TY - JOUR
T1 - Enhancing Virtual Inertia Control in Microgrids
T2 - A Novel Frequency Response Model Based on Storage Systems
AU - Criollo Ríos, Adrián Rodrigo
AU - Minchala Ávila, Luis Ismael
AU - Benavides Padilla, Darío Javier
AU - Arévalo Cordero, Wilian Pául
AU - Tostado Véliz, Marcos
AU - Sánchez Lozano, Daniel
AU - Jurado Melguizo, Francisco
AU - Tostado Véliz, Marcos
N1 - Publisher Copyright:
© 2024 by the authors.
PY - 2024/1
Y1 - 2024/1
N2 - The integration of renewable resources in isolated systems can produce instability in the electrical grid due to its intermintency. In today’s microgrids, which lack synchronous generation, physical inertia is substituted for inertia emulation. To date, the most effective approach remains the frequency derivative control technique. Nevertheless, within this method, the ability to provide virtual drooping is often disregarded in its design, potentially leading to inadequate development in systems featuring high renewable penetration and low damping. To address this issue, this paper introduces an innovative design and analysis of virtual inertia control to simultaneously mimic droop and inertia characteristics in microgrids. The dynamic frequency response without and with renewable energy sources penetration is comparatively analyzed by simulation. The proposed virtual inertia control employs a derivative technique to measure the rate of change of frequency slope during inertia emulation. Sensitivity mapping is conducted to scrutinize its impact on dynamic frequency response. Finally, the physical battery storage system of the University of Cuenca microgrid is used as a case study under operating conditions.
AB - The integration of renewable resources in isolated systems can produce instability in the electrical grid due to its intermintency. In today’s microgrids, which lack synchronous generation, physical inertia is substituted for inertia emulation. To date, the most effective approach remains the frequency derivative control technique. Nevertheless, within this method, the ability to provide virtual drooping is often disregarded in its design, potentially leading to inadequate development in systems featuring high renewable penetration and low damping. To address this issue, this paper introduces an innovative design and analysis of virtual inertia control to simultaneously mimic droop and inertia characteristics in microgrids. The dynamic frequency response without and with renewable energy sources penetration is comparatively analyzed by simulation. The proposed virtual inertia control employs a derivative technique to measure the rate of change of frequency slope during inertia emulation. Sensitivity mapping is conducted to scrutinize its impact on dynamic frequency response. Finally, the physical battery storage system of the University of Cuenca microgrid is used as a case study under operating conditions.
KW - frequency response
KW - load frequency control
KW - secondary frequency control
KW - small-signal
KW - virtual dropping
KW - virtual inertia control
KW - Frequency response
KW - Load frequency control
KW - Secondary frequency control
KW - Small-signal
KW - Virtual dropping
KW - Virtual inertia control
UR - https://www.scopus.com/pages/publications/85183366821
UR - https://www.mdpi.com/2313-0105/10/1/18
U2 - 10.3390/batteries10010018
DO - 10.3390/batteries10010018
M3 - Artículo
AN - SCOPUS:85183366821
SN - 2313-0105
VL - 10
SP - 1
EP - 19
JO - Batteries
JF - Batteries
IS - 1
M1 - 18
ER -
