Fluence’s 1MW pilot project for LitGrid in Lithuania, which has been quickly followed by the start of construction of four 50MW/50MWh storage assets for the transmission system operator. Image: Litgrid.

A couple of weeks ago, Energy-Storage.news met with leading figures from the energy storage industry at RE+ 2022, the trade exhibition and conference combining the Solar Power International and Energy Storage International events under one, very big roof at Anaheim Convention Center in California.

Battery storage technology provider Fluence officially launched in 2017 as a joint venture by AES Corporation and Siemens, two companies that already staked a claim to be energy storage pioneers with growing offerings and customer orders.

A lot has changed since then, not just for the company, which booked nearly 1,500MWh of customer orders in the first nine months of 2022, but for the industry as a whole.

For regular readers of this site, many of those changes will be well known. From the way lithium battery prices fell and fell for years before the rise in demand converged with pandemic-driven logistics challenges to arrest that decline, to how energy storage is finally becoming recognised around the world as an important tool in the energy transition, unlocking some – if not yet all – of its potential.  

We begin our series of ‘in conversation’ articles with a chat with Kiran Kumaraswamy, Fluence’s VP of growth and head of commercial.

On the opening day of the show, we saw you speaking on a panel about long-duration energy storage (LDES). There has undoubtedly been huge interest in LDES at the show and around the industry. One of your thoughts was that LDES technologies need to be able to demonstrate qualities that go beyond, or are fundamentally different, to what lithium-ion offers.

Kiran Kumaraswamy: In general, the volatility in lithium pricing has also sparked a renewed type of interest on the non-lithium technology side, which is genuine.

But in order to be of high value in the segment, you have to figure out what type of market needs these technologies address, and there are certain use cases that actually have a lot of promise.

Like on the transmission side, using energy storage as a transmission asset, and on providing, let’s say, 24/7, or ‘around-the-clock’, renewable energy using the combination of resources, wind, solar and storage to create some type of hybrid system that can deliver full renewable energy across a whole spectrum of time.

The extreme case of that could be that you do that with time matched renewables also, so that it’s not that you’re on an average providing 24/7, but you have matching timestamps, and you’re delivering it 24/7.

The approach that long duration has to potentially take is to figure out the market application that makes the most amount of sense. It’s very likely that either the market construct or the rules are not in place for this technology to get awarded appropriately in the marketplace. But once you have a very strong view on the value proposition that you bring to the grid, with the long-duration storage, then you go figure out ways to make that happen in the marketplace.

It sounds like something Fluence is looking very closely at. How much of a limiting factor is bankability for some of these newer technologies?

Bankability is a big limiting piece, honestly. Lithium has a significant advantage in that it has a very deep supply chain, and banks that are willing to stand behind that, and so it is one of those hurdles that the alternate non-lithium technology base has to overcome.

Again, if you coalesce around what the use case is and then improve the technology out through its first few installations, that probably is a pathway towards getting there, but it is certainly a hurdle to overcome.

Fluence’s Kiran Kuraswamy (second from left) talks long-duration energy storage at RE+ 2022. Image: Andy Colthorpe / Solar Media

One source a little while ago told us that the Inflation Reduction Act (IRA) could be a boost for those alternative technologies. The IRA will introduce an investment tax credit (ITC) incentive programme for standalone energy storage, along with domestic manufacturing incentives from the IRA and other legislation like the Bipartisan Infrastructure Law. We’ll have to wait and see what the details around the ITC will be, but what are your thoughts on the IRA, which we saw you’d celebrated the passing of, at a special White House event recently?

I think it’s remarkable what we’ve achieved on the IRA itself. It’s 10 years of certainty that we’ve developed for this entire marketplace. You can see it in the posture of people at the show. People are beaming with confidence, and it’s remarkable to see. I was told that there’s 20,000 people here (the final attendance figures at RE+ turned out to be in excess of 27,000).

Getting the standalone storage investment tax credit was a massive victory for us. What you have for the first time is a decoupling of development timeframes from having to worry about only interconnection issues on the storage side.

Because previously, if you did renewables-plus-storage, you would think about development from the perspective of getting land, and getting permits, and going through interconnection in a combined fashion to avail the ITCs.

