Overview

A reader-friendly introduction to reliability analysis and its power systems applications The subset of probability theory known as reliability theory analyzes the likelihood of failure in a given component or system under given conditions. It is a critical aspect of engineering as it concerns systems of all kinds, not least modern power systems, with their essential role in sustaining the technologies on which modern life relies. Reliability Analysis of Modern Power Systems is a thorough, accessible book introducing the core concepts of reliability theory as they apply to power systems engineering, as well as the advanced technologies currently driving new frontiers in reliability analysis. It is a must-own for anyone looking to understand and improve the systems that power our world. Readers will also find: Detailed discussion of reliability modeling and simulation of composite systems using Typhoon HIL 404 Reliability assessment of generation systems, transmission systems, distribution systems, and more Information on renewable energy integration for more sustainable power grids Reliability Analysis of Modern Power Systems is ideal for professionals, engineers, and researchers in power system design and reliability engineering, as well as for advanced undergraduate and graduate students in these and related subjects.

Full Product Details

Author:   R. K. Saket (Indian Institute of Technology, Varanasi, India) ,  P. Sanjeevikumar (University of South-Eastern Norway, Porsgrunn, Norway)
Publisher:   John Wiley & Sons Inc
Imprint:   Wiley-IEEE Press
Weight:   0.680kg
ISBN:  

9781394226740

ISBN 10:   1394226748
Pages:   576
Publication Date:   26 July 2024
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   Available To Order  
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Table of Contents

