric Company. He has written for approximately 180 publications on broad areas of nuclear reactor physics and engineering, including nuclear systems analysis and diagnostics. Dr.Lee is a Fellow of the American Nuclear Society. Norman J. McCormick, PhD, is an emeritus professor of mechanical engineering at the University of Washington who retired in 2003. From 1966 until the early 1990s, he was a professor of nuclear engineering. Dr. McCormick is the author of the book Reliability and Risk Analysis Methods and Nuclear Power Applications (upon which part of NERS 462 is based) and has authored approximately 150 journal articles. He is a Fellow of the American Nuclear Society.

Table of Contents

Prefacep. xii
Permissions and Copyrightsp. xiv
List of Tablesp. xvi
List of Figuresp. xviii
Risk and Safety of Engineered Systemsp. 1
Risk and Its Perception and Acceptancep. 1
Overview of Risk and Safety Analysisp. 6
Two Historical Reactor Accidentsp. 8
Definition of Riskp. 9
Reliability, Availability, Maintainability, and Safetyp. 10
Organization of the Bookp. 12
Referencesp. 13
Probabilities of Eventsp. 15
Eventsp. 15
Event Tree Analysis and Minimal Cut Setsp. 17
Probabilitiesp. 19
Interpretations of Probabilityp. 19
Axiomatic Approach to Probabilitiesp. 20
Intersection of Eventsp. 21
Union of Eventsp. 22
Decomposition Rule for Probabilitiesp. 25
Time-Independent Versus Time-Dependent Probabilitiesp. 25
Time-Independent Probabilitiesp. 26
Introductionp. 26
Time-Independent Probability Distributionsp. 27
Normal Distributionp. 32
Reliability Functionsp. 35
Time-Dependent Probability Distributionsp. 41
Erlangian and Exponential Distributionsp. 42
Gamma Distributionp. 43
Lognormal Distributionp. 44
Weibull Distributionp. 46
Generalized ôBathtubö Distributionp. 47
Selection of a Time-Dependent Probability Distributionp. 48
Extreme-Value Probability Distributionsp. 50
Probability Models for Failure Analysesp. 52
Referencesp. 53
Exercisesp. 53
Reliability Datap. 59
Estimation Theoryp. 59
Moment Estimatorsp. 60
Maximum Likelihood Estimatorsp. 61
Maximum Entropy Estimatorsp. 64
Comparison of Estimatorsp. 65
Bayesian Updating of Datap. 65
Bayes Equationp. 65
Applications of the Bayes Equationp. 67
Central Limit Theorem and Hypothesis Testingp. 70
Interpretation of the Central Limit Theoremp. 71
Hypothesis Testing with the Central Limit Theoremp. 72
Reliability Quantificationp. 74
Central Limit Theorem for Reliability Quantificationp. 74
Engineering Approach for Reliability Quantificationp. 76
X2-Distribution for Reliability Quantificationp. 77
Three-Way Comparison and Concluding Remarksp. 78
Referencesp. 80
Excercisesp. 80
Reliability of Multiple-Component Systemsp. 85
Series and Active-Parallel Systemsp. 86
Systems with Independent Componentsp. 86
Systems with Redundant Componentsp. 88
Fail-to-Safety and Fail-to-Danger Systemsp. 90
Systems with Standby Componentsp. 93
Decomposition Analysisp. 96
Signal Flow Graph Analysisp. 100
Cut Set Analysisp. 101
Referencesp. 104
Exercisesp. 104
Availability and Reliability of Systems with Repairp. 109
Introductionp. 109
Markov Methodp. 111
Markov Governing Equationsp. 111
Solution of Markov Governing Equationsp. 113
An Elementary Examplep. 116
Availability Analysesp. 118
Rules for Constructing Transition Rate Matricesp. 118
Availability Transition Rate Matricesp. 119
Time-Dependent Availability Examplesp. 123
Steady-State Availabilityp. 127
Reliability Analysesp. 128
Reliability Transition Rate Matricesp. 129
