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Erschienen in:
Introduction: The Key Role of the Transmission Network Kapitel lesen Erstes Kapitel lesen

2021 | OriginalPaper | Buchkapitel

9. Stability Considerations for Transmission System Planning

verfasst von : Francisco M. Echavarren, Lukas Sigrist

Erschienen in: Transmission Expansion Planning: The Network Challenges of the Energy Transition

Verlag: Springer International Publishing

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Abstract

Transmission system operators are required to elaborate the planning schedule for the network in various time horizons, from short-term to long-term. Traditionally stability studies have been carried out as short-term and/or mid-term planning tasks, but they have been not considered for long-term planning, where the main goal is generation-demand balance. However, the paradigm is shifting due to diverse factors, such as the sustained growth of the demand, the expansion of transmission networks, the increasing number of power electronics associated with renewable energy resources and advance control devices, or higher inter-area energy interchanges, among others. Due to these facts, power system stability and dynamic studies need to receive more attention in long-term planning to prevent future incidents and guarantee the robustness of the system. The objective of this chapter is to provide an overview of the power system stability phenomena and their increasing relevance for transmission planning issues.

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Vorheriges Kapitel The Impact of Distributed Energy Resources on the Networks
Nächstes Kapitel Energy Storage Systems in Transmission Expansion Planning
Literatur
1.
C.A. Cañizares, On bifurcations, voltage collapse and load modeling. Power Syst. IEEE Trans. 10(1), 512–522 (1995)CrossRef
2.
Cañizares, C.A., 2002. Voltage Stability Assessment: Concepts, Practices and Tools
3.
C.A. Cañizares, F.L. Alvarado, Point of collapse and continuation methods for large AC/DC systems. IEEE Trans. Power Syst. 8(1), 1–8 (1993)CrossRef
4.
K.E. Chen, A. Hussein, M.E. Bradley, H. Wan, A performance-index guided continuation method for fast computation of saddle-node bifurcation in power systems. IEEE Trans. Power Syst. 18(2), 753–760 (2003)CrossRef
5.
B. Cova, O. Fosso, D. D’hoop, E. Ãhlund, A. Braun, K. Lakmeeharan, E. Lerch, J. Lrivacoba, T. Nguyen, Y. Noro, V. Sermanson, Y. Sankar, W. Sattinger, F. Silvestro, Application and required developments of dynamic models to support practical planning. ELECTRA, 230 (2007)
6.
A.C.Z. De Souza, C.A. Canizares, V.H. Quintana, New techniques to speed up voltage collapse computations using tangent vectors. Power Syst. IEEE Trans. 12(3), 1380–1387 (1997)CrossRef
7.
I. Dobson, Observations on the geometry of saddle node bifurcation and voltage collapse in electrical power systems. Circ. Syst. I Fundam. Theory Appl. IEEE Trans. 39(3), 240–243 (1992)CrossRef
8.
I. Dobson, H. Glavitsch, L.I.U. Chen-Ching, Y. Tamura, K. Vu, Voltage collapse in power systems. Circ. Devices Mag. IEEE 8(3), 40–45 (1992)CrossRef
9.
F.M. Echavarren, E. Lobato, R. Rouco, Contingency analysis: Feasibility identification and calculation algorithm. IEE Proc. Gener. Transm. Distrib. 152(5), 645–652 (2005)CrossRef
10.
F.M. Echavarren, E. Lobato, L. Rouco, T. Gomez, Formulation, computation and improvement of steady state security margins in power systems. Part I: Theoretical framework. Int. J. Electr. Power Energy Syst. 33(2), 340–346 (2011a)CrossRef
11.
F.M. Echavarren, E. Lobato, L. Rouco, T. Gómez, Formulation, computation and improvement of steady state security margins in power systems. Part II: Results. Int. J. Electr. Power Energy Syst. 33(2), 347–358 (2011b)CrossRef
12.
I.A. Hiskens, D.J. Hill, Energy functions, transient stability and voltage behaviour in power systems with nonlinear loads. IEEE Trans. Power Syst. 4(4), 1525–1533 (1989)CrossRef
13.
C. Hsiao-Dong, R. Jean-Jumeau, Toward a practical performance index for predicting voltage collapse in electric power systems. IEEE Trans. Power Syst. 10(2), 584–592 (1995)CrossRef
