Quantifying Phase Unbalance and Coordination Impacts on Distribution Network Flexibility

The increasing integration of distributed energy resources (DER) provides distribution system operators (DSO) with new flexible resources to support more efficient operation and planning of distribution networks. To utilise these resources, various DER flexibility aggregation methods have been proposed in the literature, such as aggregated P-Q flexibility areas at the interface with other networks. However, whereas focusing on estimating the limits of flexibility services, existing studies make the critical assumption that all available flexible units are perfectly coordinated to jointly provide flexibility and manage network constraints. Moreover, due to the extensive use of single-phase power flow analysis, the impacts of phase unbalance on DER flexibility aggregation remain largely unexplored. To address these gaps in knowledge, this work proposes a framework for modelling flexibility services in low voltage (LV) distribution networks which enables explicitly imposing voltage unbalance and phase coordination constraints. The simulations, performed for an illustrative 5-bus system and a real 221-bus LV network in the UK, demonstrate that a significant share (over 30%) of total aggregated DER flexibility potential may be unavailable due to voltage unbalances and lack of coordination between DER connected to different phases.