Brian Dunn

Summit Ridge Energy, a solar and energy storage company in the United States, has commissioned the first two of its four energy storage systems (ESS) in New York City: 15 MWh Arlington ESS and 15 MWh Littlefield ESS.

Both systems feature energy storage hardware and software supplied by Qcells, a provider of complete energy solutions and long-term partner of Summit Ridge Energy. Located across Brooklyn and Staten Island, the projects will stabilize the grid and improve resiliency as more renewable energy sources are added to the power mix, including offshore wind energy.

Once the remaining projects are energized in the coming months, Summit Ridge Energy’s four ESS will provide 58 MWh of energy storage capacity to New York’s electric grid and reduce the need for diesel-powered peaker plants. The projects will also deliver power to the grid during periods of peak demand. Summit Ridge Energy financed, developed and constructed the projects, in partnership with Qcells, and serves as the long-term owner-operator.

NYU Langone Health partnered with Summit Ridge Energy to purchase all of the bill credits from these first two projects as an innovative strategy to support grid resiliency and the transition to cleaner energy for all New Yorkers. NYU Langone is demonstrating the important role large end users, such as hospitals, can play in the move towards a low carbon future.

“We have been working closely with local governments and other stakeholders over the last several years to shape battery storage legislation in the city and are proud to see the first of these four projects come online,” says Brian Dunn, COO at Summit Ridge Energy. “We are happy to lead the charge in expanding storage in New York.”

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TEC has enlisted battery storage and virtual power plant (VPP) specialist Swell Energy to provide systems, together with GRID Alternatives, a solar installation and solar workforce skills charity. On the financing side, distributed infrastructure financier Perl Street and VC Urban US Capital are working with TEC on the project, called Bassett Avocado Heights Advanced Energy Community (BAAEC).

Households can get a solar PV system typically ranging from 3kW to 5kW, and receive either one or two Tesla Powerwall home battery storage systems. BAAEC will also pay for roof upgrades in some cases, “to ensure that roof conditions are not a barrier to equitable access to solar installation,” a TEC spokesperson told Energy-Storage.news.

The programme is made possible by California’s Self-Generation Incentive Program (SGIP), which has successfully driven uptake of solar – and more recently energy storage – in the state, offering rebates for equipment purchases.

Perl Street’s financing provides immediate access to SGIP rebates and other state-level incentive programmes, while Urban US Capital is providing funding.

“Securing this financing was a key milestone in ensuring residents in disadvantaged communities have affordable access to clean, renewable energy,” TEC director of energy innovation Genaro Bugarin said.

“Through residential solar plus storage and electrification measures, we are improving residents’ comfort and safety, and ensuring everyone participates in the transition to our clean energy future.”

While SGIP offers 25% equipment cost rebates for general market purchases of clean energy technologies, for low-income communities, the rebate rises to 80%. This latter funding comes from the ‘Equity’ tier of SGIP.

A third tier, ‘Equity Resilience’ provides funding for microgrids and other solutions to providing backup power for remote communities. While a 100% rebate is available for this tier, a Perl Street spokesperson noted that funding for this tier has already been fully allocated.

Perl Street’s representative said that the remaining 20% of the capital cost, which can be considered gap funding, is being contributed “in a limited portion” by the California Energy Commission (CEC), adding that for the programme to go beyond its initial 50 homes, that gap needs to be bridged.

According to Perl Street, SGIP, and especially its Equity and Equity Resiliency tiers are excellent in ensuring that “renewable technology gets into the hands of those who really do need it most” in low-income or disadvantaged communities.

Stacking revenues, incentives, and cutting red tape are key

TEC said that its partners are “continuously looking at how to stack incentives” available for such programmes, starting with SGIP, to help lower the cost and improve the business case for adoption of solar and storage by low-income communities.

However, it said, while BAAEC is hoping to break down those barriers in regions outside of California too, the business case at the moment does largely depend on what incentives are available at state level.

