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Download the complete Electrical Engineering project topic and material (chapter 1-5) titled IMPLEMENTATION OF UNIFIED POWER FLOW CONTROLLER (UPFC) FOR IMPROVEMENT OF VOLTAGE STABILITY IN A CONGESTED ELECTRIC NETWORK here on PROJECTS.ng. See below for the abstract, table of contents, list of figures, list of tables, list of appendices, list of abbreviations and chapter one. Click the DOWNLOAD NOW button to get the complete project work instantly.

 

PROJECT TOPIC AND MATERIAL ON IMPLEMENTATION OF UNIFIED POWER FLOW CONTROLLER (UPFC) FOR IMPROVEMENT OF VOLTAGE STABILITY IN A CONGESTED ELECTRIC NETWORK

The Project File Details

  • Name:IMPLEMENTATION OF UNIFIED POWER FLOW CONTROLLER (UPFC) FOR IMPROVEMENT OF VOLTAGE STABILITY IN A CONGESTED ELECTRIC NETWORK
  • Type: PDF and MS Word (DOC)
  • Size: [1617KB]
  • Length: [50] Pages

 

ABSTRACT

As the demand of electricity from an already congested network increases, ensuring voltage stability across the network becomes challenging. One approach in ensuring system stability is to attain system redundancy but their economic and ecological limitations to this. A more cost effective means would involve the use of existing network component and incorporate less expensive scheme and policies to maintain reliable system operation. Flexible alternating Current Transmission System (FACTS) such as the Unified Power Flow Controller (UPFC) are devices incorporated to achieve improvement in overall system performance such s increasing transmission line flows, minimizing losses, and improving voltage profile across the network buses.

TABLE OF CONTENTS

Approval Page                                                                                      Vi

Certification                                                                                                    Vii

Dedication                                                                                             Viii

Acknowledgement                                                                                             Ix

Abstract                                                                                                  X

Table of Contents                                                                                   Xi

List of Figures                                                                                         Xiii

List of Tables                                                                                            Xiv

Introduction                                                                                                         1

1.1. Background                                                                                        1

1.2. Statement of Problem                                                                          2

1.3. Aim and Objective                                                                               2

1.4. Project Outline                                                                                     3

CHAPTER TWO                                                                                        4

LITERATURE REVIEW

2.1.1 Concept of FACT                                                                                      4

2.1.1. Voltage Stability                                                                                5

2.1.2. Voltage Collapse                                                                              5

2.1. CONVENTIONAL METHODS OF REACTIVE POWER                          7

COMPENSATION                                                                                     7

2.1.1. Shunt Reactors                                                                                 7

2.1.2. Shunt Capacitors                                                                              8

2.1.3. Synchronous Condensers                                                                           9

2.1.4. Load shedding                                                                                  10

2.1.5. Tap Changing of Transformers                                                                  10

2.2. FLEXIBLE ALTERNATING CURRENT TRANSMISSION SYSTEMS (FACTS)

2.2.1. Static Synchronous Compensator (STATCOM)                              12

2.2.2. Thyristor-Switched Series Capacitor (TSSC)                                            13

2.2.3. Static Synchronous Series Compensator (SSSC)                                       14

2.2.4. Thyristor-Controlled Series Capacitor (TCSC)                                16

2.2.5. Unified Power Flow Controller (UPFC)                                           17

CHAPTER THREE                                                                                    20

METHODOLOGY                                                                                     20

3.1. LOCATION OF UPLC                                                                        20

3.2. Newton Raphson Load Flow Method                                                 21

3.2.1. Formation of the Y-bus                                                                              24

3.2.2. Forming the Jacobian matrix                                                            25

3.3. Incorporating the UPLC in Newton Raphson Load Flow                             26

CHAPTER FOUR                                                                                                30

SIMULATION AND RESULTS ANALYSIS                                            30

CHAPTER FIVE                                                                                        35

CONCLUSION AND RECOMMENDATIONS                                         35

APPENDIX A                                                                                            38

References                                                                                                  43

 

LIST OF FIGURES

Figure 2. 1 A reactor located at 330/132KV transmission station in

Alaoji, Aba, Abia State                                                                              8

Figure 2. 2 A typical capacitor bank                                                           9

Figure 2. 3 A static synchronous compensator                                           13

