Idemitsu Renewables has achieved commercial operation for the Luciana solar project, a 73 MW solar project in Tulare County, Calif. It is expected to generate clean and affordable power equivalent to the needs of over 20,000 California homes. 

“Considering the unprecedented supply chain challenges the industry faced this past year, we are proud to have successfully achieved commercial operation of the Luciana project through our partnership with East Bay Clean Energy (EBCE),” says Cary Vandenberg, CEO of Idemitsu Renewables. “By leveraging our financial strength and development expertise, we’re helping California meet its aggressive clean energy goals while also providing significant investment in Tulare County.”

The renewable power generated by the Luciana project will be sold through a 15-year power purchase agreement with EBCE, which serves Alameda County and neighboring cities. “The Luciana project brings more low-cost renewable energy to EBCE’s portfolio, and it’s another big step forward on EBCE’s path to 100 percent clean energy for all of our customers by 2030,” states Nick Chaset, EBCE’s CEO.

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The co-located solar and storage project in Malawi. Image: JCM Power.

A solar and storage project totalling 20MW has entered commercial operation in Malawi, which the companies involved say is the first grid-connected utility-scale co-located project to do so in sub-Saharan Africa.

Independent power producer (IPP) JCM Power and infrastructure investor InfraCo Africa have announced that the 20MW Golomoti Solar PV and Battery Energy Storage project in the Dedza district of the country is now online.

The companies said the first-of-its-kind project, which took a little under 12 months to build, marks a milestone for the region.

The project pairs a 28.5MWp solar farm with a 50MW/10MWh lithium-ion battery energy storage system (BESS). The BESS was supplied by Sungrow as covered by Energy-Storage.news’ sister site PV Tech in May 2021 when the project was announced.

The BESS portion of the project received financial support from the Energy Catalyst programme of Innovate UK, the UK’s innovation agency. It will smooth out intermittency of the solar farm as well as provide frequency response services to the country’s electricity grid.

The solar’s effective power appears to be lower than its nameplate, with the press release stating the project will “provide 20MW of much needed power to Malawi’s grid”.

It is JCM Power’s second renewable energy project in Malawi. In October 2021, its 60MW Salima Solar project entered commercial operation.

Commenting on the Golomoti commissioning, CEO Christian Wray said: “In addition to developing and financing the project, JCM Power managed the execution of the works and, despite numerous challenges due to impacts from the global COVID-19 pandemic, we are pleased with the speed of project execution, the positive economic benefits delivered to Malawi and all while keeping our employees and communities safe.”

Some 85% of the 550 jobs created through construction went to Malawians and the process preserved ancient baobab trees which were on the site.

JCM Power has corporate backing from various development banks and has completed renewable energy projects in Malawi, Pakistan, Nigeria and Tanzania. InfraCo Africa is part of the Private Infrastructure Development Group (PIDG), an infrastructure project developer and investor specialised in sub-Saharan Africa and south and southeast Asia.

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The BESS provided by Ingeteam at the green hydrogen facility in Ciudad Real, Spain. Image: Ingeteam.

Energy conversion equipment specialist Ingeteam has supplied a battery energy storage system (BESS) for the Puertollano facility in Spain, the world’s largest operational green hydrogen plant.

The Puertollano renewable hydrogen production plant in Ciudad Real, built and owned by utility Ibredrola, was inaugurated in March 2022 by Spain’s king Felipe VI.

It will use a 20MW electrolyser to produce up to 3,000 tonnes of green hydrogen a year for a nearby factory producing green ammonia and fertilisers, run by Fertiberia Group. Iberdrola said that makes it the largest plant of its kind operating anywhere in the world.

The plant includes a 100MW PV farm with bifacial modules and an attached 5MW/20MWh BESS unit that was provided by Ingeteam, it announced yesterday (May 30).

Ingeteam provided a turnkey service with on-site assembly and subsequent commissioning. Lithium-ion batteries were integrated into four 40-foot containers totalling 1.25MW/5MWh each and the battery converters were integrated at the power stations.

