使用智能潮流控制器的现代电网潮流控制方案 Power Flow Control Solutions For A Modern Grid Using Smart Power Flow Controllers

基本信息

Series:IEEE Press Series on Power and Energy Systems

Format:Hardback 720 pages

Publisher:John Wiley & Sons Inc

Imprint:Wiley-IEEE Press

ISBN:9781119824350

Published:4 Jan 2022

Weight:1444g

Dimensions:254 x 178 (mm)

页面参数仅供参考，具体以实物为准

书籍简介

使用智能功率流控制器的现代电网功率流控制解决方案

为学生和执业工程师提供进行电力系统网络研究和缓解独特功率流问题所需的基础

使用智能功率流控制器的现代电网功率流控制解决方案是对复杂传输系统中的功率流控制的清晰易懂的介绍。作者从基本的电气工程概念和理论开始，逐步解释各种功率流控制器 (PFC) 的建模技术，例如电压调节变压器 (VRT)、相角调节器 (PAR) 和统一功率流控制器 (UPFC)。教科书涵盖了 Sen 变压器 (ST) 的新进展，包括各种形式的双芯设计和适用于各种应用的混合架构。

作者从概述现代功率流控制器的起源和发展开始，用直截了当的工程术语解释每个主题——用相关数学证实理论。本书通俗易懂的章节介绍了各种功率流控制器的特征方程，解释了电磁瞬变程序 (EMTP) 中的建模，比较了基于变压器和机械开关的 PFC，讨论了电网拥塞和功率流限制等。这本综合性教科书：

描述了为什么有效的功率流控制器应被视为阻抗调节器

以 EMTP 编程语言提供各种功率流控制器的计算机模拟代码

包含大量工作示例和数据案例以阐明复杂问题

包括实际网络模拟研究的结果

以一代 FACTS 控制器的共同发明者作者的真实经验为基础的模型

由该领域两位公认的专家撰写，《使用 SMART 功率流控制器实现现代电网的功率流控制解决方案》是电气工程研究生的理想教科书，也是电力工程从业者、监管者和研究人员的经典书籍。

Power Flow Control Solutions for a Modern Grid using SMART Power Flow Controllers

Provides students and practicing engineers with the foundation required to perform studies of power system networks and mitigate unique power flow problems

Power Flow Control Solutions for a Modern Grid using SMART Power Flow Controllers is a clear and accessible introduction to power flow control in complex transmission systems. Starting with basic electrical engineering concepts and theory, the authors provide step-by-step explanations of the modeling techniques of various power flow controllers (PFCs), such as the voltage regulating transformer (VRT), the phase angle regulator (PAR), and the unified power flow controller (UPFC). The textbook covers the most up-to-date advancements in the Sen transformer (ST), including various forms of two-core designs and hybrid architectures for a wide variety of applications.

Beginning with an overview of the origin and development of modern power flow controllers, the authors explain each topic in straightforward engineering terms—corroborating theory with relevant mathematics. Throughout the text, easy-to-understand chapters present characteristic equations of various power flow controllers, explain modeling in the Electromagnetic Transients Program (EMTP), compare transformer-based and mechanically-switched PFCs, discuss grid congestion and power flow limitations, and more. This comprehensive textbook:

Describes why effective Power Flow Controllers should be viewed as impedance regulators

Provides computer simulation codes of the various power flow controllers in the EMTP programming language

Contains numerous worked examples and data cases to clarify complex issues

Includes results from the simulation study of an actual network

Features models based on the real-world experiences the authors, co-inventors of first-generation FACTS controllers

Written by two acknowledged leaders in the field, Power Flow Control Solutions for a Modern Grid using SMART Power Flow Controllers is an ideal textbook for graduate students in electrical engineering, and a must-read for power engineering practitioners, regulators, and researchers.

