TY - GEN
T1 - Coordinated Flexible PV Operation and Fuel Cell Efficiency Tracking for Stable Microgrids with Grid-Forming Battery
AU - Abdalla, Ammar Atif
AU - El Moursi, Mohamed Shawky
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Microgrids with grid-forming Battery Energy Storage Systems (BESS) face voltage and frequency stability challenges due to fluctuating loads and intermittent sources, such as photovoltaic power plants (PVPP). Especially when the BESS's state of charge (SOC) reaches its minimum limit (SOCmin), causing under-frequency and battery depletion, leading to either load shedding or BESS damage. Conversely, over-frequency and overcharging occur when SOC reaches its maximum limit (SOCmax) due to excess PV generation, often mitigated by curtailing PV output through direct load following control, resulting in instability under rapid weather changes. This paper proposes two innovative strategies. First, to avoid load shedding at SOCmin, we propose the integration of a fuel cell (FC) equipped with a flexible efficiency tracking controller based on a polynomial fitting technique, providing efficient power support without sacrificing fuel cell efficiency. Second, when SOC reaches SOCmax, we investigate coordinated flexible operation among multiple PVPPs with different irradiance conditions to manage excess generation without inducing stability issues. The proposed controller was rigorously tested across various scenarios.
AB - Microgrids with grid-forming Battery Energy Storage Systems (BESS) face voltage and frequency stability challenges due to fluctuating loads and intermittent sources, such as photovoltaic power plants (PVPP). Especially when the BESS's state of charge (SOC) reaches its minimum limit (SOCmin), causing under-frequency and battery depletion, leading to either load shedding or BESS damage. Conversely, over-frequency and overcharging occur when SOC reaches its maximum limit (SOCmax) due to excess PV generation, often mitigated by curtailing PV output through direct load following control, resulting in instability under rapid weather changes. This paper proposes two innovative strategies. First, to avoid load shedding at SOCmin, we propose the integration of a fuel cell (FC) equipped with a flexible efficiency tracking controller based on a polynomial fitting technique, providing efficient power support without sacrificing fuel cell efficiency. Second, when SOC reaches SOCmax, we investigate coordinated flexible operation among multiple PVPPs with different irradiance conditions to manage excess generation without inducing stability issues. The proposed controller was rigorously tested across various scenarios.
KW - Battery energy storage system
KW - fuel cell
KW - grid forming control
KW - power system flexibility
KW - PV power plants
UR - https://www.scopus.com/pages/publications/105007885750
U2 - 10.1109/SPIES63782.2024.10982914
DO - 10.1109/SPIES63782.2024.10982914
M3 - Conference contribution
AN - SCOPUS:105007885750
T3 - 2024 6th International Conference on Smart Power and Internet Energy Systems, SPIES 2024
SP - 433
EP - 438
BT - 2024 6th International Conference on Smart Power and Internet Energy Systems, SPIES 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 6th International Conference on Smart Power and Internet Energy Systems, SPIES 2024
Y2 - 4 December 2024 through 6 December 2024
ER -