The PV farm will power the electrolysers meaning the green hydrogen facility can be run entirely on renewable energy. The BESS will flatten out the peaks and troughs in solar energy production, storing the energy generated during the day and using it to power the electrolysers at night when solar production drops.

At the time of the launch of the Puertollano green hydrogen facility in March, Iberdrola chairman Ignacio Galán said the project was the start of €2 billion (US$2.14 billion) of investment to replace imported gas with green hydrogen in the production of ammonia for fertilisers. Puertollano totalled €150 million of investment, although it is not clear if this includes the BESS too.

Ingeteam’s recent BESS projects have all been in the medium-duration space. It recently announced plans to build a 70MW/340MW system in Italy, nearly five hours’ duration, a few months after supplying a three-hour system, also in Spain. In December it revealed it had supplied inverters for a four-hour co-located system in the US.

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Alfen exhibiting at EES Europe / Intersolar Munich in May 2022. Image: Cameron Murray / Solar Media.

Energy solutions integrator Alfen is building a 12MW battery energy storage system (BESS) with black start functionality for co-location with a wind farm in Finland.

Netherlands-based Alfen is building the BESS, which it claims is Finland’s third-largest, for electricity generation company EPV Energy’s Teuva wind farm. The one-hour system (12MWh) will be completed in spring 2023.

The BESS will provide grid balancing services to restore frequency in the event of a generating unit dropping off the system unexpectedly. It will also provide black start functionality to the wind farm, which means that in the event of a power outage on the local grid the wind farm can be restarted with energy from the BESS.

“In this way, the new battery system will serve as a strong risk management tool in EPV Energy’s production portfolio,” said Niko Toppari, managing director of EPV Akkuhybridi, a subsidiary of EPV Energy.

Alfen said the BESS will use its latest TheBattery Elements design which has a minimum power of 1MW. The batteries are contained in smaller, more flexible outdoor units rather than traditional shipping containers, it said.

BESS projects are increasingly being called upon to provide black start functionality for not only generating units, but even entire grid networks. The first use of a BESS to do this may have come in 2017, when a utility in California used one to fire up a combined cycle gas turbine.

In 2018, UK grid operator National Grid announced it would look at including BESS projects in future procurements of black start services. The contracts are lucrative, with around £55 million (US$70 million) on 18 Black Start contracts that year. The capability for BESS has also been talked about in Texas which has recently suffered numerous outages due to extreme weather events.

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The 480-module lithium BESS in Bastogne was built with Fluence’s Gridstack products. Image: BSTOR.

In April, an inauguration was held for the 10MW/20MWh EStor-Lux battery storage project in Bastogne, Belgium, with attendees including the country’s federal energy minister Tina Van der Straeten.

The lithium-ion battery energy storage system (BESS) was among the first projects to go online using Fluence’s Gridstack modular BESS solution and has been working to provide flexibility to Belgium’s grid since the end of 2021 through optimiser Centrica Business Solutions.

More than 30GWh of balancing capacity had been provided between switch-on and the inauguration event and as things stand, EStor-Lux is the country’s biggest BESS to date.

As was always likely to be the case, even bigger projects are now on the way, with two separate 25MW/100MWh projects from Trafigura joint venture (JV) Nala Renewables and a Nippon Koei JV financially closed and in construction.

However, EStor-Lux will always have the accolade of being a pioneering project, say Pierre Bayart and Cedric Legros, co-managing directors of BSTOR, the company behind it.

BSTOR is a brand-new company formed by the merging of Bayart and Legros’ former outfits: Rent-a-port Green Energy, which Bayart came from, is a clean energy development subsidiary of marine and industrial development group Rent-a-port. Legros joined from SRIW, an investment and economic development vehicle from the Belgian region of Wallonia, where the EStor-Lux project is located.

