Enhanced inertia response control of grid-forming PMSG-based wind turbines considering safe operation boundary

Zhenyan Deng; Student Member; IEEE; Han Wang; Member; IEEE; Yao Qin; Graduate Student 
Member; IEEE; Renxin Yang; Member; IEEE; and Xu Cai; Senior Member; IEEE

Citation:Zhenyan Deng,Student Member,IEEE,et al.Enhanced inertia response control of grid-forming PMSG-based wind turbines considering safe operation boundary[J].Protection and Control of Modern Power Systems,2025,V10(05):56-67[Copy]

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Enhanced inertia response control of grid-forming PMSG-based wind turbines considering safe operation boundary
Zhenyan Deng, Student Member, IEEE, Han Wang, Member, IEEE, Yao Qin, Graduate Student Member, IEEE, Renxin Yang, Member, IEEE, and Xu Cai, Senior Member, IEEE
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Abstract:

With the rapid development of renewable energy, power system inertia is gradually decreasing, threatening the stability of system frequency. Grid-forming (GF)-based wind turbines (WTs) equipped with active inertia response are key to addressing the problem of low-inertia power systems. However, existing researches have focused on the inertia response of GF-based WTs in the maximum power point tracking (MPPT) range, while lacking the discussion on the control and implementation of inertia response in other operating ranges. Therefore, this paper proposes an inertia response control method for permanent magnet synchronous generator (PMSG)-based WTs across the full wind speed range based on inertia synchronization control (IsynC). By analyzing the characteristics of the inertia response and safe operating boundaries of the WT at different operational stages, a control method for the smooth speed transition of the WT across different operating ranges is proposed. By utilizing a composite judgment logic based on the DC voltage rate of change and rotor speed, an adaptive inertia response for different operating modes is achieved. Single and multiple PMSG-WT simulation models are built in PSCAD/EMTDC to simulate the proposed full wind speed range inertia response control and its operational characteristics. The results demonstrate that this method enables the selective inertia response of WTs across the full wind speed range, effectively enhancing the frequency support capabilities of renewable energy generation systems.

Key words: Grid-forming, permanent magnet synchronous generator (PMSG), inertia response, full wind range, seamless switching.

DOI：10.23919/PCMP.2023.000153

Fund:This work is supported in part by the National Key R&D Program of China (No. 2022YFB2402703)