According to Perl Street though, the same kind of financing programme could “theoretically” work in other states. Most rebate programmes only allow for money to be claimed back at the end of the installation process, meaning the high upfront cost at the beginning is otherwise prohibitive for many customers and communities.

Changes to energy pricing policies will also be needed, Perl Street said.

The Perl Street spokesperson told Energy-Storage.news that rather than seeing similar 80% level rebates paid out in other states, a few reforms to the way batteries and solar can be installed and earn money would be desirable.

Perl Street offered four examples: reducing permitting and interconnection red tape and waiting time, more capacity payment programmes, better certainty over various programmes and their pricing and more real-time and time-of-use pricing of electricity.

Real-time or time-of-use (ToU) pricing can allow for better alignment of electricity supply with demand, and creates “a stronger use case for storage with renewables,” while capacity payments and demand response programmes can reward energy storage assets “for the value they bring to the grid”.

Meanwhile, in terms of certainty, Perl Street said incentive programmes are often only committed to last a year or two, while eligibility criteria is published and applications sometimes only open three to six months before taking effect.  

“You can’t finance a battery off that uncertainty,” the Perl Street spokesperson said.

The exact amount of incentive or rebate needed to make a programme such as this viable depends on being able to earn revenues in two ways: market participation in grid services programmes, and commercial value generated by the asset to the user.

Further to that, while the TEC programme leans only on state-level subsidies, the Federal investment tax credit (ITC) could provide a strong driver in other parts of the US. Perl Street highlighted that a 30% ITC will be available to most programmes of this type, with 20% adders for installations in low-income areas or in ‘energy communities’ (regions with local economies that are largely dependent on their local energy industry).   

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The NAS battery is a high temperature electrochemical energy storage device which operates at 300°C, with a sulfur anode and sodium cathode and a proprietary ceramic electrolyte. It is designed to not suffer degradation through about 15 years of use, even with daily cycling at 100% depth of discharge.

The technology is marketed as suitable for medium to long-duration energy storage (LDES) applications, and NGK has sold more than 5GWh of NAS batteries to projects around the world over 20 years, for applications that include renewable energy integration and grid services as well as C&I and microgrid energy systems.

The system sold to Sala Energy will be around 6-hour duration, with capacity given as 69.6MWh in a release from NGK and Sala Energy noting its output would be 11.4MW in a separate release issued earlier this month to the Japanese market.

The project will be the first grid-scale battery energy storage system (BESS) in Shizuoka Prefecture, which is a couple of hours’ drive southwest from the capital Tokyo. Connected to a Sala Energy substation in Shizuoka’s Hamamatsu City, it will be called Sala Hamamatsu Storage Station and marks the utility’s first entry into the energy storage market.

That market has opened up considerably in recent months, after regulators amended laws to enable more transparency in the energy trading market, the eligibility of battery storage to play into the capacity market, and adjustments in legislation to allow standalone energy storage facilities to connect to the power grid.

There are also subsidies available via the Japanese Ministry of Economy, Trade and Industry (METI) covering a portion of the capital cost of projects selected for the ministry’s programme to support the promotion of energy storage.

Energy-Storage.news spoke earlier this year with the head of energy storage at developer Pacifico Energy, which in June became the first company in Japan to trade energy from batteries, from two 2MW/8MWh projects. Pacifico Energy’s Mahdi Behrangrad said the business model required stacking up revenues from a number of different streams to make it viable, which can be complex, but rewarding.

Sala Energy put its entry into the storage business alongside other initiatives such as solar-plus-storage power purchase agreements (PPAs) for residential and C&I customers and more detailed emissions reporting, in the utility’s pathway plan to carbon neutrality by 2050 – in line with the Japanese national policy target.

Construction has begun on the NAS battery installation at Hamamatsu City, and it is expected to be in commercial operation by Spring 2026.