Although the company name and the BESS mark new territories, the project has its origins as far back as the late 1990s European wind boom and there is plenty more still to come, the pair say.

BSTOR owns 75% of the ESTOR-Lux project’s equity, with backing from what Bayart calls “fully traditional project investors who know each other from having investments together in the offshore wind business in Belgium”.

Pierre, you said that when you began this project in 2018, at 10MW and 20MWh it was considered “huge”. Of course, today other projects are coming along that are bigger, but Estor-Lux is online and can be considered something of a milestone project. What does it tell us about Belgium – and perhaps Europe’s – battery storage industry today?

Pierre Bayart: For us, we still see two kinds of project developments in Belgium. Since 2016, the TSO (Elia Transmission Belgium) is not even buying ancillary services with contracts longer than one year and even at one year, it’s not sufficient to build up a bankable business model.

What we’ve seen is two types of project development: one is more balance sheet-based, people buying an asset and taking the risk. An approach that we have brought forward, which is maybe more similar to the UK industry, is project finance-backed development.

This has been part of our ambition as of Day One, to source significant, fully non-recourse project finance on this project. Maybe an even bigger achievement than the size of the project is that 50% of the project was financed by fully non-recourse project finance, senior debt.

And this is where we draw the advantages for merchant development. We could solve the value of the project on a fully merchant basis based on corporate contracts, a bit similar to power purchase agreements (PPAs) for renewable energies, but what we call the flexibility purchase agreement in our case.

With there being so many bubbles in the energy sector crashing because of inappropriate policy-driven developments, this is the type of contract we believe in. We believe that this is the key to unleashing developments that will not depend on any political decision that can take ages to be taken.

We are of the opinion that developments should follow the needs in the markets more than the other way around because we know that there’s going to be tremendous need for storage in the system, for the system.

The project went online at the end of 2021 before its inauguration took place officially in Spring. Image: BSTOR.

Attracting project finance for merchant developments has proven tricky in some markets. One example of that is Australia, where batteries have been shown to make good revenues, but it’s quite difficult to actually model what those revenues will be and the returns over the long-term. What sort of modelling, or expectations, were you able to give investors for ESTOR-Lux?

PB: [On this project] it’s a blend of private investment companies owned by public shareholders or fully private investment companies. Fully traditional project investors who know each other from having investments together in the offshore wind business in Belgium.

Basically, how we got all our sponsors but also the lender on board, is much more through investing huge efforts in trying to understand the main drivers of the markets we were targeting, much more than very complex ‘Monte Carlo’ black box simulations.

There has been some forecasting, but really the reason why our lenders and our sponsors follow is because we could give them comfort on the fundamentals of the market, of the flexibility market that we’re about to derive our revenues from and understanding that our revenue assumptions were just totally realistic or even conservative in the uncertain long run.

Cedric Legros: Even more than the revenue forecast, you need to convince the sponsors and the lender that the market positioning is a smart one – that’s a really key point. You’re starting from the basics, you’re making the risk matrix and basically, you need to reach the most optimal risk allocation between the different stakeholders.

You’ve hinted that the origins link back to work done years ago as part of the offshore wind industry. Can you tell us a little more about that and why you’ve determined not only this project but also that this industry is the right one for BSTOR and its partners?

PB: The true genesis of this project is almost in the late 1990s. Our companies have invested together in the very early years of offshore wind development, when everyone was saying that going to construct wind turbines 30 kilometres from the shore with 40-metre depth was either crazy or stupid, or both!

In the end, we delivered pioneering projects and then also a large share of the volumes of offshore wind development in Belgium. But in Belgium we only have 60 kilometres of shoreline, so we knew that wouldn’t be an endless story… we had to find a diversification option to keep the show going.

Secondly, we realised Belgium is a small and integrated electric system and that integrating all this offshore wind would require flexibility.

