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Electrical insulation for rotating machines : (Record no. 74365)

000 -LEADER
fixed length control field 13875nam a2201105 i 4500
001 - CONTROL NUMBER
control field 6879709
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20220712205905.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 151222s2014 njua ob 001 eng d
015 ## - NATIONAL BIBLIOGRAPHY NUMBER
-- GBA3-U2917 (print)
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
ISBN 9781118886663
-- electronic
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
-- print
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
-- paper
082 00 - CLASSIFICATION NUMBER
Call Number 621.31/042
245 00 - TITLE STATEMENT
Title Electrical insulation for rotating machines :
Sub Title design, evaluation, aging, testing, and repair /
300 ## - PHYSICAL DESCRIPTION
Number of Pages 1 PDF (xviii, 371 pages) :
490 1# - SERIES STATEMENT
Series statement IEEE press series on power engineering
505 0# - FORMATTED CONTENTS NOTE
Remark 2 PREFACE xix -- CHAPTER 1 ROTATING MACHINE INSULATION SYSTEMS 1 -- 1.1 Types of Rotating Machines 1 -- 1.2 Winding Components 9 -- 1.3 Types of Stator Winding Construction 11 -- 1.4 Form-Wound Stator Winding Insulation System Features 14 -- 1.5 Random-Wound Stator Winding Insulation System Features 36 -- 1.6 Rotor Winding Insulation System Components 38 -- References 45 -- CHAPTER 2 EVALUATING INSULATION MATERIALS AND SYSTEMS 47 -- 2.1 Aging Stresses 49 -- 2.2 Principles of Accelerated Aging Tests 54 -- 2.3 Thermal Endurance Tests 62 -- 2.4 Electrical Endurance Tests 67 -- 2.5 Thermal Cycling Tests 71 -- 2.6 Nuclear Environmental Qualification Tests 74 -- 2.7 Multifactor Stress Testing 77 -- 2.8 Material Property Tests 78 -- References 80 -- CHAPTER 3 HISTORICAL DEVELOPMENT OF INSULATION MATERIALS AND SYSTEMS 83 -- 3.1 Natural Materials for Form-Wound Stator Coils 84 -- 3.2 Early Synthetics for Form-Wound Stator Coils 86 -- 3.3 Plastic Films and Non-Wovens 89 -- 3.4 Liquid Synthetic Resins 90 -- 3.5 Mica 95 -- 3.6 Glass Fibers 99 -- 3.7 Laminates 100 -- 3.8 Evolution of Wire and Strand Insulations 101 -- 3.9 Manufacture of Random-Wound Stator Coils 102 -- 3.10 Manufacture of Form-Wound Coils and Bars 103 -- 3.11 Wire Transposition Insulation 106 -- 3.12 Methods of Taping Stator Groundwall Insulation 107 -- 3.13 Insulating Liners, Separators, and Sleeving 109 -- References 110 -- CHAPTER 4 STATOR WINDING INSULATION SYSTEMS IN CURRENT USE 111 -- 4.1 Consolidation of Major Manufacturers 114 -- 4.2 Description of Major Trademarked Form-Wound Stator Insulation Systems 115 -- 4.3 Recent Developments for Form-Wound Insulation Systems 123 -- 4.4 Random-Wound Stator Insulation Systems 127 -- References 129 -- CHAPTER 5 ROTOR WINDING INSULATION SYSTEMS 133 -- 5.1 Rotor Slot and Turn Insulation 134 -- 5.2 Collector Insulation 136 -- 5.3 End Winding Insulation and Blocking 136 -- 5.4 Retaining Ring Insulation 137 -- 5.5 Direct-Cooled Rotor Insulation 138 -- 5.6 Wound Rotors 139.