About the Authors xix List of Contributors xxi Foreword xxvii Preface xxix Acknowledgments xxxiii Section 1 Reliability Principles and Applications 1 1 Basic Principles and Scientific Importance of Reliability Theory 3 Aanchal Verma, Akanksha Singh S. Vardhan, Vanitha Bagana, R. K. Saket, and P. Sanjeevikumar 1.1 Introduction 3 1.2 Basic Concept of Reliability Engineering 4 1.3 Scientific Importance of Reliability in Modern Technology 6 1.4 Basic Concept of Probability Theory 7 1.5 Basic Concepts of System Reliability 9 1.6 Conclusion 17 2 Bayesian Approach for Reliability Evaluation and Remaining Useful Life Prediction 19 Debasis Jana, Suprakash Gupta, and Deepak Kumar 2.1 Introduction 19 2.2 Bayesian Network 20 2.3 Bayesian Reliability 22 2.4 Application of BN in Reliability and Remaining Useful Life 23 2.5 Dynamic Bayesian Networks 26 2.6 Advantages and Limitations of BN and DBN 27 2.7 Conclusion 28 3 Evaluation of Basic Reliability Indices Using State Enumeration Method 31 Rajesh Arya, Chandrima Roy, Atul Koshti, Ramesh C. Bansal, and Liladhar Arya 3.1 Introduction 31 3.2 Markov Process 31 3.3 Solution of State Equations 34 3.4 Functions of a Single Component’s Availability and Unavailability 37 3.5 Two-Component State Model and State Probabilities 38 3.6 Three-Component State Transition Diagram 40 3.7 Concept of Frequency and Mean Duration 41 3.8 Frequency of Combined Events 42 3.9 State Enumeration Technique for Obtaining Frequency-Duration (FD) 44 3.10 Conclusion 49 4 Methodologies for Reliability Evaluation of Network 51 Rajesh Arya, Atul Koshti, Aanchal Verma, Baseem Khan, and Liladhar Arya 4.1 Introduction 51 4.2 Series Network 51 4.3 Parallel Network 53 4.4 Partially Redundant System 56 4.5 Reliability Evaluation of Complex Networks 57 4.6 Determination of Tie-Sets 63 4.7 Method of Obtaining Cut-Set 65 4.8 Multistate Model 66 4.9 Illustrative Examples 68 4.10 Conclusions 72 5 Probabilistic Approach for Standby and Load-Sharing System Reliability Evaluation 75 Rajesh Arya, R. K. Saket, Atul Koshti, Saad Mekhilef, and Pradeep Purey 5.1 Introduction 75 5.2 Reliability Evaluation Under Ideal Condition 75 5.3 Standby System Reliability Evaluation Under Nonideal Condition 78 5.4 Reliability Evaluation of Load-Sharing System (Endrenyi 1978) 81 5.5 Illustrative Examples 83 5.6 Conclusion 88 Section 2 Reliability-Based Systems Design 91 6 Physical Reliability Methods and Design for System Reliability 93 Smriti Singh, Jyoti Maurya, Eram Taslima, Bharat B. Sagar, and R. K. Saket 6.1 Introduction 93 6.2 Reliability Methods 94 6.3 Design Analysis and Process 105 6.4 Conclusions 110 7 Design for Maintainability and Availability Analysis for System Design 113 Jyoti Maurya, Om P. Bharti, K. S. Anand Kumar, and R. K. Saket 7.1 Introduction 113 7.2 Elements of Maintainability 114 7.3 Availability of the Systems 120 7.4 Conclusion 123 8 Genetic Algorithm and Artificial Neural Networks in Reliability-Based Design Optimization 125 Heeralal Gargama, Sanjay Kumar Chaturvedi, and Rajiv Nandan Rai 8.1 Introduction 125 8.2 Reliability-based Design 127 8.3 RBDO Methodology Using PSF and ANNs 134 8.4 Conclusion 137 8.A Evaluation of Electromagnetic Shielding Effectiveness 138 9 Parametric Estimation Models for Minimal and Imperfect Maintenance 143 Rajiv Nandan Rai, Sanjay Kumar Chaturvedi, and Heeralal Gargama 9.1 Introduction 143 9.2 Maintenance Actions on Maintained Systems 145 9.3 Classifications of Imperfect Maintenance Categories 146 9.4 Parametric Reliability Estimation Models for Maintained Systems 149 9.5 NHPP: Illustrative Example 153 9.6 Generalized Renewal Process 156 9.7 GRP: Illustrative Examples 161 9.8 Conclusion 164 Section 3 Reliability Analysis of Transmission Systems 167 10 Transmission System Reliability Evaluation Including Security 169 Pushpendra Singh, Rajesh Arya, Lakhan Singh Titare, Mohd. Tauseef Khan, and Sharat Chandra Choube 10.1 Introduction 169 10.2 Problem Formulation 171 10.3 Monte Carlo Simulation for Evaluation of the Security Index: With and Without Considering the Absence of Transmission Lines 172 10.4 Evaluation of the Load Flow’s Minimal Eigenvalue Jacobian 174 10.5 Evaluation of Schur’s Inequality 175 10.6 Evaluation of the PSI and the