It’s the second deal NGK announced this week. On Monday, the company said a 250kW/1,450kW NAS battery system will be deployed at Hungary’s Centre for Energy Research.

The demonstration system, ordered by engineering company Duna Center Therm Uzemi Szolgaltato, will be used to evaluate where best to put energy storage on the grid in the European country. NAS technology was selected due to its large energy capacity, ability to discharge over long durations and peak shift solar energy, as well as their track record in the field.

The device’s designs and features also meet the requirements for national laboratory use in terms of safety and monitoring systems.   

Other recently-announced projects for NGK in what has been a busy year or so for its NAS battery division, include an 8-hour duration unit being commissioned in June at a demonstration project in South Korea, the company’s first Australian deployment, at a mining site, and an order for another 11.4MW/69.6MWh system in Japan, to be installed at a former LNG terminal owned by utility Toho Gas.

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Polar Racking, a North American supplier and manufacturer of solar mounting solutions, has been awarded the contract to supply CORE, its fixed-tilt ground-mount solar mounting solution, and ballasted foundations to two New York solar projects, Manlius and Geddes, by SolarBank Corp., an independent renewable and clean energy project developer.

The two solar projects total 10 MW and will repurpose two closed landfills, addressing both the need for clean energy and the transformation of contaminated land into valuable assets.

Polar Racking’s ballasted foundation product line, designed to securely anchor fixed-tilt and tracker solar racking solutions, and its experience supplying landfill sites made the company the top candidate for the assignment. Most recently, Polar Racking supplied ballasted foundations and racking for the 92.5 MW solar projects, Deerfoot and Barlow, located in Calgary, Alberta, Canada.

“We selected Polar Racking’s ground-mount solar solution because of the innovative and proven engineering design that stands behind it,” says Andrew van Doorn, COO, SolarBank. “Companies like Polar Racking are extending boundaries of where we can safely build large-scale solar projects, supporting our goal to drive the energy transition forward.”

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Commissioning activities have begun at Revolution, a 300 MWh battery energy storage project owned by Spearmint Energy, a renewable energy concern specializing in battery energy storage.

Situated within a major wind and solar hub in the Lower Colorado River Authority’s transmission network, Revolution is expected to be one of the largest BESS projects in the United States.

Supplied by Sungrow Power Supply Co. Ltd., the PowerTitan Series battery energy storage system uses lithium-iron phosphate battery cells and a liquid cooling system for added efficiency. Its delivery and installation is a construction highlight for Revolution and brings Spearmint closer to commencing commercial operation of the project.

“Sungrow is excited to partner with Spearmint, a like-minded and rapidly accelerating industry leader, to help bring Revolution online,” says Hank Wang, president at Sungrow Americas. “With this partnership, our PowerTitan Series Liquid Cooling Storage System batteries will continue to meaningfully contribute to the delivery of sustainable power to the ERCOT grid.”

In December 2022, Spearmint broke ground on Revolution in partnership with Mortenson, a power engineering, procurement, and construction contractor specializing in energy transmission and battery energy storage solutions. The project, which was energized in June 2023, reached mechanical completion in July and is scheduled to begin operations later this year.

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NHOA Energy’s backlog stood at €211 million, 48% higher compared to H1 2022, represented by 1,413MWh in Australia, Taiwan, China, Latin America, the US and Europe. The figure was 16% lower compared to Q1 2023, which was mainly due to the significant portion of backlog converted into revenues during the H1 2023 and the impact of commodity-indexed price formulas.

“We have converted over €30 million of backlog into revenues, which is similar to last year. We have six or seven projects in commissioning, and the rest of the portfolio is progressing healthily,” commented Giuseppe Artizzu, CEO of NHOA Energy.

In H1, a total of 1.4GWh of backlog spanned across the US, APAC, European and South American markets, while the company was awarded two contracts in the UK for a total capacity of 130MWh by EKU Energy.