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 5.7 Superconducting Sychronous Rotors 140 -- References 141 -- CHAPTER 6 ROTOR AND STATOR LAMINATED CORES 143 -- 6.1 Magnetic Materials 143 -- 6.2 Mill-Applied Insulation 149 -- 6.3 Lamination Punching and Laser Cutting 150 -- 6.4 Annealing and Burr Removal 151 -- 6.5 Enameling or Film Coatings 151 -- 6.6 Stator and Rotor Core Construction 152 -- References 157 -- CHAPTER 7 GENERAL PRINCIPLES OF WINDING FAILURE, REPAIR AND REWINDING 159 -- 7.1 Failure Processes 159 -- 7.2 Factors Affecting Repair Decisions 164 -- 7.3 Rapid Repair of Localized Stator Winding Damage 165 -- 7.4 Cutting out Stator Coils After Failure 166 -- 7.5 Bar/Coil Replacement and Half Coil Splice 167 -- 7.6 Rewinding 168 -- References 169 -- CHAPTER 8 STATOR FAILURE MECHANISMS AND REPAIR 171 -- 8.1 Thermal Deterioration 171 -- 8.2 Thermal Cycling 176 -- 8.3 Inadequate Resin Impregnation or Dipping 181 -- 8.4 Loose Coils in the Slot 185 -- 8.5 Semiconductive Coating Failure 190 -- 8.6 Semiconductive/Grading Coating Overlap Failure 194 -- 8.7 High Intensity Slot Discharge 197 -- 8.8 Vibration Sparking (Spark Erosion) 199 -- 8.9 Transient Voltage Surges 202 -- 8.10 Repetitive Voltage Surges Due to Drives 207 -- 8.11 Contamination (Electrical Tracking) 211 -- 8.12 Abrasive Particles 216 -- 8.13 Chemical Attack 217 -- 8.14 Inadequate End Winding Spacing 219 -- 8.15 End Winding Vibration 224 -- 8.16 Stator Coolant Water Leaks 228 -- 8.17 Poor Electrical Connections 231 -- References 233 -- CHAPTER 9 ROUND ROTOR WINDING FAILURE MECHANISMS AND REPAIR 235 -- 9.1 Thermal Deterioration 235 -- 9.2 Thermal Cycling 237 -- 9.3 Abrasion Due to Imbalance or Turning Gear Operation (Copper Dusting) 241 -- 9.4 Pollution (Tracking) 244 -- 9.5 Repetitive Voltage Surges 245 -- 9.6 Centrifugal Force 247 -- 9.7 Operating Without Field Current 249 -- 9.8 Remedies 250 -- References 252 -- CHAPTER 10 SALIENT POLE ROTOR WINDING FAILURE MECHANISMS AND REPAIR 253 -- 10.1 Thermal Deterioration 253 -- 10.2 Thermal Cycling 255 -- 10.3 Pollution (Tracking and Moisture Absorption) 256.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 10.4 Abrasive Particles 258 -- 10.5 Centrifugal Force 259 -- 10.6 Repetitive Voltage Surges 260 -- 10.7 Salient Pole Repair 261 -- References 263 -- CHAPTER 11 WOUND ROTOR WINDING FAILURE MECHANISMS AND REPAIR 265 -- 11.1 Voltage Surges 266 -- 11.2 Unbalanced Stator Voltages 267 -- 11.3 High Resistance Connections-Bar Lap and Wave Windings 268 -- 11.4 End Winding Banding Failures 269 -- 11.5 Slip Ring Insulation Shorting and Grounding 270 -- 11.6 Wound Rotor Winding Repair 271 -- References 272 -- CHAPTER 12 SQUIRREL CAGE INDUCTION ROTOR WINDING FAILURE MECHANISMS AND REPAIR 273 -- 12.1 Thermal 273 -- 12.2 Cyclic Mechanical Stressing 275 -- 12.3 Poor Design/Manufacture 278 -- 12.4 Repairs 283 -- References 284 -- CHAPTER 13 CORE LAMINATION INSULATION FAILURE AND REPAIR 285 -- 13.1 Thermal Deterioration 285 -- 13.2 Electrical Degradation 290 -- 13.3 Mechanical Degradation 295 -- 13.4 Failures Due to Manufacturing Defects 303 -- 13.5 Core Repairs 305 -- References 309 -- CHAPTER 14 GENERAL PRINCIPLES OF TESTING AND MONITORING 311 -- 14.1 Purpose of Testing and Monitoring 311 -- 14.2 Off-Line Testing Versus On-Line Monitoring 313 -- 14.3 Role of Visual