Cut-set Approach 175 10.7 Recurrent Neural Network (RNN) Assessment of Probabilistic Insecurity 177 10.8 Results and Discussions 178 10.9 Conclusions 190 10.A.1 Data for IEEE six-bus, seven-line test system (100MVA Base) 191 10.A.2 Data for IEEE 14-bus, 20-line system (100MVA Base) 192 10.A.3 Data for IEEE 25-bus, 35 line system (100MVA Base) 194 11 Probabilistic Voltage Security Assessment and Enhancement Using Rescheduling of Reactive Power Control Variables 199 Lakhan Singh Titare, Aanchal Singh S. Vardhan, Liladhar Arya, and Devkaran Sakravdia 11.1 Introduction 199 11.2 Computation of Probabilistic Insecurity Index (PII) Using Cut-set Technique 201 11.3 Computation of Probabilistic Insecurity Index (PII) Sensitivity using ANN 202 11.4 Voltage Security Enhancement using a Monovariable Approach 205 11.5 Results and Discussion 206 11.6 Conclusions 214 Section 4 Reliability Analysis of Distribution Systems 217 12 Modern Aspects of Probabilistic Distributions for Reliability Evaluation of Engineering Systems 219 Aanchal Singh S. Vardhan, Aanchal Verma, Jyotsna Ogale, R. K. Saket, and Stuart Galloway 12.1 Introduction 219 12.2 Life Distribution of Power Components: An Overview 220 12.3 Failure Distribution Functions for Reliability Evaluation 227 12.4 Use of Exponential Model to Evaluate Reliability and MTBF 232 12.5 Probabilistic Methods For Reliability Evaluation 233 12.6 Additional Solved Examples 242 12.7 Conclusion 244 13 Reliability Enhancement of Electrical Distribution Systems Considering Active Distributed Generations 247 Kalpesh B. Kela, Bhavik N. Suthar, Smriti Singh, Rajesh Arya, and Liladhar Arya 13.1 Introduction 247 13.2 Electrical Distribution Reliability Indices: Customer and Energy Based 249 13.3 Defining the Problem 250 13.4 The Flower Pollination Algorithm Overview 253 13.5 Solution Approach 254 13.6 Discussions and Outcomes 258 13.7 Conclusion 261 14 Reliability Enhancement Strategy for Electrical Distribution Systems Considering Reward and Penalty 267 Kalpesh B. Kela, Bhavik N. Suthar, Liladhar Arya, and Rajesh Arya 14.1 Introduction 267 14.2 Reward and Penalty System (RPS) 269 14.3 Problem Identification 271 14.4 Rao Algorithms: An Overview 273 14.5 Steps to Solve the Problem 274 14.6 A Discussion of the Findings 274 14.7 Conclusion 281 15 Reliability Analysis of Composite Distribution System Using Frequency Duration Concept 285 Atul Koshti, Eram Taslima, Pradeep Purey, Liladhar Arya, and Sharat C. Choube 15.1 Introduction 285 15.2 Components Modeling in Composite Distribution System (CDS) 286 15.3 Frequency-Duration Concept for Reliability Indices Evaluation 286 15.4 MCS-Based Reliability Indices Evaluation of CDS 288 15.5 Result and Discussion 289 15.6 Illustrative Examples 290 15.7 Conclusions 298 Section 5 Reliability Analysis of Distribution Systems Integrated With Renewable Energy Systems 301 16 Reliability Assessment of Distribution Systems Integrated with Renewable Energy Systems 303 Sachin Kumar, Sandeep Kumar, Aanchal Singh S. Vardhan, R. K. Saket, and P. Sanjeevikumar 16.1 Introduction 303 16.2 Reliability Functions 305 16.3 Renewable Energy Sources 307 16.4 Optimization and Control 313 16.5 Case Study 315 16.6 Challenges and Future Directions 320 16.7 Conclusion 323 17 Reliability Evaluation and Performance of Hybrid Photovoltaic Energy Systems for Rural Electrification Using Markov Process 325 Santosh S. Raghuwanshi, Smriti Singh, Akanksha Singh S. Vardhan, Rajesh Arya, and R. K. Saket 17.1 Introduction 325 17.2 Reliability Indices 326 17.3 Markov Process 327 17.4 Reliability of the System 329 17.5 Conclusion 338 18 Probabilistic Distribution and Monte Carlo Approach for Reliability Evaluation of SEIG-Based Micro Hydro Power Generation System 341 Lokesh Varshney, Kanhaiya Kumar, Gautam Singh Dohare, Udaya M. Bhaskara Rao, and Jitendra Singh Shakya 18.1 Introduction 341 18.2 Residual Magnetism in SEIG: Restoration and Loss 342 18.3 Problems with SEIG Excitation Failure in RE Systems 343 18.4 SEIG Tests with Lowest Capacitive Excitation 343 18.5 Rotor Core Magnetization of SEIG Reliability Assessment Using Least Capacitor Score 344 18.6 Discussion and Outcomes 349 18.7 Conclusion 350 19 Reliability and Mean Life Assessment of