Now you have a different dynamic because you’ve decoupled the solar development pathway and storage doesn’t require as much land as solar does. The only piece that you now have to solve is this interconnection piece, which takes quite a long time, but it’s a very different dynamic to solve for.

How that actually shows up in the marketplace, we have to wait and watch over the course of the next 18 to 24 months, in terms of what dynamic that it creates. That’s one impact of IRA.

The other one is that the impact of the IRA on the target addressable market for energy storage is significant in the United States. I think that our leading analysts’ estimates say that the market for standalone energy storage is going to go up to something like 140GW [cumulative installations] by 2030. It was [forecast at] around 70GW to 75GW previously.

The market has basically doubled. That is extraordinary, it puts this market at a place that nobody ever thought it would be.

How do you think the industry will adapt to the changing dynamics of the market?

There’s going to be many, many plays oriented around how people develop their commercial go-to-market, how people develop technology pathways, how business models evolve over time, how companies take advantage of the direct pay, because they don’t need a tax equity partner for the first time.

All of those have to form in the next 18 to 24 months. People are still wrapping their head around many of the facets of what the IRAs provisions are, figuring out options on how to position themselves on each of these factors, whether it’s on the commercial go-to-market, technology side, on business models to transact, financials, all of it together.

That means that on the technology side too, companies will be looking at how to develop more domestic manufacturing, and how to source many of these materials in a manner that maximises the usage of these available ITCs.

Fluence, for instance, we have announced our manufacturing of some of the products in the US and so we’re working with a partner to actually make this happen. I think it’s going to be a very exciting time.

What sort of level of vertical integration might Fluence target with that strategy?

Some of that will be confidential information, but we are certainly looking at US manufacturing of some of the products.

Presumably some of the decisions around that will also be made a little later, once the company knows how the incentives will work for producing or using US-made content?

I think so. One other thing I learned from my trip to the White House is that the amount of time that it might take for the IRS to put out actual guidance on this topic could actually be quite significant.

They have to draft a lot of clarifications on the rules. The law is signed right now, but the intent of the law has to show up in any rules the IRS and Treasury Department actually write down.

How long that takes is anybody’s guess. In today’s market, it could take six months, it could take eight months, it could take 12 months. Nobody knows, and that’s going to have an impact on what is applicable and what’s not happening for this credit.

Fluence’s GridStack BESS units at a recently commissioned project site in California, about 100 miles north of Anaheim where RE+ took place. Image: Leonardo Moreno, president of AES Clean Energy, via LinkedIn.

Fluence is obviously a global company, with projects in various markets around the world. In Europe it’s been interesting to see the 200MW/200MWh of battery storage across four separate systems the company is supplying in Lithuania take shape for transmission operator LitGrid. It’s a rare example of energy storage being used as a transmission system asset.

That’s an important project that started not long before Russia’s invasion of the Ukraine, with Lithuania and other Baltic countries aiming for greater grid synchronisation with one another and with Europe long before the war began. What is this project – and perhaps others like it – proving?

As a company, we are investing in developing product and technology capabilities in the segment on storage as a transmission asset.

Broadly, within Europe, we see that application catching a lot of traction. The interest by the transmission owning companies to utilise energy storage to add reliability, and resiliency for the system is increasing.

Think about it this way, the problem that we solve on the generation side, and the problem that we solve on the transmission side, are identical.

We build generation and transmission for the one-hour peak that happens in 8,760 hours (of the year in total). We build the church for Christmas Day: it is so large, because during Christmas Day, we want everybody to get a seat, nobody has to stand. On Christmas Day, it’s perfect, but any other day it’s too big.

Whether it’s the generation side, where you build peaking generation plants, or on the transmission side, where you build transmission lines to satisfy the peak, the problem is identical.

So, the next time you’re investing in, let’s say a US$300 million to US$500 million transmission project, people will have to ask if there was a more efficient way of solving these problems. Now, that’s not to say that you don’t need backbone transmission. There’s a lot of transmission that we need to build in all parts of the world, but we also have to consistently keep asking the question, how do we improve the utilisation of the existing transmission grid?

