Practical Course to Power System Operation, Control, Stability, and Optimization

Description

This course covers all aspects of power system operation and control, beginning with the analysis of power system stability, progressing to voltage and frequency regulation, and concluding with the development of an optimal economic power network.

The course consists of 15 chapters and 130 lectures with a duration of 16 hours.

The course is structured as follows:

Initially, an overview of power system stability is presented through the following topics:

1. What is power system stability?
2. Types of disturbances affecting the power system
3. Power system stability classification
4. Rotor angle stability
5. Frequency stability
6. Voltage stability

The swing equation, the central equation for transients in power systems, will be covered in the following section. Here are the subjects that will be discussed:

1. Synchronous machine modelling
2. Types of synchronous machines
3. Machine reactances during transients.
4. What is rotor angle?
5. Swing equation analysis
6. Accelerating torque.

Further on, we’ll go over the Single Machine Infinite Bus System (SMIB), a crucial component of power system research. Here are the subjects that will be discussed:

1. Classical model for stability studies
2. Power angle curve
3. SMIB before faults
4. SMIB during faults
5. SMIB after faults

After that, you will have a thorough understanding of SSSA, or Small Signal Stability Analysis. Here are the subjects that will be discussed:

1. Damping power
2. Linearization of swing equation
3. Small signal model
4. Checking system stability
5. The system time domain response
6. Forced and free disturbances
7. Applications on MATLAB/Simulink

Studies of transient stability will be covered next. The following are some general guidelines for determining how to evaluate a system’s stability to disturbances:

1. What is transient stability?
2. Sudden increase in mechanical power
3. Equal Area Criterion (EAC)
4. Accelerating & Decelerating areas
5. Transient stability margin
6. Applications – 3-phase faults on Transients Stability
7. Critical clearing angle & time

Coming up after that, we’ll go over power system control, where you’ll learn all about controlling voltage and frequency in power networks. First, the following subjects cover the automated voltage regulator (AVR) in detail:

1. Excitation systems
2. AVR modelling
3. AVR closed loop transfer function
4. Static accuracy limit
5. AVR dynamic response
6. AVR root locus
7. Applications on MATLAB/Simulink

The following are some detailed explanations of load frequency control (LFC) that will help you understand how to keep the frequency steady:

1. Speed changer, speed sensor, hydraulic amplifier
2. Governor, generator, turbine , load modelling
3. Static performance of speed governor
4. LFC steady state analysis
5. Secondary LFC loop
6. LFC in Multi Control Area Systems – Pool Operation
7. Tie line modelling
8. Block diagram representation of two area system
9. Applications on MATLAB/Simulink

Optimal economic dispatch (OED) is the course last lesson, and it teaches you how to minimize generation costs while still meeting load demand. Here are the main points:

1. Factors affecting ED problem
2. Cost function & incremental cost
3. Static performance of speed governor
4. Lagrangian multiplier method
5. ED Problem Neglecting Transmission Losses
6. ED problem considering transmission losses
7. Kron’s formula (Loss formula)
8. Steps of solution using successive algorithm