Turbine generator laboratory model tests to damp torsional oscillations with supplementary signals

Author

Sokhey, I.S. ; Limebeer, D.J.N. ; MacDonald, D.C.

Author_Institution

Southern Electric plc, Maidenhead, UK

Volume

8

Issue

1

fYear

1993

fDate

3/1/1993 12:00:00 AM

Firstpage

85

Lastpage

91

Abstract

The improvement of generator stability by the use of supplementary signals into the voltage regulator and governor loops using discrete-time linear optimal control theory has been studied with particular emphasis on providing better damping for torsional oscillations. A multi-inertia laboratory model equipped with data acquisition and control computers was constructed to model the shaft dynamics of a 660 MW Drax turbine-generator. It is shown that the shaft torsional phenomena can be adequately simulated on a micro-synchronous-generator at least as far as the dominant shaft torsional modes of vibration are concerned. The practical implementation of multi-mode linear quadratic Gaussian (LQG) controllers has been shown to enhance system stability and provide better damping to the lower frequency torsional modes, which are those most susceptible to excitation

Keywords

damping; discrete time systems; machine control; machine testing; oscillations; stability; torsion; turbogenerators; voltage control; 660 MW; Drax power station; control computers; data acquisition; discrete-time linear optimal control; generator stability; governor loops; laboratory model tests; linear quadratic Gaussian controllers; micro-synchronous-generator; shaft torsional phenomena; supplementary signals; torsional oscillations damping; turbine-generator; turbogenerators; voltage regulator; Damping; Data acquisition; Laboratories; Optimal control; Regulators; Shafts; Signal generators; Stability; Testing; Turbines;

fLanguage

English

Journal_Title

Energy Conversion, IEEE Transactions on

Publisher

ieee

ISSN

0885-8969

Type

jour

DOI

10.1109/60.207410

Filename

207410