Transmission and Distribution of Electrical Engineering - 3rd edition by Dr C. R. Bayliss & B. J. Hardy

Transmission and Distribution of Electrical Engineering - 3rd edition by Dr C. R. Bayliss & B. J. Hardy

Transmission and Distribution of Electrical Engineering

Author: Dr C. R. Bayliss and B. J. Hardy.

Published by: Elsevier Ltd.

Release Date: 18 Dec 2006.
Edition: 3rd.

Copyright © 2007, Colin Bayliss and Brian Hardy. Elsevier Ltd. All rights reserved.

ISBN-13: 978-0-7506-6673-2.

ISBN-10: 0-7506-6673-0.

Format: PDF.

Size: 17.33MB.

Pages: 1039.

Quality: Very Good.

OCR: Yes.

Book Description:

Most books on transmission and distribution electrical engineering are student texts that focus on theory, brief overviews, or specialised monographs. Colin Bayliss and Brian Hardy have produced a unique and comprehensive handbook aimed squarely at practising engineers and planners involved in all aspects of getting electricity from the power plant to the user via the power grid. 

The scope of this book embraces power systems, substations, cabling, switchgear, power systems protection, overhead lines, project management, planning, regulations, and more...

The third edition has been fully updated throughout in line with current IEC and European standards, an approach which has resulted in a thoroughly rewritten chapter on earthing and bonding and significant revisions to the chapters on EMC, insulation coordination and overhead line design. There is increased emphasis on reliability concepts and greatly expanded treatment of the subject of power quality..

The resulting book is an essential guide and a hard-working reference for all engineers, technicians, managers and planners involved in the electricity supply industry, and related areas such as generation, and industrial electricity usage.

Key Features:

1. A reference handbook written by engineers for engineers

2. Unrivalled in its scope, covering systems, substations, cabling, switchgear, power systems protection, overhead lines, project management, planning, regulations, and more...

3. The third edition includes expanded sections on power quality, a thoroughly updated section on earthing and bonding, and coverage of the integration embedded generation and renewables in modern power systems

Table of Contents:

Chapter 1: System Studies

1.1 Introduction

1.2 Load flow

1.3 System Stability

1.4 Short circuit analysis

Chapter 2: Drawings and Diagrams

2.1 Introduction

2.2 Block diagrams

2.3 Schematic diagrams

2.4 Manufacturers' drawings

2.5 Computer aided design (CAD)

2.6 Case study

2.7 Graphical symbols

Appendices

Chapter 3: Substation Layouts

3.1 Introduction

3.2 Substation design considerations

3.3 Alternative layouts

3.4 Space requirements

Chapter 4: Substation Auxiliary Power Supplies

4.1 Introduction

4.2 DC supplies

4.3 Batteries

4.4 AC supplies

Chapter 5: Current and Voltage Transformers

5.1 Introduction

5.2 Current transformers

5.3 Voltage transformers

5.4 Future trends

Chapter 6: Insulators

6.1 Introduction

6.2 Insulator materials

6.3 Insulator types

6.4 Pollution control

6.5 Insulator specification

6.6 Tests

Chapter 7: Substation Building Services

7.1 Introduction

7.2 Lighting

7.3 Distribution characterization

7.4 Heating, ventilation and air-conditioning

7.5 Fire detection and suppression

Chapter 8: Earthing and Bonding

8.1 Introduction

8.2 Design criteria

8.3 Substation earthing calculations

8.4 Computer simulation

References

Chapter 9: Insulation Co-ordination

9.1 Introduction

9.2 System voltages

9.3 Clearances

9.4 Procedures for co-ordination

9.5 Surge protection

References

Chapter 10: Relay Protection

10.1 Introduction

10.2 System configuration

10.3 Power system protection principles

10.4 Current relays

10.5 Differential protection schemes

10.6 Distance relays

10.7 Auxiliary relays

10.8 Computer assisted grading exercise

10.9 Practical distribution network case study

10.10 Recent advances in control, protection and monitoring

References

Chapter 11: Fuses and Miniature Circuit Breakers

11.1 Introduction

11.2 Fuses

11.3 Fuse operation

11.4 Miniature circuit breakers

References

Chapter 12: Cables

12.1 Introdcution

12.2 Codes and standards

12.3 Types of cables and materials

12.4 Cable sizing

12.5 Calculation of losses in cables

12.6 Fire properties of cables

12.7 Control and communication cables

12.8 Cable management systems

References

Chapter 13: Switchgear

13.1 Introduction

13.2 Terminology and standards

13.3 Switching

13.4 Arc quenching media

13.5 Operating mechanisms

13.6 Equipment specifications

References

Chapter 14: Power Transformers

14.1 Introduction

14.2 Standards and principles

14.3 Voltage, impedance and power rating

14.4 Thermal design

14.5 Constructional aspects

14.6 Accessories

References

Chapter 15: Substation and Overhead Line Foundations

15.1 Introduction

15.2 Soil investigations

15.3 Foundation types

15.4 Foundation design

15.5 Site works

Chapter 16: Overhead Line Routing

16.1 Introduction

16.2 Routing objectives

16.3 Preliminary routing

16.4 Detailed line survey and profile

Chapter 17: Structures, Towers and Poles

17.1 Introduction

17.2 Environmental conditions

17.3 Structure design

17.4 Pole and tower types

Chapter 18: Overhead Line Conductor and Technical Specifications

18.1 Introduction

18.2 Environmental conditions

18.3 Conductor selection

18.4 Calculated electrical ratings]

18.5 Design spans, clearances and loadings

18.6 Overhead line fittings

18.7 Overhead line impedance

18.8 Substation busbar selection- case study

References

Chapter 19: Testing and Commissioning

19.1 Introduction

19.2 Quality assurance

19.3 Works inspections and testing

19.4 Site inspection and testing

19.5 Testing and commissioning methods

Appendices

Chapter 20: Electromagnetic Compatibility

20.1 Introduction

20.2 Standards

20.3 Compliance

20.4 Testing

20.5 Screening

20.6 Typical useful formulae

20.7 Case studies

Chapter 21: Supervisory Control and Data Acquisition

21.1 Introduction

21.2 Programmable logic controllers

21.3 Power line carrier communication links

21.4 Supervisory control and data acquisition

21.5 Software management

References

Chapter 22: Project Management

22.1 Introduction

22.2 Project Evaluation

22.3 Financing

22.4 Project phases

22.5 Terms and conditions of contract

22.6 Tendering

22.7 Model forms of contract- exercise

Appendices

Chapter 23: Distribution Planning

23.1 Introduction

23.2 Definitions

23.3 Load forecasting

23.4 System parameters

23.5 System reliability

23.6 Drawings and materials take off

Chapter 24: Power Quality- Harmonics in Power Systems

24.1 Introduction

24.2 The nature of harmonics

24.3 The generation of harmonics

24.4 The effects of harmonics

24.5 The limitations of harmonics

24.6 Ferroresonance and subharmonics

24.7 Harmonic studies

24.8 Case studies

References

Chapter 25: Power Quality - Voltage Fluctuations

25.1 Introduction

25.2 The nature and cause of voltage disturbances in power systems

25.3 Solutions

25.4 Case Study

References

Chapter 26: Fundamentals

26.1 Introduction

26.2 Symbols and nomenclature

26.3 Alternating quantities

26.4 Vector representation

26.5 Vector algebra

26.6 Sequence components

26.7 Network fault analysis

26.8 Design optimization

References

Index

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