© The Institution of Engineering and Technology
To better assess the contribution of wind power plants (WPPs) during disturbances, Hydro-Québec TransÉnergie (HQT), the main transmission system operator in the Quebec Interconnection, uses on-line monitoring to record data at the point of common coupling of each WPP. This data is used to analyse their performance during voltage and frequency disturbances. Until recently, very few WPPs were able to provide an inertial response (IR) for under-frequency events. On 28 December 2015, a generation loss of 1700 MW caused a frequency nadir of 59.08 Hz on the system, to which most WPPs required to provide IR contributed significantly. The analysis of the event showed that the behaviour of the WPPs had a significant effect on the recovery of the system frequency. This study presents the performance analysis of WPPs during this under-frequency event. The analysis is based on data collected from 25 large-scale WPPs in operation and equipped with the IR feature as required by HQT. Field measurements and simulation results are used to emphasise the effect of the active power reduction during the recovery phase. Impacts of the IR from the WPPs as used on the Hydro-Quebec system are discussed.
References
-
-
1)
-
2)
-
4. Aubut, N., Brisebois, J.: ‘Wind farm inertia emulation to fulfil Hydro-Québec's specific need’. IEEE PES GM, Detroit, 2011.
-
3)
-
10. Asmine, M., Langlois, C.-E.: ‘Field measurements for the assessment of inertial response for wind power plants based on hydro-Québec TransÉnergie requirements’, IET Renew. Power Gener., 2016, 10, (1), p. pp. 25–32.
-
4)
-
12. Engelken, S., Mendonca, A., Fischer, M.: ‘Inertial response with improved variable recovery behaviour provided by type 4 wind turbines’. Proc. 14th Int. Workshop on Large-Scale Integration of Wind Power into Power Systems as well as on Transmission Networks for Offshore Wind Power Plants, 2015, Brussels, October 2015.
-
5)
-
6)
-
2. Wachtel, S., Beekmann, A.: ‘Contribution of wind energy converters with inertia emulation to frequency control and frequency stability in power systems’. 8th Int. Workshop on Large-Scale Integration of Wind Power and on Transmission Networks for Offshore Wind Farms, 2009.
-
7)
-
8. Wang, Y., Delille, G., Bayem, H., et al: ‘High wind power penetration in isolated power systems – assessment of wind inertial and primary frequency responses’, IEEE Trans. Power Syst., 2013, 28, (3), pp. 2412–2420.
-
8)
-
6. Fischer, M., Engelken, S., Mihov, N., et al: ‘Operational experiences with inertial response provided by type 4 wind turbines’, IET Renew. Power Gener., 2016, 10, (1), pp. 17–24, .
-
9)
-
3. Dernbach, M., Bagusche, D., Schrader, S.: ‘Frequency control in Québec with DFIG wind turbines’. 9th Int. Workshop on Large-Scale Integration of Wind Power and on Transmission Networks for Offshore Wind Farms, 2010.
-
10)
-
11)
-
9. Asmine, M., Langlois, C.-E.: ‘Wind power plants grid code compliance tests – hydro-Québec TransÉnergie experience’, IET Renew. Power Gener., 2017, 11, (3), pp. 202–209.
-
12)
-
7. El Itani, S., Dernbach, M., Kosbab, M.: ‘Supplementary grid functions in DFIG wind turbines to meet Québec's frequency requirements’. CIGRÉ Canada, Conf. Power Systems, Montréal, September 2012.
http://iet.metastore.ingenta.com/content/journals/10.1049/iet-rpg.2017.0392
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content/journals/10.1049/iet-rpg.2017.0392
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