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Erschienen in:

2016 | OriginalPaper | Buchkapitel

1. Introduction

verfasst von : Haifeng Wang, Wenjuan Du

Erschienen in: Analysis and Damping Control of Power System Low-frequency Oscillations

Verlag: Springer US

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Abstract

Power system low-frequency oscillations are the oscillations of active power delivered along particular transmission corridors in a power system with the oscillation frequency from 0.1 Hz up to a couple of Hz. Once started, the oscillations can continue for a while and then disappear, or grow continuously to cause power system collapse. In this book, they are called power system oscillations or power oscillations for short.

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Nächstes Kapitel A Single-Machine Infinite-Bus Power System Installed with a Power System Stabilizer

IEEE/CIGRE Joint Task Force on Stability Terms and Definitions (2004) Definition and classification of power system stability. IEEE Trans Power Syst 19(2):1387–1401

Schleif FR, White JH (1966) Damping for the northwest-southwest tieline oscillations—an analogue study. IEEE Trans Power Appar Syst 85(12):1239–1247CrossRef

Gibson CM (1988) Application of power system stabilizers on the Anglo-Scottish interconnection—programme of system proving tests and operational experience. IEE Proc Part C 135(3):255–260MathSciNet

Hsu Y-Y, Shyue S-W, Su C-C (1987) Low frequency oscillations in longitudinal power systems: experience with dynamic stability of Taiwan power system. IEEE Trans Power Syst 2(1):92–98CrossRef

Western Electricity Coordinating Council (1996) Western systems coordinating council disturbance report. www.bpa.biz

deMello FP, Concordia C (1969) Concepts of synchronous machine stability as affected by excitation control. IEEE Trans Power Appar Syst 88(4):316–329

Heffron WG, Phillips RA (1952) Effect of modern amplidyne voltage regulators on underexcited operation of large turbine generators. AIEE Trans (Power Appar Syst) 71:692–697

deMello FP, Laskowski TF (1975) Concepts of power system dynamic stability. IEEE Trans Power Appar Syst 94(3):827–833

Larsen EV, Swann DA (1981) Applying power system stabilizers part I: general concepts. IEEE Trans Power Appar Syst 100(6):3017–3024CrossRef

10.

Larsen EV, Swann DA (1981) Applying power system stabilizers part II: performance objectives and tuning concepts. IEEE Trans Power Appar Syst 100(6):3025–3033CrossRef

11.

Larsen EV, Swann DA (1981) Applying power system stabilizers part III: practical considerations. IEEE Trans Power Appar Syst 100(6):3034–3046CrossRef

12.

Rogers G (2000) Power system oscillations. Kluwer Academic Publisher

13.

Perez-Arriaga IJ, Verghese GC, Schweppe FC (1982) Selective modal analysis with applications to electric power systems, Part I. IEEE Trans Power Appar Syst 101(9):3117–3125CrossRef

14.

Perez-Arriaga IJ, Verghese GC, Schweppe FC (1982) Selective modal analysis with applications to electric power systems, part II. IEEE Trans Power Appar Syst 101(9):3126–3134

15.

Sancha JL, Perez-Arriaga IJ (1988) Selective modal analysis of electric power system oscillatory instability. IEEE Trans Power Syst 3(2):429–438CrossRef

16.

Larsen EV, Sanchez-Gasca JJ, Chow JH (1995) Concept for design of FACTS controllers to damp power swings. IEEE Trans Power Syst 10(2):948–956CrossRef

17.

Wang HF (1999) Selection of robust installing locations and feedback signals of FACTS-based stabilizers in multi-machine power systems. IEEE Trans Power Syst 14(2):569–574CrossRef

18.

Hingorani NG (1988, Aug) High power electronics and flexible ac transmission systems. IEEE Power Eng Rev 3–4

19.

Gyugyi L (1992) Unified power-flow control; concept for flexible AC transmission systems. IEE Proc Part C 139(4):323–331

20.

Smith OJM (1969) Power system transient control by capacitor switching. IEEE Trans Power Appar Syst 88(1):28–35CrossRef

21.

Webster RH, Mane AP, Smith OJM (1971) Series capacitor switching to quench electromechanical transient in power systems. IEEE Trans Power Appar Syst 99(2):427–433

22.

Song YH, Johns AT (1999) Flexible AC transmission systems. IEE Press

23.

Hingorani NG, Gyugyi L (1999) Understanding FACTS. IEEE Press

24.

CIGRE TF 30-01-08 Report (1999) Modelling of power electronics equipment (FACTS) in load flow and stability programs

25.

Hsu CS, Lee WJ (1993) Superconducting magnetic energy storage for power system applications. IEEE Trans Ind Appl 29(5):990–996

26.

Xue XD, Cheng KWE, Sutanto D (2005) Power system applications of superconducting magnetic energy storage systems. In: Fourtieth IAS annual conference meeting on industry applications, vol 2, Oct 2005, pp 1524–1529

27.

Bhargava B, Dishaw G (1998) Application of an energy source power system stabilizer on the 10 MW battery energy storage system at Chino substation. IEEE Trans Power Syst 13(1):145–151

28.

Pourbeik P, Gibbard MJ (1996) Damping and synchronizing torques induced on generators by FACTS stabilizers in multimachine power systems. IEEE Trans Power Syst 11(4):1920–1925CrossRef

29.

Swift FJ, Wang HF (1995) Static Var compensator to damp system oscillations in multi-machine power systems. In: Proceedings of IEE APSCOM conference, Hong Kong

30.

Swift FJ, Wang HF (1996) Application of the controllable series compensator in damping power system oscillations. IEE Proc Part C 143(4):359–364

31.

Wang HF, Swift FJ (1997) The indexes for selecting the best locations of PSS or FACTS-based stabilizers in multi-machine power systems: a comparison study. IEE Proc Part C 144(2):155–159

32.

Abdalla OH, Hassan SA, Tweig NT (1984) Co-ordinated stabilisation of a multimachine power system. IEEE Trans Power Appar Syst 103(3):483–494CrossRef

33.

Okamoto H, Kurita A, Sekine Y (1995) A method for identification of effective locations of variable impedance apparatus on enhancement of steady-state stability in large-scale power systems. IEEE Trans Power Syst 10(3):1401–1407CrossRef

34.

Martins N, Lima LTG (1990) Determination of suitable locations for power system stabilizers and static VAR compensators for damping electromechanical oscillations in large power systems. IEEE Trans Power Syst 5(4):1455–1469CrossRef

35.

Yang X, Feliachi A (1994) Stabilization of inter-area oscillation modes through excitation systems. IEEE Trans Power Syst 9(1):494–502CrossRef

36.

Gooi HB, Hill EF, Mobarak MA, Thonne DH, Lee TH (1981) Coordinated multimachine stabilizer setting without eigenvalue drift. IEEE Trans Power Appar Syst 100(12):3879–3887CrossRef

Titel: Introduction
verfasst von: Haifeng Wang
Wenjuan Du
Verlag: Springer US
Buch: Analysis and Damping Control of Power System Low-frequency Oscillations
Print ISBN: 978-1-4899-7694-9

Electronic ISBN: 978-1-4899-7696-3

Copyright-Jahr: 2016
DOI: https://doi.org/10.1007/978-1-4899-7696-3_1