California made a ‘smart choice’ to invest in low-cost renewables, now it’s all about how to best use those assets. Image: Ameresco.

California is pursuing some of the world’s most aggressive renewable energy and decarbonisation pathways. Those hugely positive steps forward however, present some key challenges that energy storage can solve, write the team from iron-air long-duration battery startup Form Energy.

To rapidly decarbonise its electric grid, California made a smart strategic choice: build gigawatts of renewable energy – the cheapest source of electricity available globally – so the state can wean itself from more expensive and polluting fossil-fueled power plants.

From 2010 to 2020, California went from producing 3.4% to almost 22.7% of its energy from solar and wind. It plans to keep building on that momentum, and anticipates building an additional 16.9 GW of solar and 8.2 GW of wind by 2030 to meet energy demand and avoid blackouts during multi-day heatwaves such as the one the state is currently experiencing.

This capacity isn’t always needed, leading to surplus energy that is curtailed, or shut off, during milder shoulder months when electricity demand is lower.

In a world without access to low-cost, long-duration energy storage, the smart investment for California customers is to just keep building more renewables to meet peak demand and avoid burning fossil fuels during expensive summer months.

But at a certain point (spoiler alert: we’re at that point), all that excess energy produced during periods of lower demand becomes an opportunity for the state.

Why are we convinced this moment has arrived? First, renewable energy curtailment is growing faster and persisting for longer periods than expected – at times persisting over multiple days. Second, new classes of low-cost, long-duration (defined here as greater than eight hours) and multi-day (defined here as greater than 24 hours) energy storage are entering the market.

These technologies are poised to deliver long-term benefits to Californians including grid reliability and resiliency, firmed renewables over any weather event or season, improved local air quality, job creation, and local economic development.

Opportunities to store hours to days of excess renewable energy

To understand the hour-to-hour dynamics of renewable energy curtailment, Form Energy examined data from the California Independent System Operator (CAISO) detailing the amount of renewable energy curtailed in California between May 1, 2014, and May 31, 2022.

The results point to the increasing opportunity for long-duration and multi-day storage to help integrate the state’s renewable energy resources.

Figure 1 below plots individual curtailment events over the eight-year period for which data are available and shows the amount of energy curtailed during each event. The size of each bubble represents the duration of the curtailment event.

Since 2014, the average duration of continuous renewable energy curtailment in California has increased from 2.5 hours to 9.5 hours. Many of these curtailment events span multiple days, with the longest event being 71 hours in duration.

The amount of renewable energy curtailed is growing rapidly; thus far in 2022, California has curtailed more than 1,860 gigawatt-hours of wind and solar, which is enough to power more than 200,000 homes for a year. Curtailment during multi-day events specifically totaled more than 110 gigawatt-hours, up more than 37 times since 2014.

Figure 1: Clean energy curtailments.

Storing excess renewable energy for when it’s needed most

During these curtailment periods, energy storage systems at the right locations can store this excess renewable energy at low cost, or even zero cost when electricity prices turn negative during periods of oversupply.

Long-duration and multi-day storage can then use this low cost excess clean energy to manage California’s demand ramps, provide power during net demand peaks, and, in the case of multi-day storage, provide reliability over multi-day lulls in renewable generation.

The first day-to-day use for this excess clean energy is to help solve California’s much discussed “duck curve” – the drop off in net electricity demand during solar production peaks followed by a rapid increase in net electricity demand as the sun sets.

If long-duration storage capacity had been available to charge with the curtailed energy shown in Figure 1 and discharge that energy during peak demand periods, California could have saved more than US$129 million since 2014 and avoided roughly 1.1 million metric tons of carbon dioxide emissions1.

The second major use case for excess clean energy is to fill energy supply during renewable energy lulls. These periods of low intermittent generation are the flip side of the renewable energy curtailment coin.

Form Energy’s analysis of 35 years of solar and wind profiles used in the California Public Utilities’ Commission’s Integrated Resource Planning Process identified 138 instances of multi-day renewable energy lulls (where a lull is defined as any period in which combined wind and solar output is more than 25% below average).

These multi-day renewable lulls pose the greatest reliability threat to deeply decarbonised grids. Today’s commercial battery technologies can economically store up to roughly eight or twelve hours of energy, meaning that they run out of juice during cloudy, calm periods of low renewable generation when they can’t recharge from day to day.

As a result, clean technologies capable of delivering energy over multiple days are critical for ensuring low-cost, clean, reliable power.

Without such technologies, grid planners will need to build vastly more renewable energy than the grid needs to meet typical energy demand and they may also need to keep fossil-fueled resources online, at high cost to customers.