Figure 2. 4.(a) circuit diagram of a TSSC, (b) course of capacitor voltage for

the basic element in a TSSC                                                                      13

Figure 2. 5:: (a) A two machine system with a series capacitor compensated line, (b) its associated phasor diagram                                                                15

Figure 2. 6:Thyristor-Controlled Series Capacitor (TCSC)                                   17

Figure 2. 7: Concept of the UPFC in a two-machine power system            18

Figure 2. 8: Implementation of UPLC                                                                   19

Figure 3. 1: One line diagram of the power system model                                     20

Figure 3. 2: A two bus system for illustrating Newton Raphson Power flows      24

Figure 3. 3:Unified power flow controller equivalent circuit                       26

Figure 4. 1:voltages of the buses without the UPFC between buses 3 and 4        31

Figure 4. 2: voltages of the buses with the UPFC between buses 3 and 4  32

 

LIST OF TABLES

Table 4. 1:Bus voltages without the UPFC                                                30

Table 4. 2.Line Flows and Losses without UPFC                                                31

Table 4. 3. Bus voltages with UPFC                                                          32

Table 4. 4. Line Flows and Losses with UPFC                                           33

Table 4. 5: voltages of the buses with and without the UPFC between buses

3 and 4                                                                                                      34

 

CHAPTER ONE

1.1. BACKGROUND

The control of voltage and power flows is a major issue in power system operation. This is because, due to the topological differences between distribution and transmission systems, different strategies have evolved.

This project contains contributions for power flows control and voltage stability schemes for distribution and transmission systems. A particular interest is taken to the development of control schemes to avoid so-called voltage collapse, which can result in widespread outages. In order to achieve efficient and reliable operation of power system, the control of voltage and reactive power should satisfy the following objectives:

  • Voltages at all terminals of all equipment in the system are within acceptable limits
  • System stability is enhanced to maximize utilization of the transmission system
  • The reactive power flow is minimized so as to reduce RI2 and XI2

This ensures that the transmission system operates mainly for active power. Since the power system supplies power to a vast number of loads and is feeding from many generating units, there is a problem of maintaining voltages within required limits. As load varies, the reactive power requirements of the transmission system vary. Since there is no cost free means of conveying reactive power over long distances, voltage control has to be effected by using special devices located through the system which possess difficulties in keeping sufficient levels of voltage in the power system network.

In recent decades, there has been significant progress in terms of equipment designed to improve the stability of voltage in power systems. This is mainly due to the development of power supply systems in the world, which requires seeking better ways of adjusting and controlling power flows and voltage levels

The proper selection and coordination of equipment for controlling reactive power and voltage stability are among the major challenges of power system engineering. These challenges necessitated the evolution of certain to achieve control or compensation of reactive power. In order to cover the additional demand for reactive power and retain the ability to control voltage stability acceptable range, various sources of reactive power, particularly of the FACTS family has been employed.

 

1.2. Statement of Problem

The characteristics of a given power system evolve with time, as load grows and generation is added. If the transmission facilities are not upgraded sufficiently the power system becomes vulnerable to steady-state and transient stability problems, as stability margins become narrower, posing a limit on the ability of these lines to transmit power. In principle, limitations on power transfer can always be relieved by the addition of new transmission and generation facilities. Conversely, these are not easy to come by, coupled with the high cost of executing such projects. Alternatively, UPFC can enable the same objectives to be met with no major alterations to system layout. How UPFC can be used to attain a great degree of power flow and voltage profile controllability in power system network is the challenge of this project.

 

1.3. Aim and Objective

1.3.1 Aim

To implement unified power flow controller (UPFC) for improvement of voltage stability in a congested electric network

 1.3.2 Objective

To develop mathematical models for transmission systems and UPFC, which can to be blended together, coded, and used extensively.

To illustrate the controllable features of  UPFC in active and reactive power flows in a transmission line.

To maintain the nodal voltage magnitudes in a power system in the limit for system security

 

1.4. Project Outline

Chapter 1 introduces the work carried out in this project and lists its objectives and

limitations.

Chapter 2 focuses on the literature review.

Chapter 3 presents the methodology adopted in completing the project, the modeling equations and mathematical solutions backing up the work.

Chapter 4 presents the simulation  work done in MATLAB and discuss the results.

Chapter 5 presents the conclusion, recommendations and future areas of research.

 

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