We started around 2014-15 to look into storage, mainly heavy infrastructure projects like pumped hydro, or energy atolls on the sea. It all started from there already with the partners who are in the project now. We looked at greenfield and brownfield pumped hydro and then in the meantime, battery technology emerged as something viable and bankable.

At a certain moment, we made the switch to just go for battery standalone in about late 2018, or the beginning of 2019. It took us a couple of years to close the financing, one more year to close the project and now we’re up and running. The site selection for the project in Bastogne was also a gamechanger.

CL: There was already [heavy] industry based at the site with significant access to the grid – connection capacity to the grid. It takes time to get grid connection capacity from a greenfield perspective and it costs a lot as well.

Basically, having this kind of redundancy allows us to rent this connection capacity, so it allows us first to reduce the cost and secondly to speed up the development and construction of the project.

PB: The main challenge for the moment in Belgium is lead time to get access to the grid.

Actually, one of the reasons why we abandoned the PHES developments is that it was economically viable, but you would have lead times of five to seven years before first revenues from your investment decision.

With batteries you can solve it because you can reduce this to 12, 18 or 24 months, depending on the context. But as far as getting access to the grid you would need four years, so we had to find a workaround. This was the perfect place because we could access the existing substation without having to go for a greenfield connection to the high voltage network.

I’ve heard from Giga Storage, a battery storage company in the Netherlands, that it’s extremely difficult to get a grid connection, even for housing developments or new commercial premises. Is it a similar sort of situation in Belgium?

CL: It’s not worse than the Netherlands as Belgium is not as populated as the Netherlands per square metre, but we’re going to end up there. It is going to be one of the biggest challenges for the whole energy transition: how to push all the needs for generation, new electrification and new flexibility on the existing infrastructure because building new transmission lines takes about 15 years. That’s going to be a huge challenge for us and for all the people involved in energy both as producers and as consumers.

Aerial view of the project. Image: BSTOR.

Another thing that’s interesting about ESTOR-Lux is that while other markets kicked off with a lot of shorter duration projects, you guys have gone immediately for two hours. What was behind that decision and when did that come about?

PB: We could have invested in short duration projects as early as 2015, 2017. But then you can only do frequency containment, and for us this is like being paid for not doing anything, it’s just to stay on standby in case there would be a big frequency deviation that occurs every 10 years.

Bankability in the context of no subsidies and no long-term contracts meant being able to deliver energy.

We want to use the BESS as much as possible, because we believe that we should balance the grid before it ends up into frequency deviations, because those are where the volumes are where you can sell energy not only to the TSO but also to market players.

Obviously, you’re not looking for subsidy or policy-driven projects. But it’s clear that Belgium’s energy minister, Tina Van der Straeten, did support this project by coming along to the inauguration. How do you view that support from above?

PB: We deliver projects for the moment that add flexibility. In the long run, energy storage will also need to actually supply peak power with stored renewables. For this activity, you might need some subsidies, but for us, at our stage of development, it is more important to fight for equal rights for accessing the grids and accessing the market than for subsidies.

On the other hand, there is an adequacy problem in Belgium, and it is the task of the Minister to make sure that there is sufficient capacity. So, it’s also normal that she calls upon projects like us, even if they’ve not asked for subsidies, to deliver the capacity when it be needed.

For us, there is no conflict between the two positions, it’s just different use cases, and different challenges and also different responsibilities.

The federal government has done a tremendous job from the beginning by anticipating the clean energy package, to grant us such kind of equal rights in the access to the grids as early as 2017. This made our projects possible. Also, our TSO has made a tremendous jump and efforts in opening all the markets to all technologies, including storage. So, we’ve been supported by policy where we have needed to be, not in terms of subsidies, but in terms of those equal rights.

What comes next for BSTOR? More projects in Belgium? Expanding elsewhere?

CL: First of all, we are focusing on Belgium. Surrounding countries as well, but Belgium first, and we have a pipeline around 150MW in development. We are working quite hard in order to bring the next project to financial close.

