Voltage stability boundary and margin enhancement with FACTS and HVDC

Impact of FACTS on voltage stability boundary of bus 30 of IEEE 30 bus system. [Display omitted] •Thevenin’s equivalent based approach to obtain voltage stability boundary with FACTS and HVDC.•Determination of location of shunt and series controller using voltage stability indices.•Enhancement in vo...

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Bibliographic Details
Published in:International journal of electrical power & energy systems 2016-11, Vol.82, p.429-438
Main Authors: Prabhakar, Priti, Kumar, Ashwani
Format: Article
Language:English
Subjects:
Boundaries
Bus impedance matrix
Buses (vehicles)
Devices
Electric potential
FACTS
FACTS and HVDC
Mathematical models
Matlab
Thevenin’s equivalent network
Voltage stability
Voltage stability boundary
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Summary:Impact of FACTS on voltage stability boundary of bus 30 of IEEE 30 bus system. [Display omitted] •Thevenin’s equivalent based approach to obtain voltage stability boundary with FACTS and HVDC.•Determination of location of shunt and series controller using voltage stability indices.•Enhancement in voltage stability margins with FACTS and HVDC and Comparison. Voltage stability is a major concern of today’s power system, especially under heavily loaded conditions because of reactive power limits. FACTs devices are very effective solution to prevent voltage instability and voltage collapse due to fast and very flexible control. In this paper, the impacts of SVC, STATCOM, TCSC and HVDC on voltage stability boundary (VSB) in P–Q plane have been studied. The bus impedance matrix and load flow results are used to find the voltage stability boundary. The Zbus is modified to take into account the effect of FACTS on VSB. The variable susceptance model for SVC and variable series impedance power flow model for TCSC are used in Newton Raphson’s method. The STATCOM is modelled as variable voltage source connected in series with an equivalent impedance of the shunt connected transformer. Similarly HVDC is also modelled as two STATCOMs connected at each end of the line one as rectifier and another as inverter. Some important bus and line stability indices are evaluated to determine the most effective location for SVC/STATCOM and TCSC/HVDC respectively in order to achieve the maximum enhancement of voltage stability margin. The study has been carried out on IEEE-14 bus and IEEE-30 bus test systems using MATLAB programming. A comprehensive study is done to compare the effectiveness of FACTS devices and HVDC on voltage stability margins.
ISSN:0142-0615
1879-3517
DOI:10.1016/j.ijepes.2016.03.038