Time-Dependent Reliability Examplesp. 130
Mean Time to Failurep. 130
Additional Capabilities of Markov Modelsp. 133
Imperfect Switching Between System Statesp. 134
Systems with Nonconstant Hazard Ratesp. 136
Referencesp. 137
Exercisesp. 137
Probabilistic Risk Assessmentp. 141
Failure Modesp. 142
Classification of Failure Eventsp. 143
Primary, Secondary, and Command Failuresp. 143
Common Cause Failuresp. 144
Human Errorsp. 148
Failure Datap. 150
Hardware Failuresp. 150
Human Errorsp. 150
Combination of Failures and Consequencesp. 152
Inductive Methodsp. 152
Event Tree Analysisp. 154
Fault Tree Analysisp. 156
Introductionp. 156
Fault Tree Constructionp. 157
Qualitative Fault Tree Analysisp. 157
Quantitative Fault Tree Analysisp. 160
Common Cause Failures and Fault Tree Analysisp. 165
Master Logic Diagramp. 165
Uncertainty and Importance Analysisp. 168
Types of Uncertainty in PRAsp. 168
Stochastic Uncertainty Analysisp. 169
Sensitivity and Importance Analysisp. 170
Referencesp. 172
Exercisesp. 172
Computer Programs for Probabilistic Risk Assessmentp. 179
Fault Tree Methodology of the SAPHIRE Codep. 179
Gate Conversion and Tree Restructuringp. 180
Simplification of the Treep. 180
Fault Tree Expansion and Reductionp. 182
Fault and Event Tree Evaluation with the SAPHERE Codep. 183
Other Features of the SAPHIRE Codep. 185
Other PRA Codesp. 185
Binary Decision Diagram Algorithmp. 187
Basic Formulation of the BDD Algorithmp. 187
Generalization of the BDD Formulationp. 189
Zero-Suppressed BDD Algorithm and the FTREX Codep. 193
Referencesp. 194
Exercisesp. 195
Nuclear Power Plant Safety Analysisp. 197
Engineered Safety Features of Nuclear Power Plantsp. 197
Pressurized Water Reactorp. 198
Boiling Water Reactorp. 210
Accident Classification and General Design Goalsp. 215
Plant Operating Statesp. 217
Accident Classification in 10 CFR 50p. 217
General Design Criteria and Safety Goalsp. 219
Design Basis Accident: Large-Break LOCAp. 220
Typical Sequence of a Cold-Leg LBLOCA in PWRp. 221
ECCS Specificationsp. 225
Code Scaling, Applicability, and Uncertainty Evaluationp. 227
Severe (Class 9) Accidentsp. 231
Anticipated Transients Without Scramp. 233
History and Background of the ATWS Issuep. 233
Resolution of the ATWS Issuesp. 235
Power Coefficients of Reactivity in LWRsp. 237
Radiological Source and Atmospheric Dispersionp. 241
Radiological Source Termp. 242
Atmospheric Dispersion of Radioactive Plumep. 243
Simple Models for Dose Rate Calculationp. 247
Biological Effects of Radiation Exposurep. 250
Referencesp. 252
Exercisesp. 254
Major Nuclear Power Plant Accidents and Incidentsp. 259
Three Mile Island Unit 2 Accidentp. 260
Sequence of the Accident-March 1979p. 260
Implications and Follow-Up of the Accidentp. 260
PWR In-Vessel Accident Progressionp. 263
Core Uncovery and Heatupp. 265
Cladding Oxidationp. 266
Clad Melting and Fuel Liquefactionp. 268
Molten Core Slumping and Relocationp. 270
Vessel Breachp. 271
Chernobyl Accidentp. 272
Cause and Nature of the Accident-April 1986p. 272
Sequence of the Accidentp. 274
Estimate of Energy Release in the Accidentp. 275
Accident Consequencesp. 275
Comparison of the TMI and Chernobyl Accidentsp. 276
Fukushima Station Accidentp. 277
Sequence of the Accident-March 2011p. 277
March 2011 Perspectives on the Fukushima SBO Eventp. 278
Salem Anticipated Transient Without Scramp. 279
Chronology and Cause of the Salem Incidentp. 279
Implications and Follow-Up of the Salem ATWS Eventp. 281
LaSalle Transient Eventp. 283
