When people think of the battery industry, associations likely go towards electric vehicles, but the battery industry isn’t just propelled by EVs. Utility-scale battery energy storage (BESS) has also entered the race and is more important than ever before. So, this article will explore how battery energy storage systems work.
Understanding how battery energy storage systems work is essential for those who want to know the knots and bolts of the industry. Battery Energy Storage Systems (BESS) are in simple terms big batteries that store energy for later use, ensuring a reliable supply of energy when the primary energy source is unavailable. These systems are crucial for utilities, businesses, and homes, providing a buffer against energy supply fluctuations caused by weather, blackouts, or geopolitical issues.
Battery energy storage systems have quickly gone from being overlooked to becoming a fundamental component of modern energy strategies, particularly those leveraging renewable energy sources like solar power and wind.
Solar and wind energy, while abundant, isn’t producing energy all the time. By integrating battery energy storage systems with photovoltaic (PV) solutions or wind turbines, solar and wind energy is stored for later use. This integration ensures a continuous and steady power supply, mitigating the intermittent nature of solar energy and enhancing overall energy reliability.
The operating principle of a battery energy storage system (BESS) is simple. Batteries get electricity from the power grid, directly from a power station, or from renewable energy sources like solar panels or wind turbines. They store this electricity as current, which releases when DSOs need the extra power.
That’s the very simple version, but there’s more to BESS.
When combined with advanced software, a BESS transform into a sophisticated platform that merges the storage capacity of batteries with intelligent energy management. By harnessing AI, machine learning, and data-driven solutions, these systems can optimize energy consumption, adapting to fluctuations in demand and supply. This intelligent management makes BESS a powerful asset in combating climate change by enabling more efficient and flexible energy use.
Battery energy storage systems support the increased deployment of renewable energy sources, helping to reduce carbon emissions and lower energy costs for businesses and households.
Battery storage can be used in various ways that go beyond simple emergency backups during energy shortages or blackouts. Applications differ depending on whether the storage is utilized by businesses or homes.
Let’s check them out.
For commercial and industrial use, BESS applications include:
For residential users, BESS offers several benefits:
The advantages of using battery storage technologies are numerous. They enhance the reliability and viability of renewable energy sources. Solar and wind power supplies can fluctuate, so battery storage systems are essential for “smoothing out” this flow to provide a continuous power supply, regardless of whether the wind is blowing or the sun is shining. Additionally, they protect users from grid fluctuations that could compromise energy supply. Here are some key advantages of battery storage:
Battery energy storage systems come in two primary varieties: “Behind-the-Meter” (BTM) systems, also known as “small-scale battery storage,” and “Front-of-the-Meter” (FTM) systems, which belongs on the utility side of energy distribution.
Behind-the-meter systems (BTM):
These systems are installed on the user’s premises and are typically smaller than Front-of-the-Meter systems. BTM systems, such as residential PV plants and battery storage units, reduces stress on the public grid when solar power isn’t produced, for instance, when the sun isn’t shining. The main function of a BTM is to improve the stability of the owner’s energy supply and reduce costs. If local regulations permit, these batteries can also feed energy back into the grid, providing an additional revenue stream.
Front-of-the-meter systems (FTM):
FTM systems are larger and directly connected to the power grid, typically belonging to utilities. These systems include large-scale energy production and storage facilities like power plants, solar parks, and substantial energy storage units. FTM systems help solve network congestion issues and can serve as alternatives to building new power lines.
Most battery energy storage systems last between 5 to 15 years. As integral components of the energy transition, these systems not only enable sustainability but also must be sustainable themselves. Reusing batteries and recycling their materials at the end of their life aligns with broader sustainability goals and applies circular economy principles effectively.
Recovering materials from batteries and giving them a second life offers significant environmental benefits, both in the extraction and disposal stages. Additionally, battery reuse provides economic advantages, reducing the need for new materials and lowering overall costs.