TY - JOUR
T1 - AN ARTIFICIAL INTELLIGENCE APPROACH FOR THE IDENTIFICATION OF THE NORMATIVE BEHAVIOR OF DECENTRALIZED GENERATORS IN AN ISOLATED NETWORK
AU - Bernecker-Castro, Claudia
AU - Faltz, Simon
AU - Timmermann, Johanna
AU - Lechner, Tobias
AU - Seifried, Sebastian
AU - Schaarschmidt, Kathrin
AU - Herrmann, Steffen
AU - Finkel, Michael
AU - Witzmann, Rolf
N1 - Publisher Copyright:
© Energynautics GmbH.
PY - 2024
Y1 - 2024
N2 - A sustainable, intentional, isolated grid operation could be achieved by allowing the in-feed from the available decentralized generators (DGs), like rooftop PV systems, together with the conventional ones. A concept for the emergency islanded operation was proposed based on the normative power reduction governed for higher frequencies. However, the exact amount of power reduction from the DG side is unknown since its normative requirements, intended for parallel connection, have changed within the past years in Germany, strongly differing on the frequency characteristic. One method estimates the aggregated power versus frequency behavior based on the commissioning date, as it corresponds to a valid grid code. Still, some discrepancies are observed when compared to field measurement data. This work proposes a neural network algorithm to identify the penetration level of each frequency characteristic inside the islanded grid and predict its power profile in the over-frequency region. Results show a promising capability to predict profiles closer to the recorded measurement data.
AB - A sustainable, intentional, isolated grid operation could be achieved by allowing the in-feed from the available decentralized generators (DGs), like rooftop PV systems, together with the conventional ones. A concept for the emergency islanded operation was proposed based on the normative power reduction governed for higher frequencies. However, the exact amount of power reduction from the DG side is unknown since its normative requirements, intended for parallel connection, have changed within the past years in Germany, strongly differing on the frequency characteristic. One method estimates the aggregated power versus frequency behavior based on the commissioning date, as it corresponds to a valid grid code. Still, some discrepancies are observed when compared to field measurement data. This work proposes a neural network algorithm to identify the penetration level of each frequency characteristic inside the islanded grid and predict its power profile in the over-frequency region. Results show a promising capability to predict profiles closer to the recorded measurement data.
KW - decentralized generators
KW - deep neural networks (DNN)
KW - frequency behaviour
KW - islanded forming units
KW - islanded grids
UR - http://www.scopus.com/inward/record.url?scp=85204034185&partnerID=8YFLogxK
U2 - 10.1049/icp.2024.1828
DO - 10.1049/icp.2024.1828
M3 - Conference article
AN - SCOPUS:85204034185
SN - 2732-4494
VL - 2024
SP - 129
EP - 135
JO - IET Conference Proceedings
JF - IET Conference Proceedings
IS - 2
T2 - 8th International Hybrid Power Plants and Systems Workshop, HYB 2024
Y2 - 14 May 2024 through 15 May 2024
ER -