Distribution Network Marginal Costs - Part I: A Novel AC OPF Including Transformer Degradation

This two-part paper considers the day-ahead operational planning problem of a radial distribution network hosting Distributed Energy Resources (DERs) including Solar Photovoltaic (PV) and storage-like loads such as Electric Vehicles (EVs). We estimate dynamic Distribution nodal Location Marginal Costs (DLMCs) of real and reactive power and employ them to co-optimize distribution network and DER schedules. In Part I, we develop a novel AC Optimal Power Flow (OPF) model encompassing transformer degradation as a short-run network variable cost, and we decompose real/reactive power DLMCs into additive marginal cost components related to (i) the costs of real/reactive power transactions at the T&D interface/substation, (ii) real/reactive power marginal losses, (iii) voltage and (iv) ampacity congestion, and (v) a new transformer degradation marginal cost component. Our detailed transformer degradation model captures the impact of incremental transformer loading during a specific time period, not only on its Loss of Life (LoL) during that period, but also during subsequent time periods. To deal with this phenomenon, we develop methods that internalize the marginal LoL occurring beyond the daily horizon into the DLMCs evaluated within this horizon. In Part II, we use real distribution feeders to exemplify the use of DLMCs as financial incentives that convey sufficient information to optimize Distribution Network, and DER (PV and EV) operation.