Power system transient analysis : theory and practice using simulation programs (ATP-EMTP) / Eiichi Haginomori [and three others].

Format:

Book

Author/Creator:

Haginomori, Eiichi, author.

Koshiduka, Tadashi, author.

Arai, Junichi, 1932-2017, author.

Ikeda, Hisatochi, author.

Language:

English

Subjects (All):

Transients (Electricity).

Physical Description:

1 online resource (411 p.)

Edition:

1st ed.

Place of Publication:

Chichester, West Sussex, United Kingdom : Wiley, 2016.

Language Note:

English

Summary:

Understanding transient phenomena in electric power systems and the harmful impact of resulting disturbances is an important aspect of power system operation and resilience. Bridging the gap from theory to practice, this guide introduces the fundamentals of transient phenomena affecting electric power systems using the numerical analysis tools, Alternative Transients Program- Electromagnetic Transients Program (ATP-EMTP) and ATP-DRAW. This technology is widely-applied to recognize and solve transient problems in power networks and components giving readers a highly practical and relevant perspective and the skills to analyse new transient phenomena encountered in the field. Key features: * Introduces novice engineers to transient phenomena using commonplace tools and models as well as background theory to link theory to practice. * Develops analysis skills using the ATP-EMTP program, which is widely used in the electric power industry. * Comprehensive coverage of recent developments such as HVDC power electronics with several case studies and their practical results. * Provides extensive practical examples with over 150 data files for analysing transient phenomena and real life practical examples via a companion website. Written by experts with deep experience in research, teaching and industry, this text defines transient phenomena in an electric power system and introduces a professional transient analysis tool with real examples to novice engineers in the electric power system industry. It also offers instruction for graduates studying all aspects of power systems.

Contents:

Intro

Title Page

Table of Contents

Preface

Part I: Standard Course-Fundamentals and Typical Phenomena

1 Fundamentals of EMTP

1.1 Function and Composition of EMTP

1.2 Features of the Calculation Method

References

2 Modeling of System Components

2.1 Overhead Transmission Lines and Underground Cables

2.2 Transformer

3 Transient Currents in Power Systems

3.1 Short-Circuit Currents

3.2 Transformer Inrush Magnetizing Current

3.3 Transient Inrush Currents in Capacitive Circuits

Appendix 3.A: Example of ATPDraw Sheets-Data3-02.acp

Reference

4 Transient at Current Breaking

4.1 Short-Circuit Current Breakings

4.2 Capacitive Current Switching

4.3 Inductive Current Switching

4.4 TRV with Parallel Capacitance in SLF Breaking

Appendix 4.A: Current Injection to Various Circuit Elements

Appendix 4.B: TRV Calculation, Including ITRV-Current Injection is Applied for TRV Calculation

Appendix 4.C: 550 kV Line Normal Breaking

Appendix 4.D: 300 kV, 150 MVA Shunt Reactor Current Breaking-Current Chopping-Reignition-HF Current Interruption

5 Black Box Arc Modeling

5.1 Mayr Arc Model

5.2 Cassie Arc Model

Appendix 5.A: Mayr Arc Model Calculating SLF Breaking, 300 kV, 50 kA, L90 Condition

Appendix 5.B: Zero Skipping Current Breaking Near Generator-Fault Current Lasting

Appendix 5.C: Zero Skipping Current Breaking Near Generator-Dynamic Arc Introduced, Still Nonbreaking

6 Typical Power Electronics Circuits in Power Systems

6.1 General

6.2 HVDC Converter/Inverter Circuits

6.3 Static Var Compensator/Thyristor-Controlled Inductor

6.4 PWM Self-Communicated Type Inverter Applying the Triangular Carrier Wave Shape Principle-Applied to SVG (Static Var Generator)

Appendix 6.A: Example of ATPDraw Picture

Reference.

Part II: Advanced Course-Special Phenomena and Various Applications

7 Special Switching

7.1 Transformer-Limited Short-Circuit Current Breaking

7.2 Transformer Winding Response to Very Fast Transient Voltage

7.3 Transformer Magnetizing Current under Geomagnetic Storm Conditions

7.4 Four-Armed Shunt Reactor for Suppressing Secondary Arc in Single-Pole Rapid Reclosing

7.5 Switching Four-Armed Shunt Reactor Compensated Transmission Line

8 Synchronous Machine Dynamics

8.1 Synchronous Machine Modeling and Machine Parameters

8.2 Some Basic Examples

8.3 Transient Stability Analysis Applying the Synchronous Machine Model

Appendix 8.A: Short-Circuit Phenomena Observation in d-q Domain Coordinate

Appendix 8.B: Starting as an Induction Motor

Appendix 8.C: Modeling by the No. 19 Universal Machine

Appendix 8.D: Example of ATPDraw Picture File: Draw8-111.acp (Figure D8.1).

9 Induction Machine, Doubly Fed Machine, Permanent Magnet Machine

9.1 Induction Machine (Cage Rotor Type)

9.2 Doubly Fed Machine

9.3 Permanent Magnet Machine

Appendix 9.A: Appendix Doubly Fed Machine Vector Diagrams

Appendix 9.B: Appendix Example of ATPDraw Picture

10 Machine Drive Applications

10.1 Small-Scale System Composed of a Synchronous Generator and Induction Motor

10.2 Cycloconverter

10.3 Cycloconverter-Driven Synchronous Machine

10.4 Flywheel Generator: Doubly Fed Machine Application for Transient Stability Enhancement

Appendix 10.A: Appendix Example of ATPDraw Picture

Index

End User License Agreement.

Notes:

Description based upon print version of record.

Includes bibliographical references and index.

Description based on print version record.

ISBN:

9781118737477

1118737474

9781118737491

1118737490

9781118737453

1118737458

OCLC:

922799588