Modeling of a zero-carbon grid in California in 2045 shows how this excess clean energy can be used to support grid reliability during one such lull.

Figure 2 below, taken from the preliminary results of E3 and Form Energy’s assessment of the ability of long-duration storage to help meet California’s energy goals, shows how lower solar output during a cloudy fall week makes it impossible to charge shorter-duration lithium-ion batteries such that they can’t dispatch sufficient energy to meet demand in the evening hours. Instead, multi-day storage steps in to fill this gap, serving California load cleanly and reliably when it is most needed.

Figure 2: Example dispatch during multi-day renewable lull in a portfolio with multi-day storage.

With the frequency, magnitude, and duration of renewable energy curtailment events increasing in California, the opportunity for novel long-duration and multi-day storage technologies to deliver value to California customers has arrived.

Seizing the opportunity

The value of long-duration and multi-day storage technologies to the electric grid will only increase over time as California’s decarbonisation goals become more stringent and the state needs to call on firm zero carbon resources during periods of low renewable output, extreme heat, and other stress conditions.

The state’s recent heatwave led to requests for residents and businesses to keep electricity demand low for nearly a week, underscoring the emerging multi-day weather challenges the state is facing.

Fortunately, the state has already made notable strides toward bringing long-duration and multi-day storage technologies to market. In a first among states, California approved US$126 million in incentives to demonstrate new long-duration storage technologies.

Scaling these nascent technologies requires utilities to begin factoring them into resource planning, which presents a specific modeling challenge that must be addressed. Capturing the hour-to-hour operational dynamics of these resources is the key to understanding their value, which is most apparent during multi-day periods of excess energy and energy scarcity.

Current industry-standard models only capture grid dynamics during a small number of “representative” days or weeks per year, and thus understate the value that multi-day storage can provide to the grid.

However, emerging modeling tools and techniques make it possible to consider the full range of likely grid extremes and to represent the economics of resources that can shift energy across days and seasons. The combination of new long-duration energy storage technologies and better grid planning tools makes it possible to build an electric grid for California that is more reliable, cleaner, and increasingly cost effective.

Note1: Preliminary results from an ongoing Energy and Environmental Economics, Inc. and Form Energy study identified a substantial opportunity for long-duration storage in a zero carbon California grid. The capacity-weighted average round trip efficiency for the long-duration storage resources identified in this study was roughly 39.4%.

Form calculated the dollar and emissions savings numbers by multiplying the total curtailment during events of 8 hours or more (6,809,126 MWh) by the weighted average round trip efficiency (39.4%) and either the on-peak energy prices between 2014 and 2022 (for the monetary value calculation or the natural gas emissions factor (408 kg CO2/MWh) (for the avoided emissions calculation). Average on-peak energy prices for CAISO were taken from S&P Market Intelligence. The natural gas emissions factor was taken from the U.S. Environmental Protection Agency.

About the Authors

Form Energy is a US-based energy storage technology and manufacturing company developing and commercialising a pioneering iron-air battery capable of storing electricity for 100 hours at system costs competitive with legacy power plants.

This piece was written by Form’s Scott Burger, senior manager of analytics, Jason Houck, senior manager for policy & regulatory affairs, Andea Scott, summer strategy & market development analyst and Rachel Wilson, manager of strategy & market development analytics.

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Array Technologies Inc., a provider of utility-scale solar tracker technology, is launching its two newest product offerings: Array OmniTrack and Array STI H250. The U.S. launch of the two products expands Array’s existing line of DuraTrack products.

The three tracker product lines address varying customer requirements and the changing needs of the utility-scale solar industry and meet the IRA’s domestic sourcing content requirements.

“The addition of OmniTrack and STI H250 to our continuously evolving product portfolio will help our U.S. customers to better address the unique challenges of their sites. Having a broader offering for our customers helps bring more clean energy to the market faster, advancing the clean energy transition,” says Array CEO Kevin Hostetler. “Array’s global reach, combined with locally-focused sourcing solutions, enhances our ability to deliver the best utility-scale solar solutions to our customers around the world.”

Array OmniTrack, the newest tracking solution to the Array portfolio, is specially designed for customers developing project sites on uneven and challenging terrain. Array’s OmniTrack terrain-following solution mitigates challenges associated with projects on undulating terrain while reducing costs and schedules by enabling less complex site preparation and design.

Following Array’s acquisition of STI Norland in early 2022, the addition of the STI H250 provides customers with a full suite of solar trackers products. STI H250, which upholds Array’s stringent standards for reliability and durability, is designed for sites with irregular boundaries, highly angled blocks or fragmented project areas.

