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access icon free Response of a grid forming wind farm to system events, and the impact of external and internal damping

© The Institution of Engineering and Technology
Received 25/05/2020, Accepted 20/10/2020, Revised 31/08/2020, Published 16/02/2021

Following from smaller-scale investigations of grid-forming converter control applied to wind turbines in 2017–2018, this study describes a much larger trial involving an entire wind farm, owned and operated by ScottishPower Renewables. To the authors’ knowledge, this was the first UK converter-connected wind farm to operate in grid-forming mode, and the largest in the world to date. The 23-turbine, 69 MW farm ran in the grid-forming mode for 6 weeks, exploring inertia contributions between H = 0.2 s and H = 8 s. A number of unscheduled frequency disturbances occurred due to interconnector, combined cycle gas turbine (CCGT) and other trips, to which un-curtailed turbines were able to respond. In addition, several deliberate tests were carried out. The turbines were able to provide a stable and appropriate response at relatively high inertia levels to the frequency events commonly occurring today. The captured responses stimulated a debate as to whether external damping power might be required in a grid-forming converter, or whether internal damping is sufficient to allow stable and robust power-sharing with parallel devices in all grid event scenarios. Analysis in this study suggests that, practically, internal damping is probably appropriate, and that any deficiency in external damping power can be more than mitigated by reactance and/or droop-slope response-time management in the grid-forming converters.

Inspec keywords: power generation economics; damping; power grids; wind power plants; power convertors; wind turbines; power generation control; power system interconnection

Other keywords: grid forming wind farm; uncurtailed turbines; grid-forming mode; ScottishPower Renewables; grid-forming converter; unscheduled frequency disturbances; time 0.2 s to 8 s; wind turbines; power 69.0 MW; CCGT interconnector; grid-forming converter control; robust power-sharing; external damping power; time 6.0 week; grid event scenarios; internal damping; smaller-scale investigations; droop-slope response-time management; high inertia levels; UK converter-connected wind farm

Subjects: Wind power plants; Control of electric power systems; Power system management, operation and economics; Power electronics, supply and supervisory circuits; Power system control; Power convertors and power supplies to apparatus

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