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Homepage>IEEE Standards>29 ELECTRICAL ENGINEERING>29.160 Rotating machinery>29.160.20 Generators>IEEE 1110-2002 - IEEE Guide for Synchronous Generator Modeling Practices and Applications in Power System Stability Analyses
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Released: 12.11.2003

IEEE 1110-2002 - IEEE Guide for Synchronous Generator Modeling Practices and Applications in Power System Stability Analyses

IEEE Guide for Synchronous Generator Modeling Practices and Applications in Power System Stability Analyses

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Standard number:IEEE 1110-2002
Released:12.11.2003
ISBN:978-0-7381-3482-6
Pages:80
Status:Active
Language:English
DESCRIPTION

IEEE 1110-2002

Review all 7 chapters of the existing Standard and determine which chapters, if any, need updating or significant additions. Correct, where applicable, existing typographical errors. Suggest, when necessary, new figures, illustrations, or references.

The modeling of synchronous machines for stability studies and analyses is subject to continuing review and possible improvements. Both parameter identification for dynamic analysis and accounting for generator saturation must be included. Emphasis will be placed on discussing various aspects of Synchronous Generator/Power System interactions.

Revision Standard - Superseded. Revision of IEEE Std 1110-1991. Reaffirmed September 2007. Categorizes three direct-axis and four quadrature-axis models, along with the basic transient reactance model. Discusses some of the assumptions made in using various models and presents the fundamental equations and concepts involved in generator/system interfacing. Covers, generally, the various attributes of power system stability, recognizing two basic approaches. The first is categorized under large disturbance nonlinear analysis; the second approach considers small disturbances, where the corresponding dynamic equations are linearized. Applications of a range of generator models are discussed and treated. The manner in which generator saturation is treated in stability studies, both in the initialization process as well as during large or small disturbance stability analysis procedures is addressed. Saturation functions that are derived, whether from test data or by the methods, of finite elements are developed. Different saturation algorithms for calculating values of excitation and internal power angle depending upon generator terminal conditions are compared. The question of parameter determination is covered. Two approaches in accounting for generator field and excitation system base quantities are identified. Conversion factors are given for transferring field parameters from one base to another for correct generator/excitation system interface modeling, Suggestions for modeling of negative field currents and other field circuit discontinuities are included.