Optimal Sizing and Control of a Grid-Connected Battery in a Stacked Revenue Model Including an Energy Community

TL;DR

This paper develops a methodology for optimal sizing and control of grid-connected batteries within energy communities, demonstrating economic benefits through a case study and addressing control limitations with new regularization techniques.

Contribution

It introduces a novel approach for sizing and pricing battery capacity in energy communities and improves battery control models with regularization functions for practical deployment.

Findings

Communities can save up to 12,874 euros annually with optimized battery rental.

The methodology is applicable across various tariffs and scenarios.

Enhanced control models address practical limitations of existing approaches.

Abstract

Recent years have seen rapid increases in intermittent renewable generation, requiring novel battery energy storage systems (BESS) solutions. One recent trend is the emergence of large grid-connected batteries, that can be controlled to provide multiple storage and flexibility services, using a stacked revenue model. Another emerging development is renewable energy communities (REC), in which prosumers invest in their own renewable generation capacity, but also requiring battery storage for flexibility. In this paper, we study settings in which energy communities rent battery capacity from a battery operator through a battery-as-a-service (BaaS) model. We present a methodology for determining the sizing and pricing of battery capacity that can be rented, such that it provides economic benefits to both the community and the battery operator that participates in the energy market. We examine how sizes and prices vary across a number of different scenarios for different types of tariffs (flat, dynamic) and competing energy market uses. Second, we conduct a systematic study of linear optimization models for battery control when deployed to provide flexibility to energy communities. We show that existing approaches for battery control with daily time windows have a number of important limitations in practical deployments, and we propose a number of regularization functions in the optimization to address them. Finally, we investigate the proposed method using real generation, demand, tariffs, and battery data, based on a practical case study from a large battery operator in the Netherlands. For the settings in our case study, we find that a community of 200 houses with a 330 kW wind turbine can save up to 12,874 euros per year by renting just 280 kWh of battery capacity (after subtracting battery rental costs), with the methodology applicable to a wide variety of settings and tariff types.