Wind power virtual synchronous generator active frequency regulation performance engineering verification and optimization

被引：0

作者：

Song P. ^{[1
,2
]}

Cui Y. ^{[1
,2
]}

Ge J. ^{[3
]}

Wang X. ^{[1
,2
]}

Xu P. ^{[3
]}

Zhu S. ^{[4
]}

机构：

[1] State Grid Jibei Electric Power Co., Ltd., Research Institute, North China Electric Power Research Institute Co., Ltd., Beijing

[2] Grid-Connected Operation Technology for Wind-Solar-Storage Hybrid System State Grid Corporation Key Laboratory, Beijing

[3] State Grid Jibei Electric Power Co., Ltd., Beijing

[4] Zhangjiakou Wind, Photovoltaic and Energy Storage Demonstration Station Co., Ltd., Zhangjiakou

来源：

Cui, Yang (cy01583@163.com) | 1600年 / Science Press卷 / 42期

关键词：

Active frequency regulation; Control performance optimization; Demonstration project; Reserve capacity; Rotor inertia control; Wind power virtual synchronous generator;

D O I：

10.19912/j.0254-0096.tynxb.2018-0837

中图分类号：

学科分类号：

摘要：

Compared with conventional synchronous generators, wind turbines (WT) active power response and grid frequency are decoupled. WT do not have the ability of active frequency response. New challenges of gird frequency stability occur with high percentage of new energy access. Through virtual synchronous generator (VSG) technology transformation of WT, active frequency regulation ability is possessed. Field tests of reserve capacity and rotor inertia frequency regulation control method are conducted. The results show that WPVSG have ability of active power support. Active power jump when exiting frequency regulation and improper control coordination of electromagnetic torque and pitch angle engineering problems are closed loop optimized. © 2021, Solar Energy Periodical Office Co., Ltd. All right reserved.

引用

页码：264 / 271

页数：7

共 18 条

[1] PEI Z Y, WANG C X, HE Q, Et al., Analysis and suggestions on renewable energy integration problems in China, Electric power, 49, 11, pp. 1-7, (2016)
[2] WEI L J, WANG D L, LI Y, Et al., Variable coefficient based coordinated frequency modulation strategy between DFIG-based wind turbine and synchronous generator, Automation of electric power systems, 41, 2, pp. 94-100, (2017)
[3] LI Z W, WU X L, ZHUANG K Q, Et al., Analysis and reflection on frequency characteristics of East China Grid after bipolar locking of "9•19" Jinping-Sunan DC transmission line, Automation of electric power systems, 41, 7, pp. 149-155, (2017)
[4] LIU J, YAO W, WEN J Y, Et al., Prospect of technology for large-scale wind farm participating into power grid frequency regulation, Power system technology, 38, 3, pp. 638-646, (2014)
[5] GHOSH S, KAMALASADAN S, SENROY N, Et al., Doubly fed induction generator (DFIG)-based wind farm control framework for primary frequency and inertial response application, IEEE transactions on power systems, 31, 3, pp. 1861-1871, (2016)
[6] TANG X S, MIAO F F, QI Z P, Et al., Survey on frequency control of wind power, Proceedings of the CSEE, 34, 3, pp. 4304-4314, (2014)
[7] KANG M, KIM K, MULJADI E, Et al., Frequency control support of a doubly-fed induction generator base d on the torque limit, IEEE transactions on power systems, 31, 6, pp. 4575-4583, (2016)
[8] FAN G N, LIU J Z, MENG H M, Et al., Primary frequency control strategy for wind farms under output-restricted condition, Power system technology, 40, 7, pp. 2030-2037, (2016)
[9] VIDYANANDAN K V, SENROY N., Primary frequency regulation by deloaded wind turbines using variable droop, IEEE transactions on power systems, 28, 2, pp. 837-846, (2013)
[10] LIU B B, YANG J W, LIAO K, Et al., Improved frequency control strategy for DFIG-based wind turbines based on rotor inertia control, Automation of electric power systems, 40, 16, pp. 17-22, (2016)

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