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Power System Analysis and Design Use

by:
ISBN: 9780534939601 | 0534939600
Edition: 2nd
Format: Paperback
Publisher: CENGAGE-Engineering
Pub. Date: 12/30/1993

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Table of Contents
Prefacexiii
List of Symbols, Units, and Notation
xvii
Introduction
1(12)
... MOREHistory of Electric Power Systems
2(6)
Present and Future Trends
8(2)
Computers in Power-System Engineering
10(3)
Fundamentals
13(36)
Phasors
14(1)
Instantaneous Power in Single-Phase ac Circuits
15(5)
Complex Power
20(4)
Network Equations
24(3)
Personal Computer Program: Matrix Operations
27(3)
Balanced Three-phase Circuits
30(8)
Power in Balanced Three-phase Circuits
38(4)
Advantages of Balanced Three-phase versus Single-phase Systems
42(7)
Symmetrical Components
49(30)
Definition of Symmetrical Components
50(6)
Sequence Networks of Impedance Loads
56(7)
Sequence Networks of Series Impedances
63(2)
Sequence Networks of Rotating Machines
65(6)
Power in Sequence Networks
71(2)
Personal Computer Program: Symmetrical Components
73(6)
Power Transformers
79(58)
How Electric Utilities Buy Quality When they buy Transformers
80(5)
John Reason
The Ideal Transformer
85(5)
Equivalent Circuits for Practical Transformers
90(6)
The Per-unit System
96(7)
Three-phase Transformer Connections and Phase Shift
103(5)
Per-unit Sequence Models of Three-phase Two-winding Transformers
108(8)
Three-Winding Transformers
116(6)
Autotransformers
122(2)
Transformers with Off-nominal Turns Rations
124(13)
Transmission Line Parameters
137(72)
Special Report---Transmission Structures
138(15)
John Reason
Transmission-line Design Considerations
153(4)
Resistance
157(3)
Conductance
160(1)
Inductance: Solid Cylindrical Conductor
160(5)
Inductance: Single-phase Two-wire Line and Three-phase Three-wire Line with Equal Phase Spacing
165(3)
Inductance: Composite Conductors, Unequal Phase Spacing, Bundled Conductors
168(8)
Series Impedances: Three-phase Line with Neutral Conductors and Earth Return
176(6)
Electric Field and Voltage: Solid Cylindrical Conductor
182(3)
Capacitance: Single-phase Two-wire Line and Three-phase Three-wire Line with Equal Phase Spacing
185(3)
Capacitance: Stranded Conductors, Unequal Phase Spacing, Bundled Conductors
188(3)
Shunt Admittances: Lines with Neutral Conductors and Earth Return
191(6)
Electric Field Strength at Conductor Surfaces and at Ground Level
197(3)
Parallel Circuit Three-phase Lines
200(2)
Personal Computer Program: Line Constants
202(7)
Transmission Lines: Steady-State Operation
209(44)
Phase-controlled Reactor Bucks Series Capacitor
210(4)
Mark R. Wilhelm
Duane Torgerson
Medium and Short Line Approximations
214(7)
Transmission-line Differential Equations
221(5)
Equivalent π Circuit
226(3)
Lossless Lines
229(8)
Maximum Power Flow
237(1)
Line Loadability
238(4)
Reactive Compensation Techniques
242(4)
Personal Computer Program: Transmission Lines---Steady-state Operation
246(7)
Power Flows
253(42)
Survey of the Voltage Collapse Phenomenon, North American Electric Reliability Council
254(3)
Direct Solutions to Linear Algebraic Equations: Gauss Elimination
257(4)
Iterative Solutions to Linear Algebraic Equations: Jacobi and Gauss-Seidel
261(5)
Iterative Solutions to Nonlinear Algebraic Equations: Newton-Raphson
266(5)
The Power-flow Problem
271(4)
Power flow Solution
275(2)
Gauss-Seidel
Power-flow Solution
277(3)
Newton-Raphson
Sparsity Techniques
280(3)
Personal Computer Program: Power Flow
283(1)
Fast Decoupled Power Flow
284(1)
Control of Power Flow
285(10)
Symmetrical Faults
295(42)
The Problem of Arcing Faults in Low-voltage Power Distribution Systems
296(3)
Francis J. Shields
Series R- L Circuit Transients
299(2)
Three-phase Short Circuit---Unloaded Synchronous Machine
301(4)
Power-system Three-phase Short Circuits
305(4)
Bus Impedance Matrix
309(4)
Formation of Zbus One Step at a Time
313(7)
Personal Computer Program: Symmetrical Short Circuits
320(3)
Circuit Breaker and Fuse Selection
323(14)
Unsymmetrical Faults
337(34)
Fires at U. S. Utilities
338(1)
Glenn Zorpette
System Representation
339(5)
Single Line-to-ground Fault
344(3)
Line-to-Line Fault
347(3)
Double Line-to-Ground Fault
350(6)
Sequence Bus Impedance Matrices
356(5)
Personal Computer Program: Short Circuits
361(10)
System Protection
371(56)
The Impact of Microprocessor Protective Relays in the Electric Utility Industry
373(4)
Keith W. Jeffers
System-Protection Components
377(2)
Instrument Transformers
379(6)
Overcurrent Relays
385(5)
Radial System Protection
390(4)
Reclosers and Fuses
394(4)
Directional Relays
398(1)
Protection of Two-source System with Directional Relays
399(1)
Zones of Protection
400(3)
Line Protection with Impedance (Distance) Relays
403(7)
Differential Relays
410(3)
Bus Protection with Differential Relays
413(1)
Transformer Protection with Differential Relays
414(4)
Pilot Relaying
418(1)
Computer Relaying
419(8)
Power System Controls
427(34)
Scada Upgrade with AGC Using Different Vendor's Computer
430(4)
Joseph Kimbriel
Larry Douglas
Joe Bodmann
Full Graphics Boost Dispatcher's Capacity
434(4)
John Reason
Generator-Voltage Control
438(2)
Turbine-Governor Control
440(4)
Load-Frequency Control
444(4)
Economic Dispatch
448(13)
Transmission Lines: Transient Operation
461(68)
Protecting Computer Systems Against Power Transients
463(7)
Francois Martzloff
How to Get Top Performance from Polymer MOV Arresters: Not All Polymer Housings Are the Same Quality
470(2)
Jeffrey Mackevich
Why Higher MOV Ratings May be Necessary
472(2)
Ramon Mancao
James Burke
Andrew Myers
Traveling Waves on Single-phase Lossless Lines
474(3)
Boundary Conditions for single-phase Lossless lines
477(9)
Bewley Lattice Diagram
486(5)
Discrete time Models of single phase Lossless Lines and Lumped RLC Elements
491(7)
Lossy Lines
498(4)
Multiconductor Lines
502(3)
Power System Overvoltages
505(5)
Insulation Coordination
510(6)
Personal Computer Program: Transmission Line Transients
516(13)
Transient Stability
529(40)
The Great Blackout
532(3)
Bob McCaw
The Swing Equation
535(5)
Simplified Synchronous Machine Model and System Equivalents
540(3)
The Equal Area Criterion
543(7)
Numerical Integration of the Swing Equation
550(4)
Multimachine Stability
554(5)
Personal Computer Program: Transient Stability
559(2)
Design Methods for Improving Transient Stability
561(8)
Appendix569(4)
Index573

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