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One of Gresham House’s UK battery storage projects. Image: Gresham House.

London Stock Exchange listed battery storage investor-developer Gresham House Energy Storage Fund has successfully raised £150 million (US$189 million) in a share placing announced just a few days prior.

The company is to issue 103,448,275 ordinary shares at 1p each in the capital of the company, with the placing significantly oversubscribed – leading to a scaling back exercise.

This new funding is to finance the majority of a 747MW existing battery storage pipeline the company is acquiring, with this consisting of projects in the UK and Ireland. Due diligence is under way for 674MW of this.

John Leggate CBE, chair of Gresham House Energy Storage Fund PLC said: “Strong investor demand means that we can commit to further development of our pipeline to create even greater scale and diversification.”

Application has been made for the new ordinary shares to be admitted to trading on the Specialist Fund Segment of the London Stock Exchange’s main market, with admission expected to occur and dealings in the new ordinary shares to commence on 31 May 2022.

It follows the company raising £100 million last year and £120 million in 2020.

This story first appeared on Solar Power Portal.

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Australia’s new Prime Minister Anthony Albanese at Sapphire Wind Farm, New South Wales. Image: Anthony Albanese’s office via Twitter.

An energy storage target policy could be an effective way for Australia’s new government to follow through on decarbonisation promises while insulating consumers from electricity price shocks.

That’s according to a new report from the Victoria Energy Policy Centre (VEPC), which has proposed a Renewable Electricity Storage Target (REST) to enable the country to reach the high levels of storage needed to integrate wind and solar onto the grid.  

The recently inaugurated Australian Labor Party government led by Prime Minister Anthony Albanese promised an end to the ‘Climate Wars’ that have characterised Australian politics. Among its election pledges was the creation of a new A$20 billion (US$14.83 billion) corporation called Rewiring the Nation, which could be used to fund transmission upgrades.  

However, Rewiring the Nation, as explained by Albanese’s campaign team, would largely constitute investment into Australia’s networks of poles and wires. Dr Bruce Mountain, one of the authors of the new VEPC report, told Energy-Storage.news that government intervention is still needed in the energy sector, but may be better directed elsewhere.

“We started work on this about three months ago, before we knew what the outcome [of the election] would be and we did it as a way to figure out what we thought the main focus of the future government should be,” Mountain said.

VEPC is part of Victoria University in Melbourne, conducting research and analysis on regional and national energy policies, with a core background in economics.

“We felt that Labour was likely to win, and they’d promised this A$20 billion corporation, ostensibly focused on building poles and wires for the new wind and solar farms that that are planned. We felt that that was not the right priority for the Commonwealth governments, because the states are already well and truly on to this.”

State governments in Australia are responsible for supplying electricity and have programmes and policies in place to support extensions to the transmission network.

Rather than the Commonwealth Government putting money and efforts into transmission, Mountain and his colleagues at VEPC felt that electricity storage was instead a “missing ingredient” of the energy transition on which Albanese and co could have maximum impact.

A community, or neighbourhood, battery installation in Western Australia. Image: Western Power.

Labor was elected partly on the promise of reducing greenhouse gas emissions by 43% compared to 2005 levels by 2030. The Australian Energy Market Operator (AEMO) meanwhile has estimated that by 2050, about 59GW of energy storage will be needed to integrate 204GW of variable renewable energy (VRE), equivalent to about 29% of output.

Battery storage has become a viable economic opportunity in Australia, with frequency control ancillary services (FCAS) perhaps the easiest to tap of revenue streams. However, leaving it to the market alone to decide won’t prioritise the kind of drastic emissions reductions the country needs, according to Mountain.

“We aren’t going to decarbonise just by providing FCAS, we have to decarbonise by storing electricity, and that’s an energy arbitrage economic proposition, moving electricity from the day into the evening.”

Emissions reduction has become a bipartisan effort, with state and Commonwealth government ministers alike pushing for it.

