Analysis And Design Of Low-Voltage Power Systems: An Engineer’s Field Guide
Contents
- Chapter Winding Distribution In An Ideal Machine
- Winding Function
- Calculation Of The Winding Function
- Multipole Winding Configurations
- Inductances Of An Ideal Doubly Cylindrical Machine
- Calculation Of Winding Inductances
- Mutual Inductance Calculation—An Example
- Winding Functions For Multiple Circuits
- Analysis Of A Shorted Coil—An Example
- General Case For C Circuits
- Winding Function Modifications For Salient-Pole Machines
- Leakage Inductances Of Synchronous Machines
- Synchronous Machine Stator
- Synchronous Machine Rotor
- Practical Winding Design
- Conclusion
- References
- Chapter Reference Frame Theory
- Introduction
- Rotating Reference Frames
- Transformation Of Three-Phase Circuit Variables To A Rotating
- Reference Frame
- Vector Approach Applied To R–L Circuits
- Transformation Equations
- System Equations In The D–Q–N Coordinate System
- Power Flow In The D–Q–N Equivalent Circuits
- Stationary Three-Phase R–L Circuits Observed In A D–Q–N
- Reference Frame
- Matrix Approach To The D–Q–N Transformation
- The D–Q–N Transformation Applied To A Simple Three-Phase
- Cylindrical Inductor
Winding Functions In A D–Q–N Reference Frame
- Direct Computation Of D–Q–N Inductances Of A Cylindrical Three Phase Inductor
- Chapter The D–Q Equations Of A Synchronous Machine
- Introduction
- Physical Description
- Synchronous Machine Equations In The Phase Variable Or
- Voltage Equations
- Flux Linkage Equations
- Transformation Of The Stator Voltage Equations To A Rotating
- Reference Frame