Optimized Strategies for Peak Shaving and BESS Efficiency Enhancement through Cycle-Based Control and Cluster-Level Power Allocation

TL;DR

This paper introduces a cycle-based control strategy and cluster-level power allocation using an improved PSO algorithm to optimize BESS performance, reduce energy loss, and extend lifespan in peak shaving applications.

Contribution

It presents a novel cycle-based control method and an innovative cluster-level power allocation strategy that significantly improve BESS efficiency and operational accuracy.

Findings

Increased capacity utilization rate from 75.1% to 79.9%.

Reduced daily energy loss by 174.21 kWh (3.7%).

Enhanced BESS lifespan by reducing equivalent cycles.

Abstract

Battery Energy Storage Systems (BESS) are essential for peak shaving, balancing power supply and demand while enhancing grid efficiency. This study proposes a cycle-based control strategy for charging and discharging, which optimizes capture rate (CR), release rate (RR), and capacity utilization rate (CUR), improving BESS performance. Compared to traditional day-ahead methods, the cycle-based approach enhances operational accuracy and reduces capacity waste, achieving a CUR increase from 75.1% to 79.9%. An innovative cluster-level power allocation method, leveraging an improved Particle Swarm Optimization (PSO) algorithm, is introduced. This strategy reduces daily energy loss by 174.21 kWh (3.7%) and increases BESS efficiency by 0.4%. Transient and steady-state energy loss components are analyzed, revealing that transient loss proportion decreases significantly as power depth increases, from 27.2% at 1 MW to 1.3% at 10 MW. Simulations based on a detailed Simulink/Simscape model validate these methods, demonstrating enhanced peak shaving effectiveness and prolonged BESS lifespan by reducing equivalent cycles. The study provides a robust framework for optimizing BESS performance and efficiency in real-world applications.