Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power
Conventional VAR compensation devices such as capacitor banks and synchronous condensers, after long periods of service, have become aged and less effective to satisfy stringent requirement of short-term voltage stability in high-level wind power penetrated power systems. STATCOMs with a rapid and d...
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sg-ntu-dr.10356-1398072020-05-21T09:03:05Z Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power Liu, Junwei Xu, Yan Dong, Zhao Yang Wong, Kit Po School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Dynamic Load Dynamic VAR Compensation Conventional VAR compensation devices such as capacitor banks and synchronous condensers, after long periods of service, have become aged and less effective to satisfy stringent requirement of short-term voltage stability in high-level wind power penetrated power systems. STATCOMs with a rapid and dynamic reactive power support capability can be an ideal alternative, when combined with a proper equipment retirement and upgrades scheme. This paper proposes a systematic approach for optimal dynamic VAR resource planning and upgrading for a power system with increased wind power penetration and equipment retirement. The problem is constituted by two parts that are aged equipment retirement and new equipment placement. A multiobjective optimization model is proposed to minimize three objectives: the cost of retirement and upgrades, the index of proximity to steady-state voltage collapse, and the index of transient voltage unaccepted performance. To simulate real-world operating situation, multiple contingencies and uncertain dynamic load models are taken into account. Furthermore, low- and high-voltage ride through abilities for wind farms are modeled. The proposed model is tested on the New England 39-bus test system. 2020-05-21T09:03:05Z 2020-05-21T09:03:05Z 2017 Journal Article Liu, J., Xu, Y., Dong, Z. Y., & Wong, K. P. (2018). Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power. IEEE Transactions on Power Systems, 33(2), 2282-2291. doi:10.1109/TPWRS.2017.2732441 0885-8950 https://hdl.handle.net/10356/139807 10.1109/TPWRS.2017.2732441 2-s2.0-85029858687 2 33 2282 2291 en IEEE Transactions on Power Systems © 2017 IEEE. All rights reserved. |
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Engineering::Electrical and electronic engineering Dynamic Load Dynamic VAR Compensation Liu, Junwei Xu, Yan Dong, Zhao Yang Wong, Kit Po Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| description |
Conventional VAR compensation devices such as capacitor banks and synchronous condensers, after long periods of service, have become aged and less effective to satisfy stringent requirement of short-term voltage stability in high-level wind power penetrated power systems. STATCOMs with a rapid and dynamic reactive power support capability can be an ideal alternative, when combined with a proper equipment retirement and upgrades scheme. This paper proposes a systematic approach for optimal dynamic VAR resource planning and upgrading for a power system with increased wind power penetration and equipment retirement. The problem is constituted by two parts that are aged equipment retirement and new equipment placement. A multiobjective optimization model is proposed to minimize three objectives: the cost of retirement and upgrades, the index of proximity to steady-state voltage collapse, and the index of transient voltage unaccepted performance. To simulate real-world operating situation, multiple contingencies and uncertain dynamic load models are taken into account. Furthermore, low- and high-voltage ride through abilities for wind farms are modeled. The proposed model is tested on the New England 39-bus test system. |
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School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Liu, Junwei Xu, Yan Dong, Zhao Yang Wong, Kit Po |
| format |
Article |
| author |
Liu, Junwei Xu, Yan Dong, Zhao Yang Wong, Kit Po |
| author_sort |
Liu, Junwei |
| title |
Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| title_short |
Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| title_full |
Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| title_fullStr |
Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| title_full_unstemmed |
Retirement-driven dynamic VAR planning for voltage stability enhancement of power systems with high-level wind power |
| title_sort |
retirement-driven dynamic var planning for voltage stability enhancement of power systems with high-level wind power |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/139807 |
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1681058491679113216 |