Battery Energy Storage Systems (BESS)
Battery Energy Storage Systems (BESS) play a critical role in the UK's renewable energy strategy, enabling the integration of solar and wind energy into the grid and providing backup power. Currently, over 20% of the UK's energy is renewable, with a goal to reduce carbon emissions by 80% by 2050. BESS can store excess renewable energy for peak demand times, mitigating the challenges of unpredictability from renewable sources. Key battery technologies used include VRLA, Lithium Ion, Vanadium Flow, Sodium Nickel, and Liquid Metal batteries, each with distinct advantages and limitations.
Battery Energy Storage Systems (BESS) store electrical energy in batteries for later use. These batteries are either charged via solar panels or charged overnight when grid supply is cheaper. They play a crucial role in stabilising power grids, integrating renewable energy sources, and providing backup power during outages.
Battery Energy Storage Systems (BESS)
Battery Energy Storage Systems are the only way to achieve the renewable energy targets for the UK.
Presently, over 20% is renewable energy (this includes both electricity, heating and transportation). Depending on the scenario this equates to 30% renewable electricity usage. Furthermore, the target is a reduction of carbon emissions by 80% of 1990 levels by 2050.
200 kVA Battery Energy Storage System (BESS) by Power Continuity
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Solar PV Panels and Wind Turbines
The Government and private companies are investing considerably in solar pv panels and wind turbines as well as Energy Storage Systems (BESS).
However, renewable energy sources pose quite a challenge to the National Grid. For instance, solar pv power, which we get from the Sun’s energy. Only generated when the sun is above the horizon, unimpeded by clouds. Allowing a large peak being achieved during the middle of the day. At night solar generates zero power. Wind power similarly depends on whether the wind, blowing or not. Although is planned for when selecting the best areas for wind turbines is still unreliable. One day all your wind turbines could be generating their near maximum capacity and the next they could be outputting 10% or less of their capacity. Non-renewable power stations, on the other hand, such as gas and coal are pretty constant at outputting the same output day in day out.
The unpredictability of renewable energy means that the Grid has to cope with these surges of power (which often occur when the actual UK demand for energy is quite low in comparison to its peak) potentially having to pay operators to disconnect their systems from the Grid. At the other end, a lot of renewable energy capacity is not available when the daily peaks in power usage occur. Energy storage promises to solve this by storing excess energy from renewables and feeding this into the grid when the peak power demand occurs. This is all part of a Smart Grid, which can automatically decide when to store the energy and when not to. When it comes to energy storage systems, there are a number of different storage technologies that are used. Current technologies include:
VRLA or valve regulated lead acid batteries.
These are the batteries used in Uninterruptible Power Supplies. They have been around since 1934, the cost is relatively low in comparison to other battery technologies. Deep cycle VRLA batteries are the type most suited to energy storage to ensure that they have a long enough life span for this use.
Lithium Ion batteries.
Lithium Ion batteries are commonly found in modern consumer electronics. For example, a smartphone. They have a high energy density with the potential for even higher capacities (lithium ion technology is constantly changing and improving).
The main benefit:
– can be charged/discharged more often that VRLA batteries.
– less deterioration in terms of storage capacity of longevity of product.
The main downside:
– the cost is coming down progressively.
Vanadium Flow batteries.
This battery uses vanadium ions to store chemical potential energy. They are currently quite bulky in size, nevertheless offer the ability to completely discharge without any adverse effects. Also a long life time of 20 plus years.
Sodium Nickel batteries.
These batteries use molten salt as the electrolyte. The cells themselves operate at 270+ degrees Celsius and insulated, so that the external chassis is just above ambient temperature. This allows the batteries to withstand greater temperature extremes.
Liquid metal batteries.
This battery technology uses liquid metals as both the electrodes and the electrolyte. As there is a constant regeneration between cycles, the electrodes do not degrade with time. The cost of liquid metal is currently the main stumbling block.