That’s where the use of technology like fast acting battery energy storage has huge potential.

I guess it’s fair to say any sort of transmission infrastructure investment decisions will be made on a cautious basis, and Fluence is bullish on the potential of batteries as a transmission asset. What are the limiting factors storage faces in penetrating that market opportunity?

I think the regulatory considerations are the limiting factor. This is an area where having regulations that clarify the use of storage for this application would be incredibly helpful in a market like the US.

It is a slow-moving market, in that, for example, the GridBoosters (transmission level projects in Germany for TSOs) have been in development the last two years or three years, they’re just beginning to transact right now. Chile has something similar to that too.

It’s an extraordinary value proposition, but these things take time, because they need to make their way into the national or regional transmission expansion plan and then they need to be approved by the regulatory body in those regions or in those countries, and then they need to be procured and put into service.

It’s a long cycle but I’m still super excited about it. Why? Because of the transformational power that it brings for us to add resiliency to the electric grid and use power grids more efficiently.

Being transformational requires you to do those trade-offs – you can’t achieve a transformational change without them. Transformational change is not easy.

And if I look at the US, in most parts of the US grid this application has significant potential.

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Hitachi Energy delivered the first battery project in Australia capable of providing inertia to the grid through advanced inverter technology (pictured), in Dalrymple, South Australia. Image: Hitachi Energy.

Japanese tech conglomerate Hitachi has bought the remaining 19.9% stake held in Hitachi Energy by ABB.

Hitachi Energy was formed as a joint venture (JV) between the two companies as Hitachi acquired 81.1% ownership of Switzerland-headquartered ABB’s power grids business in mid-2020. The JV was known as Hitachi ABB Power Grids until October last year, when it rebranded to reflect the new majority ownership.

Hitachi Energy is involved in a broad range of power sector technologies and services, including high voltage DC (HVDC) transmission infrastructure, transformers, SCADA and control systems.

It also manufactures its own range of battery energy storage systems (BESS), called PowerStore, mostly aimed at the larger industrial and utility-scale applications. Powerstore is modular and can be configured for use with nickel manganese cobalt (NMC) battery cells from Samsung or lithium iron phosphate (LFP) cells from CATL.

Powerstore is designed to be used in a variety of regions as it is adaptable to different grid codes. The BESS is part of its Grid Edge Solutions portfolio, which also includes e-mobility equipment and other distributed energy resources (DERs) equipment, controlled and monitored by Hitachi’s digital software platform, E-Mesh.

The company announced on Friday that it has signed an agreement with ABB for the remaining shares, which had always been the plan. Hitachi said transfer of shares will be completed by the end of December.

“Electricity will be the backbone of the entire energy system and the urgency of the energy transition requires us to collaborate and innovate across stakeholders and sectors, and the good news is that we can act now,” Hitachi Energy CEO Claudio Facchin, who is also a senior VP and executive officer at Hitachi, said.

“Hitachi and Hitachi Energy have been generating synergies by combining digital and energy technologies that are contributing to the global energy transition.”

Hitachi Energy-supplied solar-plus-storage project opens at Canadian water treatment plant

In related news, a solar PV plant at a water treatment facility in Alberta, Canada, went online at the end of September, equipped with a Hitachi Energy BESS.

Edmonton-headquartered water and energy services company EPCOR held the power plant’s grand opening on 20 September, at EL Smith Water Treatment Plant in the city of Edmonton. The water treatment plant serves about two-thirds of drinking water consumed in Edmonton and 65 nearby communities, pumping around 250 million litres of water every day.   

The site’s 13.6MW solar PV array is paired with a 4MW/8.9MWh BESS in a behind-the-meter microgrid. If energy production exceeds requirements at the water treatment plant, it can be exported to the grid.

Named kīsikāw pīsim, which means ‘daylight sun’ in the local Enoch Cree Nation language, the project is one of Hitachi Energy’s first to combine batteries with solar PV, with most of the company’s projects to date having been standalone BESS.

Other battery projects it is currently working on include the first grid-scale BESS in Australia’s Northern Territory, which began construction in late August-early September, and an EPC contract to work on a 20MW/20MWh BESS in the Philippines with Philippine power company Aboitiz Power and renewables developer Scatec.