14.
IEEE Power System Relaying Committee, Voltage Collapse Mitigation (1996)
15.
G.D. Irisarri, X. Wang, J. Tong, S. Mokhtari, Maximum loadability of power systems using interior point nonlinear optimization method. IEEE Trans. Power Syst. 12(1), 162–172 (1997)CrossRef
16.
P. Kundur, N.J. Balu, M.G. Lauby, Power System Stability and Control (McGraw-Hill, 1994)
17.
P. Kundur, J. Paserba, V. Ajjarapu, G. Andersson, A. Bose, C. Canizares, N. Hatziargyriou, D. Hill, A. Stankovic, C. Taylor, T. Van Cutsem and V. Vittal, 2004. Definition and Classification of Power System Stability IEEE/CIGRE Joint Task Force on Stability Terms and Definitions
18.
D.H.A. Lee, Voltage stability assessment using equivalent nodal analysis. IEEE Trans. Power Syst. 31(1), 454–463 (2016)CrossRef
19.
P.A. Lof, T. Smed, G. Andersson, D.J. Hill, Fast calculation of a voltage stability index. IEEE Trans. Power Syst. 7(1), 54–64 (1992)CrossRef
20.
M. Stubbe (Convener). Long Term Dynamics, Phase II, Cigré Task Force 38.02.08 – TB 102. CIGRE (1995)
21.
J. Machowski, P. Kacejko, S. Robak, P. Miller, M. Wancerz, Power system stability screening for long-term planning of transmission network development, in 2013 12th International Conference on Environment and Electrical Engineering 2013, (2013), pp. 100–105CrossRef
22.
Renedo, J., García-Cerrada, A. and Rouco, L., 2016a. Active Power Control Strategies for Transient Stability Enhancement of AC/DC Grids with VSC-HVDC Multi-Terminal SystemsCrossRef
23.
J. Renedo, A. García-Cerrada, L. Rouco, Reactive-Power Coordination in VSC-HVDC Multi-Terminal Systems for Transient Stability Improvement (IEEE Transactions on Power Systems, 2016b), pp. 1–1
24.
L. Rouco, Coordinated design of multiple controllers for damping power system oscillations. Int. J. Electr. Power Energy Syst. 23, 517–530 (2001)CrossRef
25.
L. Rouco, F. Pagola, An eigenvalue sensitivity approach to location and controller design of controllable series capacitor for damping power system oscillations. Power Syst. IEEE Trans. 12, 1660 (1997)CrossRef
26.
R. Seydel, A Continuation Algorithm with Step Control, in Numerical Methods for Bifurcation Problems., Aug 22–26, 1983, (1984), pp. 480–494CrossRef
27.
L. Sigrist, L. Rouco, Damping Electromechanical Oscillations with Both Ratio and Phase Modulation of Static Synchronous Series Sources: Controller Design (2007), p. 316
28.
L. Sigrist, L. Rouco, An induction motor model for system frequency response models. Int. Trans. Electr Energy Syst. 27 (2017)
29.
L. Sigrist, I. Egido, L. Rouco, A method for the design of UFLS schemes of small isolated power systems. IEEE Trans. Power Syst. 27, 951–958 (2012)CrossRef
30.
L. Sigrist, I. Egido, L. Rouco, Principles of a centralized UFLS scheme for small isolated power systems. IEEE Trans. Power Syst. 28(2), 1779–1786 (2013)CrossRef
31.
L. Sigrist, F. Echavarren, L. Rouco, P. Panciatici, A fundamental study on the impact of HVDC lines on transient stability of power systems, in 2015 IEEE Eindhoven PowerTech, (2015), pp. 1–6
32.
L. Sigrist, E. Lobato, F.M. Echavarren, I. Egido, L. Rouco, Island Power Systems (CRC Press, 2016)
33.
L. Sigrist, L. Rouco, F. Echavarren, A review of the state of the art of UFLS schemes for isolated power systems. Int. J. Electr. Power Energy Syst. 99, 525–539 (2018)CrossRef
34.
Sorensen, P., Fortmann, J., Jiménez Búendía, F., Bech, J., Morales, A. and Ivanov, C., 2014. Final Draft International Standard IEC 61400-27-1
35.
C.W. Taylor, N.J. Balu, D. Maratukulam, Power System Voltage Stability (McGraw-Hill Ryerson, Limited, 1994)
36.
37.
T. Van Cutsem, Voltage Stability of Electric Power Systems (Springer, 2007)
Metadaten
Titel
Stability Considerations for Transmission System Planning
verfasst von
Francisco M. Echavarren
Lukas Sigrist
Copyright-Jahr
2021
Buch
Transmission Expansion Planning: The Network Challenges of the Energy Transition

Print ISBN: 978-3-030-49427-8

Electronic ISBN: 978-3-030-49428-5

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-3-030-49428-5_9