IEEE 1110-2002
Superseded
A superseded Standard is one, which is fully replaced by another Standard, which is a new edition of the same Standard.
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IEEE Guide for Synchronous Generator Modeling Practices and Applications in Power System Stability Analyses
02-03-2020
English
12-11-2003
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1 Overview and objectives
1.1 Introduction
1.2 Specialized problems in stability not discussed in
this guide
1.3 Overview of the guide
2 References
3 Classification of power system stability and synchronous
machine modeling requirements
3.1 General background
3.2 Rotor-angle stability
3.3 Voltage stability
3.4 Frequency stability
3.5 Modeling requirements for synchronous machines
4 Types of models available
4.1 Introduction
4.2 Terminology
4.3 Direct-axis model structures
4.4 Quadrature-axis model structures
4.5 Constant-voltage-behind-reactance model
4.6 Field-winding per-unit systems
4.7 Generator to power system interfacing
5 Application of generator models in stability studies
5.1 General
5.2 Modeling considerations based on categories of stability
5.3 Modeling considerations based on rotor structure
5.4 Use of simplified models
6 Representation of saturation and its effect on synchronous
generator performance
6.1 General
6.2 Representation of synchronous generator saturation
in the steady state
6.3 Representation of saturation effect during large
disturbances
6.4 Generator saturation in small-disturbance modeling
7 Determination of generator stability parameters
7.1 Introduction
7.2 Parameter determination by tests
7.3 Parameters derived by manufacturers
7.4 Data translation
Annex A (informative) Bibliography
Annex B (normative) List of main symbols
Annex C (informative) Calculation of generator electrical
torque or power
Annex D (informative) Procedures in a widely used stability
program to account for saturation when adjusting mutual
reactances
Annex E (informative) Sample matlab listing
Categorizes three direct-axis and four quadrature-axis models, along with the basic transient reactance model. It also discusses some of the assumptions made in using various models and presents the fundamental equations and concepts involved in generator/system interfacing. Also covers, generally, the various attributes of power system stability, recognizing two basic approaches.
| Committee |
Electric Machinery
|
| DocumentType |
Standard
|
| Pages |
80
|
| PublisherName |
Institute of Electrical & Electronics Engineers
|
| Status |
Superseded
|
| SupersededBy | |
| Supersedes |
| IEEE 421.6-2017 | IEEE Recommended Practice for the Specification and Design of Field Discharge Equipment for Synchronous Machines |
| IEEE 115-2009 REDLINE | IEEE Guide for Test Procedures for Synchronous Machines Part I—Acceptance and Performance Testing Part II—Test Procedures and Parameter Determination for Dynamic Analysis |
| IEEE 45.3-2015 | IEEE Recommended Practice for Shipboard Electrical Installations -- Systems Engineering |
| IEEE 421.5-2005 | IEEE Recommended Practice for Excitation System Models for Power System Stability Studies |
| 16/30342504 DC : 0 | BS EN 61970-302 ED 1.0 - ENERGY MANAGEMENT SYSTEM APPLICATION PROGRAM INTERFACE (EMS-API) - PART 302: CIM FOR DYNAMICS |
| IEEE 115-2009 REDLINE | IEEE Guide for Test Procedures for Synchronous Machines Part I—Acceptance and Performance Testing Part II—Test Procedures and Parameter Determination for Dynamic Analysis |
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