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SolarEdge Technologies Inc.’s SolarEdge Home Battery has qualified to join grid operator Rocky Mountain Power’s Wattsmart Battery program. This will enable Rocky Mountain Power to leverage customer-generated solar power along with battery technology in the homes of over 60,000 existing rooftop solar customers in Utah and Idaho.

Launched in 2021, the Wattsmart Battery program utilizes a growing fleet of residential batteries to help manage the electric system during peak usage periods.

The program has over 3,000 batteries currently enrolled in Utah and Idaho. The SolarEdge partnership will allow Rocky Mountain Power to take advantage of the fast response and accurate cloud control of SolarEdge smart inverters and distributed batteries to help balance the grid in real-time while building toward the grid of the future.

“Wattsmart is an innovative program, but what really sets it apart from other VPPs is the speed of deployment. While typical demand-response programs work on a day-ahead basis, the Wattsmart program is designed to respond on-demand with almost immediate response in unplanned grid events,” states Peter Mathews, SolarEdge North America’s general manager. “The more flexibility and speed battery assets can provide, the more valuable they are to grid operators – both as a contingency and frequency reserve. As we continue to move towards a net-zero economy, this level of optimization will become the standard for VPP models, allowing grid operators such as Rocky Mountain Power to build a resilient and flexible distributed energy grid of the future.”

Homeowners joining the Wattsmart Battery program with the DC-Coupled SolarEdge Home Battery will benefit from higher efficiency due to its ability to directly store DC power from the sun, reducing the number of energy conversions and reducing energy loss.

“When a customer participates in the program, they are partnering with Rocky Mountain Power to innovate for the future and become part of a sustainable energy grid solution,” adds Bill Comeau, Rocky Mountain Power’s vice president of customer experience and innovation. “The SolarEdge Home Battery, along with its advanced grid-connectivity capabilities, will help us to advance that effort.”

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One of fourteen community solar projects in Illinois that leverages Solar FlexRack’s FlexTrack Solar Trackers.

Solar FlexRack has supplied its FlexTrack Solar Trackers for a 42 MW portfolio of community solar projects in Illinois to Summit Ridge Energy, an owner-operator of community solar assets. All 14 projects are part of Illinois Shines, a state-administered program that creates incentives for the development of new solar photovoltaic projects. Once these projects are complete, small businesses and homeowners will be able to access clean, reliable energy while saving up to 10% on their electricity bills.

“We’re pleased to work with Solar FlexRack on these projects given their engineering expertise and reliable partnership,” says Raj Soi, executive vice president of operations at Summit Ridge Energy. “With over 250 MW of clean energy assets online or in development in Illinois, we’re proud of our leadership in the state and we look forward to continuing to deliver more affordable and reliable clean energy to local communities.”

These projects were established through the Illinois Climate and Equitable Jobs Act (CEJA), which was signed into law on September 15, 2021, re-establishing the Illinois Shines ABP, which authorizes the purchase of Renewable Energy Certificates (RECs) from solar panel system owners. At least 250 MW of new community solar projects have already been approved through this program and when completed, these projects will allow an estimated 35,000 families to lower their electric bills without installing solar panels.

“Summit Ridge Energy is a leader in renewable energy in Illinois and we are excited to have the opportunity to work with their team to cost effectively deploy a large volume of high quality community solar projects in the state,” comments Greg Lewis, director of sales for Eastern U.S. at Solar FlexRack. “Having completed hundreds of cold weather challenged projects in Canada and the Northeastern U.S. over the past decade, we look forward to further utilizing our expertise and tracker technology in these impactful projects.”

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Microvast Holdings Inc., a company that designs, develops and manufactures lithium-ion battery solutions, has launched a new energy division. Microvast Energy designs, develops and manufactures Battery Energy Storage Systems (BESS) that are co-located with solar solutions using Microvast’s battery technology. The engineering, sales, marketing and customer care departments for Microvast Energy are headquartered in Northern Colorado.

Zach Ward has been appointed as president of Microvast Energy, with overall responsibility for the division’s strategic direction, operations, product development, sales and key relationships. He has executed more than 20 GW of utility and distributed generation solar and 500 MWh of energy storage projects.