“But none of them are willing to price emissions in the electricity market. Once you have a policy to reduce, but you’re not willing to reflect that in the prices in the market, there is no alternative but to intervene,” he said.

“This is entirely justifiable as a emission reduction policy. In the same way that the RET ultimately became, although it didn’t start out as one, it did alter, and it served a role. So, this will improve the economics of storage. You can liken it to, for example, putting a A$50 to A$100 tonne of carbon price on coal.”

Bruce Mountain is keen to point out that the report largely represents a thought exercise at this point, with details, regulatory and policy framework and implementation of any target to be determined if the politicians bite and decide to adopt one.

Mountain suggested however that all types of energy storage – not just batteries – should be eligible for a REST programme, which could be paid out per kilowatt of storage installed and connected to the grid.

Despite it being a call for government intervention, VEPC asserted in the report and in Mountain’s interview with this site that there should be ample opportunity for free market activity for energy storage assets that benefit from it.

“My thinking is that this REST should be set at a level that’s likely to recover about 15% of the cost of the storage device. The rest of the income should be raised in the market, whether it’s the provision of very short-term services, as is currently the main role of batteries in the market, or whether it’s arbitrage or network support or a combination of those, they’ll need to gather that income from the market itself,” Mountain said.

Read the full report from Victoria Energy Policy Centre, ‘Electricity storage: the critical electricity policy challenge for our new Government,’ here.

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Tom Hoad of TMK and Ed Grimston, joint MD of Altelium (right) announcing a separate partnership in early May. Image: Altelium.

Specialist insurer Altelium has launched a new ‘all risk’ battery energy storage system (BESS) insurance solution, in partnership with global insurer and reinsurer MS Amlin.

London-based Altelium has partnered with MS Amlin Underwriting Limited to provide a BESS construction all risk and operational all risk insurance solution, it announced last week (23 May). ‘All risk’ means coverage that covers all risks that are not explicitly omitted in the insurance agreement.

The announcement comes a month after Altelium announced a partnership with fellow insurer Tokio Marine Kiln (TMK) to deliver, it claimed, the world’s first data-driven BESS warranty programme.

Altelium’s warranty is built on an understanding of battery properties, behaviours and data analytics. Its online platform allows every aspect of warranty, including data capture, performance and risk assessment, to be carried out through a single platform.

The company’s co-founder (along with Ed Grimston, pictured above at the time of the TMK announcement) and executive chairman Charley Grimston wrote about the importance of insurance in the battery energy storage sector in a recent guest blog for Energy-storage.news.

Few insurers have the ability to understand the chemistry and technology of BESS projects, or the ability to process and apply the data required to accurately price the risk into insurance products, he wrote.

Speaking about the partnership with Altelium on 23 May, Julian Samuel, head of natural resources at MS Amlin Underwriting Limited, said: “We’ve partnered with Altelium, a specialist in the sector, because of their deep technical knowledge and expertise within the battery market. I’m delighted that through this partnership, we are playing a part in the effort to combat climate change.”

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Slate, a large-scale solar-plus-storage project in California developed and sold to Goldman Sachs Renewable Power by Canadian Solar subsidiary Recurrent Energy. Image: Goldman Sachs Renewable Power.

Canadian Solar has said its project development arm has a pipeline of more than 27GWh of battery storage projects, while its system integrator business has a pipeline exceeding 4GWh.

The vertically integrated solar PV company announced its latest quarterly financial results last week. Our colleagues at PV Tech reported on 24 May that Canadian Solar unveiled a major new PV manufacturing strategy as it said revenues for Q1 2022 stood at US$1.25 billion, within the range of its guidance.

Meanwhile, Canadian Solar has been steadily increasing its involvement in the battery storage space over the past couple of years, through both its Global Energy project development division and CSI Solar, its manufacturing and system integration division.

The company has guided that it will ship 1.8GWh to 1.9GWh of battery storage this year and make combined solar and storage project sales worth 2.1GW to 2.6GW, alongside 20GW to 22GW of expected PV module shipments, to earn revenues within the range of US$7 billion to US$7.5 billion.

