Integrated Battery and Energy Management System for Second-Life Battery energy storage

Optimal control and safe operation, lifetime prediction and management are amongst the most important open questions in the field of battery energy storage systems and of particular importance for second-life battery storage systems. Customers currently lack confidence about the quality and remaining lifetime of second-life battery systems. In first-life BESS, cell parameters and expected lifetime are determined through expensive and often destructive lab tests executed on a subset of the battery cells. The test results are representative since all cells are new and behave in a similar way. This is not the case for second-life BESS, where each cell may have a different history and therefore a different remaining lifetime and cell parameters. A battery controlled without detailed knowledge of the state of the battery cells will not deliver its optimal value as both the operational limits and lifetime warranty need to be set in a conservative way, underusing its full commercial potential.

This project improves the way battery energy storage systems (BESS) are operated by bringing together the BMS, which traditionally performs battery pack state estimation, and the EMS, which controls the (dis)charging of the BESS, into iBEMS, an integrated battery & energy management system.
The iBEMS has access to all raw battery cell measurements normally only accessible by the BMS. The energy management and optimisation function of the iBEMS is performed leveraging the plethora of useful data from the battery cells. Traditionally, an EMS only sees the state of charge of the battery pack and this data would have been lost. The data is available in Octave’s battery cloud, which opens multiple improvements in operating the BESS, such as delivering an optimized service, building a digital twin of the cells, applying machine learning, extending the lifetime, improving monitoring and enabling predictive maintenance, all which are of particular importance for second-life battery systems.

The project advanced second-life Battery Energy Storage Systems (BESS) from prototypes to TRL8 demonstrators. A modular 19” rack design with a patented module holder and integrated Battery Protection Unit was developed, enabling safe and flexible integration of diverse EV modules. An economical procedure for testing and selecting used batteries was defined and validated, ensuring reliable second-life qualification. The Integrated Battery & Energy Management System (iBEMS) was implemented, combining edge control with cloud intelligence, scalable IoT data architecture, and user-friendly dashboards for operators and clients.

Multiple pilot systems were installed and tested, culminating in a large-scale 1.75 MWh / 1.47 MW demonstrator at the Ipalle site, certified for regulatory compliance. The systems successfully demonstrated a range of energy management applications — from local site optimization to participation in energy markets and ancillary services.

The project reached TRL8, proving technical maturity, operational robustness, and readiness for commercial deployment.

The project proved the techno-economic feasibility of second-life battery energy storage and delivered several advances beyond the state of the art. A modular 19” rack and patented module holder were developed, providing a standardised and scalable architecture that allows the safe integration of heterogeneous EV modules up to 1000V DC. The Integrated Battery & Energy Management System (iBEMS) was created, combining edge and cloud intelligence to optimise performance, safety, and lifetime beyond the capabilities of conventional BMS/EMS solutions. A scalable IoT and analytics platform was deployed, with a secure cloud pipeline processing over one million datapoints per day per system at 93% compression, enabling predictive maintenance and fleet-wide optimisation. Finally, a TRL8 demonstrator of 1.75 MWh / 1.47 MW was installed at the Ipalle site and connected to the transmission grid, proving technical maturity and robustness by delivering certified grid services.

These results extend the lifetime of EV batteries, reduce waste, and contribute to the circular economy. They also lower the cost of energy storage, increasing accessibility for SMEs and municipalities. The systems enable advanced energy management applications ranging from local optimisation to energy market arbitrage and ancillary services, while strengthening Europe’s leadership in sustainable energy storage technologies.

To achieve full impact, further steps are required. These include building an ecosystem for cost-effective large-scale manufacturing in Europe that can compete with Asian cost structures, securing access to finance and investment to scale production and deployment, and pursuing internationalisation to expand adoption beyond Belgium and the EU.