“We are excited to launch the new Microvast Energy division and support the rapidly growing energy storage market, with an initial focus in the United States,” states Ward. “Our grid-scale BESS solutions provide critical infrastructure capable of addressing the gap between renewable energy supply and peak grid demand. With the recent passing of the Inflation Reduction Act and the construction of our new Tennessee manufacturing facility, we look forward to advancing clean and renewable energy initiatives. Additional details on Microvast’s industry leading BESS solutions will be forthcoming.”

Microvast’s BESS solutions will incorporate battery cells and modules manufactured in Clarksville, Tenn. The Clarksville facility features 650,000 sq. feet of manufacturing space on 85 acres and is expected to create up to 300 new jobs in the region.

“We believe the Clarksville factory will contribute to the resilience of the domestic lithium-ion battery supply chain, create manufacturing jobs, and expand American battery capacity for the US power grid,” says Shane Smith, Microvast’s COO.

Microvast’s new BESS solutions have been developed for grid-scale energy storage projects using the same proven technology as Microvast’s EV batteries.

“We expect the superior performance of our BESS solutions to exceed the expectations of our customers and put us in a leading position to take advantage of the benefits outlined in the Inflation Reduction Act,” Ward adds. “We expect the current electrification trends to further accelerate and keep us very busy.”

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Markus Krebber

RWE AG has signed a purchase agreement with Con Edison Inc. to acquire all shares in Con Edison Clean Energy Businesses Inc. (Con Edison CEB). Headquartered in Valhalla, N.Y., Con Edison CEB is an operator and developer of renewable energy plants in the United States, with about 3 GW of operating capacity, thereof 90% in solar energy, and a strong development pipeline of more than 7 GW.

Combining RWE’s and Con Edison CEB’s portfolios almost doubles RWE’s operating asset base in the U.S. to 7.2 GW. Growth from the acquisition will come on top of RWE’s existing growth plans for the United States. RWE had already earmarked up to EUR 15 billion gross for investment in the U.S. as part of its Growing Green strategy, which envisages global investments of EUR 50 billion gross by 2030.

RWE and Con Edison have agreed on a purchase price based on an enterprise value of $6.8 billion. At a multiple Enterprise Value/EBITDA of 11x, this represents an attractive price. Furthermore, with EBITDA of around $600 million from year one on, the acquisition is earnings accretive.

Closing of the transaction is subject to customary regulatory approvals and is expected to take place in the first half of 2023.

Financing of the acquisition and the additional growth are funded through debt instruments and an equity capital measure undertaken by RWE AG. Equity will be raised via issuance of a mandatory convertible bond to a subsidiary of QIA (Qatar Investment Authority). The mandatory convertible bond will have an aggregate principal amount of EUR 2,427.6 million and will be converted into new ordinary bearer shares, expected to represent just under 10% of RWE AG’s existing share capital (approximately 9.09% post conversion). RWE maintains its plan to pay a dividend of EUR 0.90 per share for fiscal 2022.

“Our equity capital measure is the basis for financing the acquisition of Con Edison CEB and of the additional green growth in the years to come,” says Markus Krebber, CEO of RWE AG. “I am delighted that QIA is supporting RWE’s accelerated growth ambitions with their capital commitment. This underlines our strategy to be one of leading drivers of the global energy transition.“

Prior to the transaction with Con Edison, the geographical footprint of RWE’s operating base includes much of Texas, with projects also in the states of New York, Pennsylvania, North Carolina, Georgia, Ohio, Indiana, Illinois, Oklahoma and Arizona.

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Another Renesola completed project, the 2.6 MW Helen solar project in Minnesota (Image: Renesola Power)

Solar project developer ReneSola Ltd. has closed the sale of a ~70 MW portfolio of solar development projects to funds managed by AB CarVal Investors L.P., an alternative investment fund headquartered in Minneapolis, Minn.

The portfolio consists of three ground-mounted utility-scale projects in Pennsylvania located in the broader PJM transmission territory. The projects are being sold at the Notice to Proceed (NTP) stage, and AB CarVal will complete the construction and retain long-term ownership.