Solar Panel by Cooling 353 Rahul Agrawal, Jyotsna Ogale, Nga T. T. Nguyen, R. K. Saket, and Joydeep Mitra 19.1 Introduction 353 19.2 Methodology 355 19.3 Reliability Assessment 365 19.4 Probability Density Function 369 19.5 Cumulative Distribution Function 371 19.6 Results 378 19.7 Conclusion 378 20 Reliability Assessment of Different Topologies in Photovoltaic System 381 Laxman Chaudhary, Aanchal Verma, Ramesh C. Bansal, and R. K. Saket 20.1 Introduction 381 20.2 Reliability Modeling of PV Topology 385 20.3 Estimation of Failure Rate 387 20.4 Reliability Estimation Using RBD 388 20.5 Results 400 20.6 Conclusions 405 Section 6 Reliability Analysis of Power Electronics Components and Systems for Modern Power System Applications 409 21 Reliability Evaluation of Power Electronics Converters for Modern Power System Applications 411 Amit Kumar, Sachin Kumar, Sunil K. Singh, R. K. Saket, and P. Sanjeevikumar 21.1 Introduction 411 21.2 Failures in Power Electronics Converters 412 21.3 Estimation and Monitoring of Junction Temperature 414 21.4 Reliability of a Modern Power System 420 21.5 Challenges and Future Directions 424 22 Reliability Assessment of Sub-components of Electric Vehicle for Performance Enhancement Grid Integrated Power System 427 Saumya Singh, Dhawal Dwivedi, Sandeep K. Soni, R. K. Saket, and Dwarkadas P. Kothari 22.1 Introduction 427 22.2 Electric Vehicles and Grid Integration 428 22.3 Sub-components of EVs 431 22.4 Reliability Assessment Techniques in EVs 435 22.5 Evaluation of Distribution Systems Reliability with Integrated EVs 443 22.6 Conclusion 448 23 Reliability Assessment of Multilevel Inverter for Modern Power System Applications 451 Saumya Singh, Dhawal Dwivedi, Kumari Sarita, R. K. Saket, and P. Sanjeevikumar 23.1 Introduction 451 23.2 Reliability Assessment Techniques 453 23.3 Types of Multilevel Inverters (MLIs) 456 23.4 Comparative Reliability Assessment of MLIs 463 23.5 Conclusion 464 24 Reliability Aspects in Snubber Circuit for Industrial Power Applications 467 Dhawal Dwivedi, Saumya Singh, Kumari Sarita, R. K. Saket, and P. Sanjeevikumar 24.1 Introduction 467 24.2 Passive Snubber Circuit 468 24.3 Selection of Turn-OFF Snubber 469 24.4 Design of a Discharge-Suppressing RCD Snubber 471 24.5 Simulation Results of RCD Snubber 472 24.6 Reliability Aspects in Snubber Design for Industrial Power Applications 476 24.7 Conclusion 478 25 Reliability Assessment of Power Electronics Devices and Systems for Modern Power Applications 481 Jyoti Maurya, Saumya Singh, Sachin Kumar, P. Sanjeevikumar, and R. K. Saket 25.1 Introduction 481 25.2 Concept of PEDS Reliability in Modern Power System 483 25.3 V-Shape Model-Based Reliability Assessment in PEDS 486 25.4 Converter Reliability Modeling 489 25.5 Conclusion and Future Challenges 492 26 Reliability Aspects in the Design and Development of Microgrids 493 Amit Kumar, Sachin Kumar, Almoataz Y. Abdelaziz, R. K. Saket, and D. P. Kothari 26.1 Introduction 493 26.2 Architecture and Operation of Microgrid 494 26.3 Microgrid Control Strategies 496 26.4 Reliability Aspects in Microgrid Planning and Design 499 26.5 Conclusion and Future Challenges 504 References 505 Abbreviations 507 Notations 513 Index 525

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R. K. Saket, PhD, is a Full Professor in the Department of Electrical Engineering, Indian Institute of Technology (Banaras Hindu University) Varanasi (UP), India. He is a Senior Member of IEEE and an Associate Editor of IET Renewable Power Generation, IET Electrical Systems in Transportation, IEEE Access, and the Managing Guest Editor of IEEE Journal of the Electron Devices Society, Computers & Electrical Engineering, and Electrical Engineering (Springer Nature). P. Sanjeevikumar, PhD, is a Full Professor in the Department of Electrical Engineering, Information Technology and Cybernetics, University of South-Eastern Norway, Porsgrunn, Norway. He is a Senior Member of IEEE and an Associate Editor of the IEEE Transactions of Industry Applications, and the Deputy/Subject Editor of IET Renewable Power Generation, IET Generation, Transmission and Distribution, IETE Journal of Research, and FACETS (Canada).

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