Simulation of Some Power System, Control System and Power Electronics Case Studies Using Matlab and PowerWorld Simulator E-Book

Simulation of Some Power System, Control System and Power Electronics Case Studies Using Matlab and PowerWorld Simulator

Simulation of Some Power System, Control System and Power Electronics Case Studies Using Matlab and PowerWorld Simulator Programs

Simulation of Some Power System, Control System and Power Electronics Case Studies Using Matlab and PowerWorld Simulator Programs

By

Dr. Hedaya Mahmood Alasooly

[email protected]

Overview:

Overview:

The book consists from three parts concerning simulation of some power system, control system and power electronics case studies using matlab and powerworld simulator programs

I. Part A: Simulation of Some Power Electronics Case Studies in Matlab Simpowersystem Blockset:

This part covers some case studies that provide detailed, realistic examples of how to use SimPowerSystems in modeling power system dynamics in various types of application that use power electronics converters. The following case studies are simulated on the paper:

1- Thyristor-Based Static Var Compensator.

2. Transient Stability of a Power System with SVC and PSS.

3. GTO-Based STATCOM.

4. Control of load flow using UPFC.

5- Control of AC motor.

6- Control of DC motor.

7- VSC-Based HVDC Link.

II. Part B: Control of DC Motor Using Different Control Strategies in Matlab:

A simple model of a DC motor driving an inertial load has the angular speed of the load, , as the output and applied voltage, , as the input. The system was used as an example in [1]. The ultimate goal of this paper is to control the angular rate by varying the applied voltage using different control strategies for comparison purpose. The comparision is made between the proptional controller, integral controller, propotional and integral controller, phase lag compensator, derivitive controller, lead integral compensator, lead lag compensator, PID controller and the the linear quadratic tracker design based on the optimal control theory.

III. Part C: Investigation of the Usefulness of the PowerWorld Simulator Program Developed by “Glover, Overbye & Sarma” in the Solution of Power System Problems:

The objective of this part is to investigate the usefulness of the power system simulator PowerWorld program developed by “Glover, Overbye &Sarma”. The results obtained from the power simulator program were presented for different case studies. The power system network used in this study consists from 6 buses. Area 1 includes bus 1-5 while Bus 6 will be part of Area 1 in some case studies, or will form separate area 2 in other case studies for comparison purpose. Note that the Available Transfer Capability (ATC) analysis add-on which determines the maximum MW transfer possible between two parts of a power system without violating any limits, and the voltage adequacy and stability tool (VAST) add-on that can solve multiple power flow solutions in order to generate a PV curve for a particular transfer or a QV curve at a given bus, was not studied here because we don’t have yet VAST add-on and the ATC add-on packages.

Part A: Simulation of Some Power Electronics Case Studies in Matlab Simpowersystem Blockset

Part A: Simulation of Some Power Electronics Case Studies in MatlabSimpowersystem Blockset

By

Dr. Hidaia Mamood Alassouli

[email protected]

A.1 Introduction to Par A: Simulation of Some Power Electronics Case Studies in Matlab Simpowersystem Blockset

A.1 Introduction to Par A: Simulation of Some Power Electronics Case Studies in Matlab Simpowersystem Blockset

Electrical power systems are combinations of electrical circuits and electromechanical devices like motors and generators devices and sophisticated control system concepts that tax traditional analysis tools and techniques. Further complicating the analyst's role is the fact that the system is often so nonlinear that the only way to understand it is through simulation. Land-based power generation from hydroelectric, steam, or other devices is not the only use of power systems. A common attribute of these systems is their use of power electronics and control systems to achieve their performance objectives. Matlab SimPowerSystems[1] is a modern design tool that allows scientists and engineers to rapidly and easily build models that simulate power systems. It uses the Simulink environment, allowing you to build a model using simple click and drag procedures. SimPowerSystems toolbox is an efficient tool for modeling and simulating power system with FACTS devices and power converters. SimPowerSystems also is an efficient tool for modeling the dynamics of power system including all types of machines and controllers, i.e. modeling synchronous machines with governor, exciter and AVR, power system stabilizer, asynchronous machines, High Voltage DC Links (HVDC), DC motors and various speed controllers for DC and AC drives using power electronics converters. Reference [3] is one of the best references in studying multimachine system dynamics and stability. Reference [4] includes analysis of the properties of semiconductor devices and their applications as controlled rectifiers, inverters, cycloconverters, choppers, HVDC and solid state control of DC and AC motor. Reference [2], [5] include an overview of the principles of work of most FACTS devices.

The paper covers some case studies that provide detailed, realistic examples of how to use SimPowerSystems in modeling power system dynamics in various types of application that use power electronics converters. The following case studies are simulated on the paper:

1- Thyristor-Based Static Var Compensator.

2. Transient Stability of a Power System with SVC and PSS.

3. GTO-Based STATCOM.

4. Control of load flow using UPFC.

5- Control of AC motor.

6- Control of DC motor.

7- VSC-Based HVDC Link.

A.4. GTO-Based STATCOM

Fig. 6. Waveforms for 3 phase faults and SVC in voltage regulation mode