Resumen:
To address the reduction of system inertia, transmission system operators are now requesting converter-interfaced generators (CIGs) to participate in frequency support services. Microgrids (MGs) and virtual power plants have been used as a solution for aggregation of small CIGs. It has been recently considered they may use their combined actions to provide frequency services. However, these proposals are not general enough, focusing on specific CIGs controllers and, in many cases, stability and operational limits are not considered. This paper presents an standardised methodology to design MG controllers that are in compliance with the MG transient response specifications (frequency nadir and rate-of-change-of-frequency, ROCOF). The methodology has an iterative nature and can be applied when the network conditions change. In each iteration, the control parameters are adjusted based on the sensitivity of the system eigenvalues against the frequency metrics of interest while stability and operational constraints are respected. Compared to the literature, the use of quantitative parametric sensitivity is performed for the reallocation of several eigenvalues using two sensitivity components, not only one. Moreover, it is suitable for any combination of grid-forming and grid-following devices. The proposed methodology is applied to a benchmark MG and results show that both nadir and ROCOF can be effectively modified and set as required. The methodology was validated by using a real MG comprising four 15 kW converters and one 75 kW converter.
Palabras Clave: Microgrid; Inertia; Grid-forming; Nadir; ROCOF; Small-signal analysis
Índice de impacto JCR y cuartil WoS: 5,000 - Q1 (2023)
Referencia DOI: https://doi.org/10.1016/j.ijepes.2023.109539
Publicado en papel: Enero 2024.
Publicado on-line: Octubre 2023.
Cita:
D.P. Morán-Río, A. Anta, J. Roldán-Pérez, M. Prodanovic, A. García-Cerrada, Coordination of distributed resources for frequency support provision in microgrids. International Journal of Electrical Power & Energy Systems. Vol. 155, nº. Part B, pp. 109539-1 - 109539-11, Enero 2024. [Online: Octubre 2023]