Power switching components : theory, applications and future trends

This book focuses on the theory and application of power switching components in power networks. More specifically, it discusses current interruption theory, applied stresses to switching components in power networks and appropriate methods to test their different functionalities. It reviews the basic working principles of current technologies and summarizes the upcoming technological advances within the field of power switching devices. Taking an educational approach to the subject, this book is useful for graduate courses on high voltage equipment and power device technology within the electric power engineering discipline. Furthermore, inclusion of numerous worked examples, exercises and easily digestible descriptions of complex physical phenomena in switching devices make this an invaluable self-learning resource for engineers.

1. IntroductionScope of the book, brief description of book structure and chapters 2. Current interruption: basicsa. IntroductionSwitching arc initiation, schematic current / voltage during current interruption, importance of short circuit current and Transient recovery voltage, dielectric recovery, thermal / dielectric re-ignitions.b. Basics of arc physicsDynamic arc behavior, Arc in gaseous medium, thermal ionization mechanismArc in low pressure / vacuum, thermo-field emission / impact ionizationc. Arc modeling basicsBrief description of different modeling levels (detailed physical models, qualitative arc models as well as black box models), basic consideration of arc-network interaction (current commutation ...) 3. Application of power switching devices in power networksa. Interruption of fault currentShort circuit current (symmetrical / asymmetrical, decay DC, neutral point) different TRV forms, standard for CBTesting methods (direct / synthetic)b. Closing under fault condition (short circuit making)Pre-strike, arc energy, importance for LBS and earthing switch, standard for LBS and CB, test circuitc. Energizing of loadsOver-voltages, trapped charges, reclosingd. Switching of inductive loadsImportance of increased RRRVe. Switching of capacitive loadsInrush current, pre-strike, 1-cos TRV, re-strike / re-ignition, voltage escalation, standard requirements, test methodsf. Switching of small inductive currentsCurrent chopping, multiple re-ignitions, virtual current chopping, transient over-voltages 4. Current interruption technologies: present statusa. different types of power switching componentsDifferent parts of a power-switching device, Classification of power switching components based on the requirements, installation, rated voltage as well as arc-extinguishing mediumb. disconnecting switchesConstruction for different voltage ratings, challenges including short circuit current carrying capability, mechanical considerationsc. load break switchesDifferent technologies, application to MV, gaseous LBS, vacuum contactor, peculiarities regarding load current interruption and fault current making, transient switching over-voltagesd. fuseArc extinguishing principle in fuse, applications MV / LV, limitations, Is-limiter, possible applications, RMU, fuse + LBS combinatione. circuit breakersi. Oil circuit breakersInterruption principle, minimum oil vs. bulk oil CBs, brief description of role of cross baffle, parallel resistor, etc.ii. Gas circuit breakersPrinciple of current interruption in gases, brief description of importance of different cooling mechanisms, construction of compressed air, double pressure SF6, single pressure SF6, puffer vs. self-blastiii. Magnetic air CBCurrent interruption principle, arc elongation + cathode/anode fall, blow out coil, construction of LV CBsiv. Vacuum CBSimple construction of VCB, dielectric breakdown in vacuum, different modes of arc in vacuum, role of magnetic field, different technologies to control switching arc in vacuum 5. Future trends of power switching devicesa. HVDC current interruptionMissing CZ, fast operation, principle of current interruption in DC network, upcoming applications, review of different schemes, hybrid circuit breakers, challengesb. Fault current limitationUpcoming applications, nonlinear current dependent impedance in network, energy absorption /conversion during the fault, brief review of different schemes, challengesc. Condition assessmentImportance of condition monitoring in view of recent developments in power systems, brief review of different condition monitoring + decision making concepts, challenges / open questions