Five projects entered operation in H1 2023, including the two fast reserve projects in Italy for an combined capacity of 41.1MWh, one of the two Peruvian storage systems (31MWh) and one of the storage systems in Massachusetts for Kearsarge Energy.

Moving forward, NHOA Energy is shortlisted in six projects with short-term conversion prospects. The pipeline of NHOA Energy stood at €1,035 million, down 16% from the pipeline announced in the Q1 2023 trading statement.

“NHOA Energy performed remarkably well with five energy storage projects online in H1 2023, €250 million rolling order intake and over 1.6GWh in four continents, while expanding in new key geographies, like the UK, with the newly awarded 130MWh projects for Eku Energy,” said Carlalberto Guglielminotti, CEO of NHOA Group.

Overall, NHOA Group’s EBITDA loss for H1 2023 widened to €16.59 million from a €5.27 million loss a year earlier. While revenues increased from €81.2 million in H1 2022 to €115.7 in H1 2023, personnel costs and other operating expenses increased by 101.5% to €23.34 million and 163.3% to €10.35 million respectively.

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Revolution uses Sungrow’s PowerTitan Series liquid-cooled BESS solution, with lithium iron phosphate (LFP) chemistry batteries. Sister site PV Tech ran a webinar with the Chinese PV inverter and energy storage manufacturer and integrator a few months ago, launching the PowerTitan product, which you can watch here.

Startup Spearmint was only founded in 2021, and has three strategic areas of focus: solar PV and battery storage project development, energy storage offtake and power trading of renewable energy.

CEO and co-founder Andrew Waranch wrote a Guest Blog for this site in July 2022, advocating for the use of battery storage in Texas to help the state integrate higher shares of variable renewable energy (VRE) from wind and solar onto the “broken” ERCOT grid, while maintaining reliability and security of supply.

Just a few days after that blog was published, Spearmint announced its acquisition of the Revolution project from Con Edison Development. Revolution is located next to a 279MW wind farm in Texas’ Upton County.   

The timeline of development kept pace, and in December 2022, Spearmint Energy broke ground on the project, hiring engineering, procurement and construction (EPC) contractor Mortenson to work on it.

A few months after that, in March this year, Spearmint made further Texas acquisitions, buying three projects in ERCOT totalling 900MW from an undisclosed developer and operator of clean energy projects that Spearmint said was among the largest in the US.

ERCOT projected to reach 8GW, overtaking CAISO

Texas, and specifically the ERCOT grid and wholesale market which serves about 80% of the state, has become the fastest-growing utility-scale BESS market in the US by state or transmission grid in recent years, overtaking California.  

According to S&P Global, 70% of the 710MW total of new BESS deployed in the US in the first quarter of 2023, for example, was in ERCOT. Meanwhile, from an installed base of around 2GW as of the end of Q1, the market is expected to grow to 8GW by the end of 2023. California recently just passed the 5GW mark on its main CAISO grid.

This growth has led to discussion over when market saturation might be reached. Meanwhile, Spearmint Energy got involved in a high profile discussion over the merits of artificial intelligence (AI)-driven trading of energy from battery storage systems through the pages of this site.

A Spearmint Energy representative had said the company was sceptical of the value of so-called ‘black box’ optimisation, prompting David Miller, VP of business development at Gridmatic, one such optimiser, to offer the rebuttal that the financial results should speak for themselves.

Prudence Heck and Andrew Young of Spearmint Energy’s analytics and development team wrote a Guest Blog published on this site yesterday, debating the leveraging of AI and machine learning versus the need for human intervention in the optimisation of BESS market participation.

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In March this year, the initiative committed US$2 million in funding to six DOE national laboratories to aid in their research, and the US$15 million in new funding could help accelerate research into battery storage systems.

The other half of the DOE funding will be used to support what the DOE called “pre-competitive” systems, those at an earlier stage of the research and development pipeline and not yet ready for commercial implementation.

