Renewable Connections has been established by Armstrong Capital Management, one of the UK’s leading renewable energy companies to help drive the decarbonisation of the UK economy by developing renewable energy projects. Our team has a successful track record of developing hundreds of MWs of solar and storage projects in the UK and beyond.
Renewable Connections is investigating the potential for a 30 MW Battery Energy Storage System (BESS) at Burnbank Street, Coatbridge. Once operational, the batteries will enable energy from renewables, like solar and wind, to be stored and then released when customers need power most.
As we prepare an application to submit to North Lanarkshire Council, Renewable Connections is undertaking consultation to inform local communities of our proposed plans and invite any feedback. We will also be hosting virtual community information event to present our proposals and answer any questions given the COVID-19 pandemic. This website will remain live and will be updated throughout the planning process so please do check back for updates
We welcome any feedback you wish to provide so please do get in touch.
The proposed BESS site is located to the rear of the industrial site on Burnbank Street, Coatbridge. The area is predominantly industrial on the southern side of Burnbank Street, with housing to the north. Burnbank Street provides good access to the site. Because the site is located at the rear of the industrial site it will have limited impact on the housing to the north of the street
Our plans are still in the development stages, so our design proposals will evolve as we gather local input and the results of our planning assessments.
If installed the Battery Energy system will have a capacity of up to 30 MWp (60 MW hrs) which is the equivalent to power 6,486 homes and will be operational for up to 40 years. After this time, all of the installation will be removed, and the land restored to how it was before. The power will be imported / exported to the grid via a substation connecting directly into the SP Energy Networks Coatbridge, no new pylons will be necessary to facilitate the connection.
The Batteries will be constructed using state-of-the-art lithium-ion phosphate battery technology. It will comprise of battery storage modules aligned in rows supported by transformer and invertor platforms. The maximum height of the modules will be less than 3 metres and therefore will be lower than existing structures within the industrial estate.
The transformers and invertors platforms will be connected via underground cables. The point of connection to SP Energy Coatbridge substation will be connected via underground cables. A 2m perimeter security fence and free-standing security cameras with infrared lighting pointing into the site will protect the site to ensure safety and protect the equipment.
Documents will go live once available
Site selection
2020 – 2021
Preliminary Surveys
June – July 2021
Pre-application
August 2021
Community Consultation
17th November 2021
Submission
December 2021
Construction
2023
Following the Government’s declaration of an “Environment and Climate Emergency” in May 2019, the Committee on Climate Change (CCC) advised that to meet ‘Net Zero’ targets, the UK will require substantial amounts of new, low carbon power sources to be built before 2050, up to four times that of today’s levels. Energy storage systems are essential for achieving these goals and National Grid estimates that over 100 GWh of energy storage will be required to meet UK’s net zero target by 2050. There are currently approximately 4 GWh.
Battery storage, together with renewable energy generation help support Scotland’s target of 50% of energy for Scotland’s heat, transport, and electricity consumption to be supplied from renewable sources by 2030.
Renewable energy generation is intermittent and hard to predict due to the fluctuations of wind and solar. Intermittent renewable energy is challenging because it disrupts the conventional methods for planning the daily operation of the electricity grid. Fast fluctuation in wind and solar energy disrupts the balance between total energy supply and demand. BESS’s can react rapidly to sudden changes in the electricity supply and demand securing the stability of the network.
The BESS would have a capacity of 30 MW and be built on approximately 1 acres of land. It would optimise 100 MW of renewable energy projects around the UK to connect onto the electricity network. The project connects to the Coatbridge substation which has been identified by SP Energy as a location where a BESS would benefit the network.
Advanced technology battery storage systems can be charged by electricity generated from renewable energy, like wind and solar power. Intelligent battery software uses algorithms to coordinate energy production and computerised control systems are used to decide when to keep the energy to provide reserves or release to the grid. Energy is released from the battery storage system during peak demand, keeping electricity flowing and costs down.
Wind and solar farms are cheaper to operate than nuclear (and fossil fuels). Therefore, wind and solar can bid lower prices into electricity markets and displace nuclear from base-load operation, which it needs to pay off its huge capital costs. Nuclear reactors are not suited to working together with renewable generation due to their inflexibility they can’t react to fast changing grid fluctuations, whereas battery storage is ideally suited to balancing the grid.
This site has been identified following extensive site selection across North Lanarkshire which considered environmental designations, local electricity network access and capacity, the physical characteristics of the site, and a supportive landowner.
For a period of approximately six months during construction, there will be deliveries of equipment to site. Renewable Connections will put in place measures to manage impacts of construction traffic and these measures will be included in a Construction Traffic Management Plan that will submitted with the planning application. We work closely with the local Highways Authority to prevent damage and minimise disruption.
There will be infrequent maintenance visits to the site during operation.
No – LFP batteries (or Lithium Iron Phosphate) will be used in the Burnbank Energy Storage system. LFP batteries are thermally and chemically stable, with no risk of fumes or gas leaks. They are made of abundant, non-toxic materials like iron, copper and graphite so have a lower environmental impact from mining, processing and recycling.
BESS sites are temporary, and the land will be fully reinstated once the equipment is removed at the end of the project life.
No – the battery energy storage system will generate some low-level electrical noise from the inverter, switchgear and fans, however the noise impact for people living near the site is negligible. A noise impact assessment will be commissioned as part of the planning application submission.
Located at the rear of the industrial site at Burnbank Street, the site will have limited visual impact in the surrounding area. Any lighting will be free-standing security cameras with infrared lighting pointing into the site itself to minimise light disruption.
The development proposes a life span of up to 40 years. No later than this, the development would be decommissioned. A decommissioning plan will be provided with the planning submission.
We want to hear your thoughts on our proposals and vision for Burnbank BESS.
You can provide feedback using the form below.
Alternatively, you can also provide us feedback by emailing or posting the hard copy feedback form to: Burnbank Energy Centre Limited, 141-145 Curtain Road, London, EC2A 3BX.
Deadline for feedback is 5pm on Tuesday 7th December 2021.
Come and chat to us
burnbankbatterystorage@renewableconnections.co.uk
Telephone: 0131 555 3311
Burnbank Energy Centre Limited,
141-145 Curtain Road,
London,
EC2A 3BX
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