Second-order Cone Optimization Modeling and Simulation for Three-phase Unbalanced Active Distribution Networks

Authors

Yiran Zhao, State Grid Henan Electric Power Company Xixia County Power Supply Company, Nanyang 474500, China
Yong Xue, State Grid Henan Electric Power Company Xixia County Power Supply Company, Nanyang 474500, China
Haoxin Tian, State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources (North China Electric Power University), Beijing 102206, China
Ruixin Zhang, State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources (North China Electric Power University), Beijing 102206, China
Zhi Zhang, State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources (North China Electric Power University), Beijing 102206, China
Yanbo Chen, State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources (North China Electric Power University), Beijing 102206, China

Abstract

Abstract: Guided by the carbon peaking and carbon neutrality goals, and propelled by the development of new type power systems, the significance of distribution networks as key energy infrastructure has been increasingly underscored. Amidst the burgeoning rise of distributed photovoltaics, electric vehicles, and novel energy storage technologies, distribution networks are transitioning from passive entities to active systems capable of bidirectional interaction, heralding the advent of active distribution networks with a critical mission. This research tackles the optimal power flow issue in three-phase unbalanced active distribution networks, incorporating inter-phase coupling relationships. By employing dimensionality lifting and rank relaxation, along with the Sylvester criterion, second-order cone constraints are established among voltages, currents, and powers. The branch flow model is expanded from a single time period to multiple periods. In line with the principles of the symmetrical component method and national standards, constraints on three-phase voltage unbalance are formulated. The study integrates active management and demand response strategies, targeting the minimization of active energy losses in distribution networks. A dynamic optimal power flow model for three-phase unbalanced active distribution networks is developed based on mixed-integer second-order cone programming, facilitating coordinated optimization of active and reactive power dispatch. The case study analysis demonstrates that the proposed method can effectively reduce the system's operational network losses, significantly improve the degree of three-phase voltage unbalance, and comply with the national standard's upper limit of 2%, thus providing valuable insights for precise modeling and simulation of three-phase unbalanced distribution networks.

Recommended Citation

Zhao, Yiran; Xue, Yong; Tian, Haoxin; Zhang, Ruixin; Zhang, Zhi; and Chen, Yanbo (2025) "Second-order Cone Optimization Modeling and Simulation for Three-phase Unbalanced Active Distribution Networks," Journal of System Simulation: Vol. 37: Iss. 9, Article 7.
DOI: 10.16182/j.issn1004731x.joss.24-0463
Available at: https://dc-china-simulation.researchcommons.org/journal/vol37/iss9/7

First Page

2258

Last Page

2268

CLC

TP391.9; TM732

Recommended Citation

Zhao Yiran, Xue Yong, Tian Haoxin, et al. Second-order Cone Optimization Modeling and Simulation for Three-phase Unbalanced Active Distribution Networks[J]. Journal of System Simulation, 2025, 37(9): 2258-2268.

Corresponding Author

Tian Haoxin

DOI

10.16182/j.issn1004731x.joss.24-0463