A storage ‘supercharge’

“These funding opportunities will ‘supercharge’ the future of energy storage and enable cost-effective solutions for all Americans’ electricity needs,” said Gene Rodrigues, assistant secretary for electricity in the OE. “This is the culmination of extensive stakeholder outreach over the past year, as well as the hard work of our energy storage division which is on the forefront of spurring development of the most advanced long-duration storage available.”

While the DOE did not announce which companies or projects would receive the funding, these initiatives will aim towards the 2030 targets set by the Energy Storage Grand Challenge (ESGC), which includes a number of ambitious targets for the US energy storage sector.

Launched in December 2020, the challenge aims to reduce the levelised cost of storage for LDES by 90% between 2020 and 2030, which will drive the price of storing energy to just US$0.05/kWh. The ESGC also targets a 44% in reduction in the cost of producing a battery pack for an electric vehicle with a range of 300 miles over this period, which would put the price of producing such a battery system at US$80/kWh.

ESGC funding has been used to support a number of storage projects, including the Grid Storage Launchpad, which is being built by the Pacific Northwest National Laboratory (PNNL) in Washington with US$75 million of government funding. The department expects the launchpad to begin operation next year, and will be optimistic that its latest round of funding will be used for similarly ambitious research and development projects.

The ESGC has also committed US$17.9 million in funding for four companies – Largo Clean Energy, TreadStone Technologies, OTORO Energy and Quino Energy – to develop new research and manufacturing processes for the energy storage sector.

Positive trends in US storage systems

The DOE announced these new funding opportunities at the ESGC Summit in Atlanta. The department also noted that the PNNL and Argonne National Laboratory would serve as lab coordinators for the ESGC project for the next two years. The DOE’s OE and Office of Energy Efficiency and Renewable Energy will each provide US$300,000 in funding to cover the costs of the ESGC scheme until the end of the 2024 financial year.

The new funding has been greeted positively by parts of the global commodities sector, as International Zinc Association (IZA) executive director Andrew Green has described his organisation as “thrilled” with the news.

“The IZA is thrilled to see the DOE announce significant new investments in energy storage,” said Green, drawing attention to increasing interest in zinc as a component in battery storage systems. “We’re excited about the opportunities zinc batteries bring to this sector. We look forward to collaborating via the Zinc Battery Initiative to address these new initiatives.”

The news follows dramatic increases in the capacity of battery storage systems in the US in recent years. According to figures from the Energy Information Administration, the net cumulative capacity of large-scale battery storage systems in the US increased from 149.6MW in 2012 to 8.8GW in 2022. The rate of growth is also increasing significantly, with the 2022 capacity almost double the capacity of the previous year, which reached 4.9GW.

Government funding will likely be crucial to meeting some of the US’s more ambitious energy storage targets, both in terms of increasing the capacity of US storage systems in place, and developing technologies such as LDES. Last November, the DOE announced US$350 million in funding for LDES projects in particular, as the government looks to encourage innovation in the sector.

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Particularly in the US, AHJs are among the most important community stakeholders in the energy storage development process. As defined by the US National Fire Protection Association (NFPA), AHJs are responsible for enforcing requirements of a code or standard, as well as approving equipment, materials, an installation or procedure.

Already adopted by many AHJs is the requirement to meet NFPA 855, which is the Standard for the Installation of Stationary Energy Storage Systems. The standard aims to mitigate the hazards associated with energy storage systems.

NFPA 855, Groves said, allows for two different means of protection from explosion. Passive protection means a deflagration panel set on the BESS unit’s roof, which opens once a set pressure is reached in a deflagration event, relieving the pressure in a safe manner. This is defined by the standard NFPA 68.

Meanwhile active protection, defined by the standard NFPA 69, means equipment installed in the unit can vent gases before it gets to an explosive limit. As reported by Energy-Storage.news in June, Wärtsilä’s GridSolv Quantum large-scale BESS product was recently tested and certified to NFPA69.

