Energy storage and rechargeable batteries are key to unlocking the potential of renewable energy. As we touched on in our previous article, lithium-ion batteries are already helping the integration of renewable energy supplies to the grid. This is a rapidly evolving field and, as with all developing technologies, some trends and pitfalls are beginning to emerge. One risk is fires caused by thermal runaway; these are causing significant losses in the industry and a tragic loss of life in some cases.1 In this article, we will be exploring the issue of battery fires and discussing the mitigation strategies available.
Batteries have always been a big part of our lives, and now power our cars, laptops, and mobiles. These small-scale batteries (such as Ni-Cad and Li-ion batteries) are fairly robust and have limited power and duration. Battery Energy Storage Systems (BESS) are batteries deployed on a much larger scale, with enough power and capacity to provide meaningful storage of power for electric grids. A BESS can be a standalone system located near loads or transmission infrastructure, or integrated into renewable energy sources or other power generation facilities. BESS projects are also deployed as a power storage solution for remote areas that are not connected to the grid.
Whenever you store a large amount of energy — whether in traditional liquid/gas forms or in batteries — there is a risk that an uncontrolled release of the energy could result in a fire or explosion. In batteries, thermal runaway describes a chain reaction in which a damaged battery begins to release energy in the form of heat, leading to further damage and a feedback loop that results in rapid heating. Left unchecked, the heat generated can cause a fire. The only way to stop thermal runaway is rapid cooling of the affected cell(s); another approach is to simply separate the affected battery module and allow the reaction to reach its destructive conclusion in a safe location.
Note that even if the fire is suppressed, thermal runaway alone can generate enough heat to damage adjacent cells and spread the reaction. Therefore thermal management, fire suppression, and physical design layout to isolate batteries from each other are all essential elements to protect a BESS installation from a thermal runaway event in a single cell.
Some of the possible causes of fires include:
It is clear from the number and frequency of incidents that thermal runaway and battery fires are a serious risk that must be proactively managed by the owners, operators, and constructors of BESS systems. A holistic approach in BESS design is needed for each project. Batteries must be protected from day one of construction and there must be a zero tolerance approach to battery abuse. Battery management systems must be sophisticated, monitored, and responded to. Gas detection, explosion prevention, fire detection, and fire suppression as well as a robust emergency response plan are essential to mitigate the damage if a thermal runway event does occur.
There are a number of new and recently-revised standards relevant to the design and deployment of BESS systems, however the technology and industry continues to develop rapidly and is constantly innovating to improve project value and safety. While future-proofing an installation to ensure long-term insurability can be challenging in this environment, success can be found in a holistic approach that covers all aspects of the design.
To assess emergency response, underwriters look for evidence of detailed dialogue with emergency services and a written protocol for incidents (documented pre-fire plans). Ultimately, early engagement with your risk adviser is key to ensuring that your project is well protected, safe, reliable, and well positioned to benefit from a competitive insurance placement for the long-term life of the project.
Need expert advice? Get in touch with our renewable energy experts.
Sources:
1 The Guardian ‘Tesla big battery fire in Victoria burns into day three’, Aug 2021