TY - JOUR
T1 - Aggregate data-driven dynamic modeling of active distribution networks with DERs for voltage stability studies
AU - Subedi, Sunil
AU - Vasquez-Plaza, Jesus D.
AU - Andrade, Fabio
AU - Rekabdarkolaee, Hossein Moradi
AU - Fourney, Robert
AU - Tonkoski, Reinaldo
AU - Hansen, Timothy M.
N1 - Publisher Copyright:
© 2024 The Author(s). IET Renewable Power Generation published by John Wiley & Sons Ltd on behalf of The Institution of Engineering and Technology.
PY - 2024/10/26
Y1 - 2024/10/26
N2 - Electric distribution networks increasingly host distributed energy resources based on power electronic converter (PEC) toward active distribution networks (ADN). Despite advances in computational capabilities, electromagnetic transient models are limited in scalability because of their reliance on exact data about the distribution system and each of its components. Similarly, the use of the DER_A model, which is intended to examine the combined dynamic behavior of many DERs, is limited by the difficulty in parameterization. There is a need for improved dynamic models of DERs for use in large power system simulations for stability analysis. This paper proposes an aggregate model-free, data-driven approach for deriving a dynamic partitioned model (DPM) of ADNs. Detailed residential distribution feeders were first developed, including PEC-based DERs and composite load models (CMLDs), from which the aggregated DPM was derived. The performance was evaluated through various case studies and validated against the detailed ADN model and state-of-the-art DER_A model with CMLD. The data-driven DPM achieved a (Formula presented.) of over 90%, accurately representing the aggregated dynamic behavior of ADNs. Furthermore, the DPM significantly accelerated the simulation process with a computational speedup of 68 times compared to the detailed ADN and a 3.5 times speedup compared to the DER_A CMLD model.
AB - Electric distribution networks increasingly host distributed energy resources based on power electronic converter (PEC) toward active distribution networks (ADN). Despite advances in computational capabilities, electromagnetic transient models are limited in scalability because of their reliance on exact data about the distribution system and each of its components. Similarly, the use of the DER_A model, which is intended to examine the combined dynamic behavior of many DERs, is limited by the difficulty in parameterization. There is a need for improved dynamic models of DERs for use in large power system simulations for stability analysis. This paper proposes an aggregate model-free, data-driven approach for deriving a dynamic partitioned model (DPM) of ADNs. Detailed residential distribution feeders were first developed, including PEC-based DERs and composite load models (CMLDs), from which the aggregated DPM was derived. The performance was evaluated through various case studies and validated against the detailed ADN model and state-of-the-art DER_A model with CMLD. The data-driven DPM achieved a (Formula presented.) of over 90%, accurately representing the aggregated dynamic behavior of ADNs. Furthermore, the DPM significantly accelerated the simulation process with a computational speedup of 68 times compared to the detailed ADN and a 3.5 times speedup compared to the DER_A CMLD model.
KW - DC-AC power convertors
KW - distribution networks
KW - power electronics
KW - power system dynamic stability
UR - http://www.scopus.com/inward/record.url?scp=85199985794&partnerID=8YFLogxK
U2 - 10.1049/rpg2.13063
DO - 10.1049/rpg2.13063
M3 - Article
AN - SCOPUS:85199985794
SN - 1752-1416
VL - 18
SP - 2261
EP - 2276
JO - IET Renewable Power Generation
JF - IET Renewable Power Generation
IS - 14
ER -