GridSolv Quantum’s enclosure features a filter fan assembly on the front side, drawing air through the enclosure and exhausting it out the other side. After trying out a number of fans from different manufacturers and putting the equipment through “real world” testing, Wärtsilä settled on a make and design that maintained the concentration of explosive gases at below the required 25% limit.

“We used actual battery gas mixture to represent an actual battery cell, we released it at its peak release rate during UL9540A testing, and proved the average concentrations remain below 25% or better in the enclosure,” Groves said.

“This isn’t required by the code, but it’s something we wanted to do to validate our design and give peace of mind to customers and AHJs.”

Anyone familiar with the energy storage sector will be aware of new stories about opposition to new battery projects by local communities around the world, often motivated by perceived fears over their safety.

While fires and explosions are rare at large-scale BESS installations, and local opposition is often guided by mistaken or limited understanding of the layers of safety mechanisms inside a BESS container unit, those concerns need to be taken seriously by the industry.

Wärtsilä has been vocal recently about taking its BESS safety testing beyond the limits required by standards and conducting “worst case scenario” tests. On its NFPA69 compliance, Groves said the company is trying “to calm the nerves in the industry”.

“Our system has always had this ventilation option, but we haven’t claimed NFPA69 compliance [until now]. What we’re seeing more and more from the AHJs is, they don’t like just a passive means of protection. They don’t like the fact that you could build up to this explosive limit and then they’re at risk if there is anybody nearby the enclosures, first responders, and if there was a deflagration event, somebody could potentially be injured,” Groves said.

Automatically venting gas detected by sensors inside the enclosure helps ensure the safety of first responders such as fire crews, while Wärtsilä also allows AHJs to programme the system where the AHJ can remotely purge the gases themselves from a safe distance.

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Sited in the western part of the state, the site comprises three salt caverns. It marks Corre Energy’s first entry into the US, and the company hoped for a final investment decision (FID) in 2025 after agreeing to acquire 100% of the project.

The developer is targeting getting 1.3GW of projects under construction around the world by 2026. This includes a 320MW CAES project with 84-hour storage duration in the Dutch municipality of Zuidwending, Groningen.

As reported by Energy-Storage.news in December last year, Netherlands utility company Eneco signed an agreement with Corre Energy for the project.

The developer said yesterday that financial close has been achieved on it, while it anticipates reaching financial close on a similarly-sized project in Denmark in the second half of this year. Elsewhere, the company acquired four salt caverns in Germany adding up to 500MW of potential projects.

Corre Energy is currently seeking portfolio-level financing from institutional investors for its pipeline of projects and said yesterday that its plan to secure such funding was “progressing well”. Previous investors in the company have included Italian energy transition fund Fondo Italiano per I’Efficienza Energetica (FIEE). FIEE, which counts the European Investment Bank among its backers, committed up to €20 million to Corre Energy in mid-2021.

The company also received just under £150,000 funding from the UK government towards a long-duration hydrogen storage demonstration project a few months ago.

Corre Energy chief strategy officer Patrick McClughan wrote a Guest Blog for this site in June 2022 on how European policymakers had made powerful moves in favour of the transition to green energy. Leading with the REPowerEU plan to up renewable energy targets and reduce reliance on Russian fossil fuels, McClughan said LDES was a crucial piece of the puzzle in enabling decarbonisation and security of energy supply.

On the Texas project acquisition, Corre Energy said supportive government policy direction for clean energy made this an attractive time to enter the US market, citing the Inflation Reduction Act (IRA) and its tax credit incentives as particular drivers.

Another company attempting to bring compressed air storage into the mainstream is Canada’s Hydrostor, which has developed a different kind of technology, called advanced compressed air energy storage (A-CAES). Corre Energy has said previously that while A-CAES has higher round-trip efficiency, the site specifics required are more demanding than for its CAES technology, which is designed to be hydrogen-ready where possible.

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