Load Balancing in Low-Voltage Distribution Networks via Optimizing Residential Phase Connections

TL;DR

This paper presents an optimized method for balancing low-voltage distribution networks by dynamically controlling residential phase connections using phase-switching devices, improving network stability and resource management.

Contribution

It introduces an iteration-based algorithm to solve a complex MINCP problem for phase connection optimization, surpassing previous heuristic and linearization approaches.

Findings

Effective unbalance mitigation in real networks

Enhanced network security and flexibility

Superior performance over existing methods

Abstract

Unbalance issues in low-voltage distribution networks (LVDN) can be worsened by increasing penetration of residential PV generation if unevenly distributed among three phases. To address this issue, the phase-switching device (PSD) provides a viable and efficient method by dynamically switching customers to other phases. This paper further investigates how to optimize residential phase connections by controlling PSDs efficiently. The optimization problem is formulated as a mixed-integer non-convex programming (MINCP) problem considering relevant operational requirements of an LVDN based on the exact formulation of unbalanced three-phase optimal power flow (UTOPF). Unlike most heuristic algorithms and the linearization techniques in our previous work, this paper proposes to solve the MINCP problem via an iteration-based algorithm after exact reformulations and reasonable approximations of some constraints. The proposed method is tested in a real LVDN and compared with the approach of Zhao et al. based on the well-known linear UTOPF formulation. Case studies based on the European low-voltage test feeder demonstrate the proposed method's efficiency in mitigating the network unbalance while ensuring network security and flexibility to deal with more controllable resources.