Inspections 314 -- 14.4 Expert Systems to Convert Data Into Information 315 -- References 316 -- CHAPTER 15 OFF-LINE ROTOR AND STATOR WINDING TESTS 317 -- 15.1 Insulation Resistance and Polarization Index 317 -- 15.2 DC Hipot Test 326 -- 15.3 Polarization/Depolarization Current (PDC) 330 -- 15.4 DC Conductivity 331 -- 15.5 Poor Connection Hot Spot (High Current-Infrared Camera) 334 -- 15.6 AC Hipot 335 -- 15.7 Capacitance 339 -- 15.8 Stator Capacitance Tip-Up 342 -- 15.9 Capacitive Impedance Test for Motor Stators 344 -- 15.10 Dissipation (or Power) Factor 344 -- 15.11 Power (Dissipation) Factor Tip-Up 348 -- 15.12 Off-Line Partial Discharge for Conventional Windings 350 -- 15.13 Off-Line Partial Discharge for Inverter-Fed Windings 357 -- 15.14 Stator Blackout and Ultraviolet Imaging 359 -- 15.15 Stator Partial Discharge Probe 361.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 15.16 Stator Surge Voltage 363 -- 15.17 Inductive Impedance 367 -- 15.18 Semiconductive Coating Contact Resistance 368 -- 15.19 Conductor Coolant Tube Resistance 369 -- 15.20 Stator Wedge Tap 370 -- 15.21 Slot Side Clearance 373 -- 15.22 Stator Slot Radial Clearance 374 -- 15.23 Stator End Winding Bump 375 -- 15.24 Stator Pressure and Vacuum Decay 377 -- 15.25 Rotor Pole Drop (Voltage Drop) 378 -- 15.26 Rotor RSO and Surge 380 -- 15.27 Rotor Growler 382 -- 15.28 Rotor Fluorescent Dye Penetrant 383 -- 15.29 Rotor Rated Flux 384 -- 15.30 Rotor Single-Phase Rotation 385 -- References 385 -- CHAPTER 16 IN-SERVICE MONITORING OF STATOR AND ROTOR WINDINGS 389 -- 16.1 Thermal Monitoring 390 -- 16.2 Condition Monitors and Tagging Compounds 395 -- 16.3 Ozone 398 -- 16.4 Online Partial Discharge Monitor 400 -- 16.5 Online Capacitance and Dissipation Factor 415 -- 16.6 Endwinding Vibration Monitor 417 -- 16.7 Synchronous Rotor Flux Monitor 420 -- 16.8 Current Signature Analysis 427 -- 16.9 Bearing Vibration Monitor 432 -- 16.10 Stator Winding Water Leak Monitoring 435 -- References 435 -- CHAPTER 17 CORE TESTING 439 -- 17.1 Knife 439 -- 17.2 Rated Flux 441 -- 17.3 Core Loss 450 -- 17.4 Low Core Flux (El-CID) 451 -- References 461 -- CHAPTER 18 NEW MACHINE WINDING AND REWIND SPECIFICATIONS 463 -- 18.1 Objective of Stator and Rotor Winding Specifications 464 -- 18.2 Trade-Offs Between Detailed and General Specifications 464 -- 18.3 General Items for Specifications 465 -- 18.4 Technical Requirements for New Stator Windings 467 -- 18.5 Technical Requirements for Insulated Rotor Windings 475 -- References 486 -- CHAPTER 19 ACCEPTANCE AND SITE TESTING OF NEW WINDINGS 487 -- 19.1 Stator Winding Insulation System Prequalification Tests 487 -- 19.2 Stator Winding Insulation System Factory and On-Site Tests 494 -- 19.3 Factory and On-Site Tests for Rotor Windings 501 -- 19.4 Core Insulation Factory and On-Site Tests 505 -- References 506 -- CHAPTER 20 MAINTENANCE STRATEGIES 509 -- 20.1 Maintenance and Inspection Options 509.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 20.2 Maintenance Strategies for Various Machine Types and Applications 515 -- Reference 525 -- APPENDIX A INSULATION MATERIAL TABLES 527 -- APPENDIX B INSULATION SYSTEM TABLES 553 -- INDEX 629.