“We continue to successfully execute our NTP sale strategy in one of our most important markets, United States,” says =Yumin Liu, ReneSola Power’s CEO. “AB CarVal is an excellent partner in this portfolio, and we are thrilled to close this transaction. We look forward to collaborating with them on future opportunities.”

“These are the largest scale single site project sales in the U.S. for ReneSola Power to date and represent years of commitment to utility solar development in this market,” comments John Ewen, CEO of ReneSola Power North America. “Project development is complicated and AB CarVal demonstrated patient and steadfast commitment through the process.” “It’s rewarding to be part of expanding renewable energy access in the U.S.,” adds Jerry Keefe, principal at AB CarVal. “ReneSola Power is a great partner to work with, and their extensive experience was a clear benefit in originating these solar projects. We look forward to collaborating again on future sustainable energy endeavors.”

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A battery storage project the utility turned on in Iowa in August this year. Image: Alliant Energy.

Wisconsin utility Alliant Energy has announced plans to deploy two projects totalling 175MW/700MWh of battery energy storage in the midwestern state.

The plan was filed last week (30 September) with the Public Service Commission of Wisconsin and calls for battery storage units to be developed in Grant and Wood counties.

The planned projects are both four-hour systems, with Wisconsin appearing to follow in the footsteps of the California market, the US’ most developed where four hours is now a widely used duration for energy storage.

Grant County battery project would total 100MW/400MWh while the Wood County would be 75MW/300MWh. Both would be co-located with solar PV developments, with Wood County’s completed last week and Grant County’s expected online in late 2023.

Pending approval from the Commission, Alliant intends to start construction on the battery storage projects in 2023 and for them to be online by autumn 2025.

Filings on the Commissions’ website for the Wood County, as well as Grant County projects, indicate that system integrator Flexgen will be providing the battery storage solutions to Alliant. A map of the project site demarcates where a ‘Flexgen Hybrid OS’, the company’s in-house energy management system (EMS), would be located.

The utility has a Clean Energy Blueprint plan to build 1,100MW of utility-scale solar PV across the state. Alliant said the battery storage capacity would provide additional flexibility and smooth out intermittent generation.

David de Leon, president of Alliant Energy’s Wisconsin division (it also operates in Iowa), said: “As we transition to cleaner, more cost-effective renewable energy, the added capacity and unique capabilities of these energy storage solutions will strengthen our generation portfolio, improve reliability and help meet customer needs. It’s just one more way we’re delivering on our purpose-driven strategy.”

The company turned a smaller, 5MW system online in Iowa in August this year.

2022 has seen several large solar and storage projects go ahead in the midwestern state. In March, investor-owned utilities MGE and WEC Energy received the regulatory green light to buy a 200MW solar park with 110MW battery storage in Kenosha County, as reported by Energy-Storage.news at the time. A month later, Invenergy had a 300MW solar, 165MW battery storage plant approved.

IHS Markit expects the midwestern region as a whole to grow as an energy storage market as it phases out its coal plants.

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The prototype machine. Image: Aceleron.

A prototype system that can test and sort used battery cells for second life applications has been developed by four companies in the UK in a government-funded initiative.

The system, pictured above, relies on a combination of robotics, software and automation to detect the health of individual cells taken from end-of-life battery projects like EVs.

The project has been underway since May 2021 and was part-funded by Innovate UK, the UK’s innovation agency. It involved four companies and organisations including Aceleron, the battery energy storage system solution company which designs its systems to be easy to disassemble and re-purpose.

Other participants include Innvotek, a specialist in the automation of inspection, maintenance and the digitisation of processes; MEV, an ultrasonics specialist company providing equipment and expertise in operating systems and bespoke application software; and the Brunel Innovation Centre, part of Brunel University.

The companies said the prototype has the potential to significantly reduce the unnecessary waste of the raw materials used to build batteries.

Carlton Cummins, Aceleron’s CTO and co-founder said that at the end-of-life point, half of the battery cells in an EV battery will typically still have a state of health higher than 80% which could give them a lifetime of a decade or more in the stationary energy storage sector.