LaSalle Nuclear-Coupled Density-Wave Oscillationsp. 283
Simple Model for Nuclear-Coupled Density-Wave Oscillationsp. 287
Implications and Follow-Up of the LaSalle Incidentp. 289
Davis-Besse Potential LOCA Eventp. 291
Background and Chronology of the Incidentp. 291
NRC Decision to Grant DB Shutdown Delayp. 293
Causes for the Davis-Besse Incident and Follow-Upp. 295
Referencesp. 297
Exercisesp. 300
PRA Studies of Nuclear Power Plantsp. 303
WASH-1400 Reactor Safety Studyp. 304
Assessment of Severe Accident Risks: NUREG-1150p. 311
Background and Scope of the NUREG-1150 Studyp. 311
Overview of NUREG-1150 Methodologyp. 313
Accident Frequency Analysisp. 315
Accident Progression Analysisp. 320
Radionuclide Transport Analysisp. 324
Offsite Consequence Analysisp. 327
Uncertainty Analysisp. 330
Risk Integrationp. 331
Additional Perspectives and Comments on NUREG-1150p. 337
Simplified PRA in the Structure of NUREG-1150p. 340
Description of the Simplified PRA Modelp. 340
Parametric Studies and Comments on the Simplified PRA Modelp. 344
Referencesp. 345
Exercisesp. 347
Passive Safety and Advanced Nuclear Energy Systemsp. 349
Passive Safety Demonstration Tests at EBR-IIp. 349
EBR-II Primary System and Simplified Modelp. 350
Unprotected Loss-of-Flow and Loss-of-Heat-Sink Testsp. 357
Simplified Fuel Channel Analysisp. 361
Implications of EBR-II Passive Safety Demonstration Testsp. 362
Safety Characteristics of Generation III+ Plantsp. 364
AP1000 Design Featuresp. 364
Small-Break LOCA Analysis for AP1000p. 366
Economic Simplified Boiling Water Reactorp. 371
Reliability Quantification of SBWR Passive Safety Containmentp. 375
Generation IV Nuclear Power Plantsp. 382
Sodium-Cooled Fast Reactorp. 383
Hypothetical Core Disruptive Accidents for Fast Reactorsp. 387
VHTR and Phenomena Identification and Ranking Tablep. 393
Referencesp. 396
Exercisesp. 399
Risk-Infoimed Regulations and Reliability-Centered Maintenancep. 401
Risk Measures for Nuclear Plant Regulationsp. 402
Principles of Risk-Informed Regulations and Licensingp. 402
Uncertainties in Risk-Informed Decision Makingp. 405
Other Initiatives in Risk-Informed Regulationsp. 406
Reliability-Centered Maintenancep. 406
Optimization Strategy for Preventive Maintenancep. 407
Reliability-Centered Maintenance Frameworkp. 409
Cost-Benefit Considerationsp. 410
Referencesp. 413
Exercisesp. 415
Dynamic Event Tree Analysisp. 417
Basic Features of Dynamic Event Tree Analysisp. 418
Continuous Event Tree Formulationp. 421
Derivation of the Stochastic Balance Equationp. 421
Integral Form of the Stochastic Balance Equationp. 423
Numerical Solution of the Stochastic Balance Equationp. 425
Cell-to-Cell Mapping for Parameter Estimationp. 426
Derivation of the Bayesian Recursive Relationshipp. 427
CCM Technique for Dynamic Event Tree Constructionp. 430
Diagnosis of Component Degradationsp. 434
Bayesian Framework for Component Diagnosticsp. 434
Implementation of the Probabilistic Diagnostic Algorithmp. 437
Referencesp. 441
Exercisesp. 442
Reactor Radiological Sourcesp. 443
Fission Product Inventory and Decay Heatp. 443
Health Effects of Radiation Exposurep. 446
Referencesp. 448
Some Special Mathematical Functionsp. 449
Gamma Functionp. 449
Error Functionp. 451
Referencesp. 451
Some Failure Rate Datap. 453
Linear Kalman Filter Algorithmp. 457
Referencesp. 461
Answers to Selected Exercisesp. 462
Indexp. 467
Table of Contents provided by Ingram. All Rights Reserved.

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