作者简介

Kalyan K. Sen，博士，PE（宾夕法尼亚州和纽约州），MBA，IEEE 院士，是 Sen Engineering Solutions, Inc. 的总裁兼首席技术官。他是西屋科技中心 ​​FACTS 开发团队的关键成员，在那里他开发了一些 FACTS 技术的基本概念。他是 IEEE 杰出讲师，也是《FACTS 控制器简介：理论、建模和应用》的合著者。

Mey Ling Sen，MEE，IEEE 会员，是 Sen Engineering Solutions, Inc. 的运营官。此前，她曾担任西屋机电部门技术中心的顾问工程师。Sen 女士是 Sen 变压器的共同发明者，该变压器是高效、可靠、具成本效益的智能功率流控制器 (SPFC)。

Kalyan K. Sen, PhD, PE (PA & NY), MBA, IEEE Fellow, is President and Chief Technology Officer at Sen Engineering Solutions, Inc. He was a key member of the FACTS development team at Westinghouse Science & Technology Center, where he developed some of the basic concepts of FACTS technology. He is an IEEE Distinguished Lecturer, and is the co-author of Introduction to FACTS Controllers: Theory, Modeling, and Applications.

Mey Ling Sen, MEE, IEEE Member, is Chief Operating Officer at Sen Engineering Solutions, Inc. Previously, she was a consultant engineer at the Westinghouse Electro-Mechanical Division Technology Center. Ms. Sen is the co-inventor of the Sen transformer, which is the most efficient, reliable, and cost-effective SMART power flow controller (SPFC).

部分目录，仅供参考

Authors’ Biographies xiii

Foreword xv

Nomenclature xix

Preface xxv

Acknowledgments xxix

About the Companion Website xxxi

1 Smart Controllers 1

1.1 Why is a Power Flow Controller Needed? 1

1.2 Traditional Power Flow Control Concepts 5

1.3 Modern Power Flow Control Concepts 14

1.4 Cost of a Solution 22

1.4.1 Defining a Cost-Effective Solution 22

1.4.2 Payback Time 24

1.4.3 Economic Analysis 24

1.5 Independent Active and Reactive PFCs 26

1.6 SMART Power Flow Controller (SPFC) 39

1.6.1 Example of an SPFC 40

1.6.2 Justification 41

1.6.3 Additional Information 41

1.7 Discussion 42

2 Power Flow Control Concepts 45

2.1 Power Flow Equations for a Natural or Uncompensated Line 60

2.2 Power Flow Equations for a Compensated Line 63

2.2.1 Shunt-Compensating Voltage 67

2.2.1.1 Power Flow at the Modified Sending End with a Shunt-Compensating Voltage 70

2.2.1.2 Power Flow at the Receiving End with a Shunt-Compensating Voltage 73

2.2.1.3 Exchanged Power by a Shunt-Compensating Voltage 79

2.2.1.4 Representation of a Shunt-Compensating Voltage as a Shunt-Compensating Impedance 79

2.2.2 Series-Compensating Voltage as an Impedance Regulator, Voltage Regulator, and Phase Angle Regulator (Asymmetric) 80

2.2.2.1 Power Flow at the Sending End with a Series-Compensating Voltage 92

2.2.2.2 Power Flow at the Receiving End with a Series-Compensating Voltage 95

2.2.2.3 Power Flow at the Modified Sending End with a Series-Compensating Voltage 100

2.2.2.4 Exchanged Power by a Series-Compensating Voltage 109

2.2.2.5 Additional Series-Compensating Voltages 126

2.2.2.5.1 Phase Angle Regulator (Symmetric) 126

2.2.2.5.2 Reactance Regulator 129

2.2.2.5.2.1 Reactance Control Method 137

2.2.2.5.2.2 Voltage Control Method 139

2.2.2.6 Representation of a Series-Compensating Voltage as a Series-Compensating Impedance 145

2.2.2.6.1 Equivalent Impedance of a Voltage Regulator (VR) 152

2.2.2.6.2 Equivalent Impedance of a Phase Angle Regulator (Asymmetric) 154

2.2.2.6.3 Equivalent Impedance of a Phase Angle Regulator (Symmetric) 157

2.2.2.6.4 Equivalent Impedance of a Reactance Regulator 160