Second life solutions company Connected Energy’s CEO Matthew Lumsden, who Energy-Storage.news recently interviewed, says that a 25% degraded battery is still good for ten years of energy storage.

Cummins added: “As we increasingly turn to electricity to power our lives, the issue of battery waste is of serious concern and this new system has the potential to preserve cells that would otherwise have been discarded. With Lithium shortages being forecast as soon as 2035, this machine has enormous potential to preserve what is left – and ensure that we maximise the use of the raw materials used to make battery products.”

The issue of waste in the lithium-ion battery sector has come to the fore in recent years as the number of cells in use grows exponentially with the rise in EVs and energy storage. In a guest feature for Energy-Storage.news in June, Piotr Grudzień, innovation consultant at Bax & Company, proposed a four-step plan to improve the efficiency of battery reverse logistics in Europe. The US just launched a US$335 million battery recycling programme.

EV groups are increasingly tying up with second life energy storage solution companies to repurpose their batteries for storage, but the scale and universality of these are small relative to the size of the market.

A major challenge in designing storage systems using pre-used batteries is the potential lack of uniformity of design, degradation and use case history amongst constituent battery cells. Lumsden said his company’s ‘secret sauce’ was a sophisticated battery management system (BMS) that could communicate across these parameters, but ensuring storage units are as uniform as possible to start with will also be integral to ensuring systems perform.

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One of the fund’s battery energy storage system (BESS) projects. Image: Gresham House.

Gresham House Energy Storage Fund (GRID) has seen its net asset value (NAV) increase by 53.5% to £785 million (US$879 million), the London Stock Exchange-listed firm disclosed in its half year results ending 30 June 2022.

This NAV increase builds from previous results of £511 million from 31 December 2021. As well as this, the NAV total return also increased by 27.2%.

According to Gresham House, the NAV increase has been assisted by upward revaluations of projects that went from being valued at cost to a value using a net present value basis. In doing so, this reflected underlying internal rates of return (IRRs) of the projects at the time they were acquired.

This increase in projects means the Fund’s total operating capacity is now expected to reach 1GW/1.2GWh by the end of the first quarter of 2023. This is ahead of the prospective portfolio of 1.6GW by mid-2024 with a duration of 2.1GWh.

“We are pleased with GRID’s performance in the first half of the year as we continue to deploy essential battery energy storage infrastructure and deliver above-target total returns to shareholders,” said John Leggate CBE, chair of Gresham House Energy Storage Fund.

“We have started to draw down on our debt facilities as expected. Combined with the £150 million equity we raised from shareholders, we expect these funds to deliver most of the existing pipeline, taking GRID to over 1GW of capacity, currently expected by the end of Q1 2023.

“We are ambitious to scale up GRID, both in the UK and beyond, enabling a cost-effective transition to net zero, supporting near-term energy security as gas supplies continue to be unreliable while helping maximise the output from low-cost renewable energy sources.”

Building on its portfolio, as of 30 June 2022, GRID had 425MW across 17 operational projects. This has increased to 500MW across 19 operational projects as of 31 August 2022.

602MW across 11 projects had been under construction as of 30 June 2022 with this having increased to 527MW as of 30 August 2022. The firm now has confirmed a further 90MW is due to commission in the coming days.

“Our next batch of projects is in advanced stages of construction; as of today, a further 527MW across 9 projects are anticipated to commission in the next six months, going into 2023. Beyond that, our project pipeline into 2024 is also strong, with over 500MW planned for the 12-18 months that follow,” said Ben Guest, fund manager of Gresham House Energy Storage Fund and managing director of Gresham House New Energy.

“Great Britain (GB) needs at least 20GW of BESS by 2030, demonstrating its critical importance to the energy transition. We are working on additional pipeline both in GB and overseas, and we look forward to providing updates as this work progresses.”

In late May, Gresham House Energy Storage Fund confirmed it raised £150 million following an announcement of a new share placing. This resulted in the increase in projects as witnessed in the half year results.

The funding was used to finance the majority of a 747MW existing battery storage pipeline the company was to acquire, with it consisting of projects in the UK and Ireland. At the time, due diligence was under way for 674MW of this.

This story first appeared on Solar Power Portal.

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