520 ## - SUMMARY, ETC.
Summary, etc A fully expanded new edition documenting the significant improvements that have been made to the tests and monitors of electrical insulation systemsElectrical Insulation for Rotating Machines: Design, Evaluation, Aging, Testing, and Repair, Second Edition covers all aspects in the design, deterioration, testing, and repair of the electrical insulation used in motors and generators of all ratings greater than fractional horsepower size. It discusses both rotor and stator windings; gives a historical overview of machine insulation design; and describes the materials and manufacturing methods of the rotor and stator winding insulation systems in current use (while covering systems made over fifty years ago). It covers how to select the insulation systems for use in new machines, and explains over thirty different rotor and stator winding failure processes, including the methods to repair, or least slow down, each process. Finally, it reviews the theoretical basis, practical application, and interpretation of forty different tests and monitors that are used to assess winding insulation condition, thereby helping machine users avoid unnecessary machine failures and reduce maintenance costs.Electrical Insulation for Rotating Machines:. Documents the large array of machine electrical failure mechanisms, repair methods, and test techniques that are currently available. Educates owners of machines as well as repair shops on the different failure processes and shows them how to fix or otherwise ameliorate them. Offers chapters on testing, monitoring, and maintenance strategies that assist in educating machine users and repair shops on the tests needed for specific situations and how to minimize motor and generator maintenance costs. Captures the state of both the present and past (3z(Bart(3y(B in rotating machine insulation system design and manufacture, which helps designers learn from the knowledge acquired by previous generationsAn ideal read for researchers, developers, and manufacturers of electrical insulating materials for machines, Electrical Insulation for Rotating Machines will also benefit designers of motors and generators who must select and apply electrical insulation in machines.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Electric insulators and insulation.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Electric machinery
General subdivision Windings.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Electric motors.
700 1# - AUTHOR 2
Author 2 Stone, Greg C.
856 42 - ELECTRONIC LOCATION AND ACCESS
Uniform Resource Identifier https://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=6879709
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Koha item type eBooks
264 #1 -
-- Piscataway, New Jersey :
-- IEEE,
-- c2004.
264 #2 -
-- [Piscataqay, New Jersey] :
-- IEEE Xplore,
-- [2014]
336 ## -
-- text
-- rdacontent
337 ## -
-- electronic
-- isbdmedia
338 ## -
-- online resource
-- rdacarrier
588 ## -
-- Description based on PDF viewed 12/22/2015.
695 ## -
-- Aging
695 ## -
-- Asphalt
695 ## -
-- Bars
695 ## -
-- Bonding
695 ## -
-- Coils
695 ## -
-- Copper
695 ## -
-- Current measurement
695 ## -
-- DC motors
695 ## -
-- Electric breakdown
695 ## -
-- Expert systems
695 ## -
-- Generators
695 ## -
-- Heating
695 ## -
-- IEC standards
695 ## -
-- Induction motors
695 ## -
-- Inspection
695 ## -
-- Insulation
695 ## -
-- Lamination
695 ## -
-- Magnetic cores
695 ## -
-- Magnetic domains
695 ## -
-- Magnetic flux
695 ## -
-- Magnetic hysteresis
695 ## -
-- Magnetic materials
695 ## -
-- Maintenance engineering
695 ## -
-- Materials
695 ## -
-- Mathematical model
695 ## -
-- Moisture
695 ## -
-- Monitoring
695 ## -
-- Partial discharges
695 ## -
-- Pollution measurement
695 ## -
-- Power capacitors
695 ## -
-- Resins
695 ## -
-- Rotors
695 ## -
-- Stator cores
695 ## -
-- Stator windings
695 ## -
-- Stress
695 ## -
-- Surges
695 ## -
-- Synchronous motors
695 ## -
-- Temperature measurement
695 ## -
-- Temperature sensors
695 ## -
-- Testing
695 ## -
-- Voltage measurement
695 ## -
-- Windings

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