Abstract:

Large-scale battery energy storage systems (BESS) are helping transition the world towards sustainability with their broad use, among others, in electrified transportation, power grid, and renewables. However, optimal power management for them is often computationally formidable. To overcome this challenge, we develop a scalable approach in the paper. The proposed approach partitions the constituting cells of a large- scale BESS into clusters based on their state-of-charge (SoC), temperature, and internal resistance. Each cluster is characterized by a representative model that approximately captures its collective SoC and temperature dynamics, as well as its overall power losses in charging/discharging. Based on the clusters, we then formulate a problem of receding-horizon optimal power control to minimize the power losses while promoting SoC and temperature balancing. The cluster-based power optimization will decide the power quota for each cluster, and then every cluster will split the quota among the constituent cells. Since the number of clusters is much fewer than the number of cells, the proposed approach significantly reduces the computational costs, allowing optimal power management to scale up to large-scale BESS. Extensive simulations are performed to evaluate the proposed approach. The obtained results highlight a significant computational overhead reduction by more than 60% for a small-scale and 98% for a large-scale BESS compared to the conventional cell-level optimization. Experimental validation based on a 20- cell prototype further demonstrates its effectiveness and utility.