Almost all of the Global Energy business’ projects awarded to date and now in construction have been in North America, with 1,400MWh in the region and just 20MWh outside, in the Asia-Pacific region.

Of a total claimed pipeline of 24,655MWh of potential project opportunities, over 15,400MWh are in North America (see chart below).

RegionIn constructionBacklogPipelineTotalNorth America1,40015,47916,879Latin America1,0502,8603,910EMEA562,6172,673Japan1919Asia-Pacific (exc China, Japan)202,2802,300China3001,4001,700TOTAL1,4201,40624,65527,481Canadian Solar Global Energy’s storage project development pipeline as of 31 March 2022, in MWh.

CSI Solar’s battery storage system integration business meanwhile has a project pipeline totalling 7,172MWh globally, including 861MWh with long-term service agreements (LTSAs) in place, 1,572MWh in construction or contracted for, 340MWh of forecasted contract wins and 4,399MWh of prospective opportunities it is pursuing.

Forecasted opportunities are considered to be 75% likely to be won, the pipeline of prospective opportunities falls below that threshold, while projects in construction or contracted for are expected to be completed within a year or year-and-a-half.

CSI Solar earned US$82.5 million in the three months ending 31 March 2022, a massive leap from the first quarter of 2021 when it earned just US$2.358 million, although it was slightly down quarter-on-quarter from US$88.43 million.

Group CEO Dr Shawn Qu said Canadian Solar’s battery divisions are “winning contracts in new markets and segments, while continuing our development of proprietary battery storage technologies for both utility-scale and residential solutions”.

Canadian Solar entered the UK battery storage market during the quarter, winning an EPC contract for a 100MWh project.

The company’s US developer subsidiary Recurrent Energy featured in a recent article for our quarterly journal PV Tech Power. The article focuses on the rapid rise of solar-plus-storage in the US and Recurrent Energy’s head of energy storage Lucas Moller discussed how all of the company’s hybrid solar and storage projects to date are in California, but that in much of the southwest US, energy storage is increasingly key to the business case for solar PV.

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The 200MW BESS will help alleviate transmission line constraints and increase utilisation of renewable energy. Image: Getty Images.

A 200MW battery energy storage system (BESS) to be located in Heysham, Lancashire, northern England, has secured planning permission.

Forming part of a wider 1GW portfolio under development by Kona Energy, the BESS has been strategically located to participate in multiple energy markets and is situated at the landing point of six offshore wind farms.

The project is connecting on the B7a constraint boundary, which Kona Energy founder Andy Willis said is one of the most constrained areas in the UK where wind farms and other low carbon technologies are regularly curtailed.

“As these constraint costs rise, projects like this are essential to relieving network congestion and reducing unnecessary waste,” he said.

The award of planning permission to what will be one of the UK’s biggest BESS projects to date follows about a week after a 100MW BESS project also in northern England got the green light.

Developer Aura Power’s project at Drax in the English county of Yorkshire was granted planning permission by the local Selby District Council earlier this month.

Aura Power planning manager George Wilyman telling councillors that the development will “directly support the effective transition to a renewable future”.

“The alternative is generating power from diesel, gas or hydro-electric at times of high demand,” he said.

The site for the BESS was selected due to the available nearby grid connection required for import and export, with a grid connection secured at Drax Power Station – which is 600m from the site.

Drax Power Station was initially built as a coal-fired power station. Drax ended coal generation at the site in 2021, although the units won’t be formally closed until September when their existing Capacity Market obligations end. 

At the beginning of this month, a 350MW/1,750MWh UK BESS project got planning permission, co-developers Penso Power and Luminous Energy announced.

These two items originally appeared as separate news stories on our sister site Solar Power Portal.

To read the Kona Energy story in full, go here.

To read the Aura Power story in full, go here.

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