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A 4.5MWh BESS using Audi EV batteries brought online by RWE in January 2022.. Image: RWE.

Germany’s early lead among Europe’s battery storage adopters is now long gone. But with the urgency to deploy renewable energy compounded by the need for greater energy independence, some industry players and experts see change coming on the horizon in the German market, Cameron Murray writes.

This is an extract of an article which appears in Vol.32 of PV Tech Power, Solar Media’s quarterly technical journal for the downstream solar industry. Every edition includes ‘Storage & Smart Power,’ a dedicated section contributed by the team at Energy-Storage.news.

As by far Europe’s largest economy, the German market is usually on the radar of businesses in any fast-growing and internationalising sector. But when it comes to large-scale front-of-meter battery storage projects, its deployment figures for 2021 lagged far behind the UK, Ireland and France.

The residential sector has conversely always been very strong, as homeowners increasingly seek to back up their home PV systems. But just 32MW of utility-scale (1MW-plus) projects were installed in thecountry in 2021, according to a recent report by a group of RWTH Aachen University-based and spinout organisations.

However, the situation is starting to change, one of its authors tells PV Tech Power.

“The large-scale market is gaining traction, with different drivers from previous years. You have big Innovation Tenders for co-located sites, you have many industrial sites installing MW-plus systemsand you also have the Grid Boosters which will provide a huge boost to the market,” says Jan Figgener, head of grid integration and storage system analysis at ISEA RWTH Aachen University.

People see the German market now as ‘boiling’ and want to be there early, adds Florian Mayr, partner at clean energy finance and strategy consultancy Apricum.

Two companies which were part of the start of the energy storage boom in the UK, investor Gore Street Capital and renewables developer Anesco, entered the German market in quarter one 2022. In June, SwissLife Asset Managers, which has US$290 billion of investments, joined them when it acquired a platform with a 220MW BESS pipeline.

But this bullishness isn’t necessarily widely shared. Claus Urbanke, head of wind and solar Germany for Norwegian hydropower company Statkraft, says that the short-term storage needs of the market arelimited and that Statkraft does not currently see a commercial case for standalone battery energy storage, although it is participating in the Innovation Tenders from federal network operator Bundesnetzagentur for co-location, explained later.

Jorg Blaurock, partner at 3Energie Consulting which produces annual reports on the storage sector for national storage association BVES, agrees to an extent. He says that Germany does not need any moreenergy storage for grid stability as its needs are already well served by existing assets and interconnection with other countries, and that the main driver is opportunities in the wholesale energy market capitalisingon increased volatility.

Where are we today?

One big reason why the German battery energy storage market has not taken off yet is because of a relatively small grid frequency services market, typically the first driver for battery storage because of itsstable revenue guarantees. This relates to Germany’s greater array of options for grid flexibility, including numerous interconnectors to other national grids.

Value stacking is also more difficult due to unfavourable regulatory conditions. This stems from the existing regulatory definitions for storage assets being inadequate according to BVES, although should change going forward after new definitions were brought into German law in May 2022.

Frequency containment reserve (FCR) is the main ancillary service for batteries to play in, but the 550-600MW market is close to saturation with around 600MW of utility-scale battery energy storage installedat the time of writing, according to project developer ECO STOR.

FCR will soon be replaced by aFRR, which will help make the service more international amongst Europe’s interconnected markets, although will not on its own increase the size of the market, points out Statkraft’s Urbanke.

“There was a short time when these (short duration storage) projects were commercially viable in primary reserve (FCR), but since this is such a small segment of the market which got exploited quickly,this opportunity doesn’t exist anymore,” he says.

The period he refers to is around 2018 when nearly 200MW of utility-scale battery storage was installed according to Delta-EE, a record year for the sector. But the market slowed substantially in 2020 and 2021 as FCR was increasingly saturated.

The largest operational battery storage system in Germany today is the Lausitz Battery Energy Storage System at 60MW/52MWh, attached to a coal plant operated by power plant operator andutility LEAG. LEAG, RWE and other large utilities have been the main players installing large systems to-date, says Lars Fallant, COO of project developer Tricera Energy.

These are market-driven projects, he adds, capitalising on grid frequency services and trading opportunities. These, plus the Innovation Tenders incentivising co-located storage projects and a handfulof massive ‘Grid Booster’ storage tenders are the main drivers of the market going forward, according to all the sources we interviewed.

The Smareg
4 project in
Eisenach,
Germany,
developed by
Smart Power and
recently acquired
by BCP Battery. Image: Smart Power.

‘Ukraine has amplified the drivers’: ancillary services and short-term trading

Along with the rest of the European Union, Germany recently upped its renewable energy targets for 2030 to reduce reliance more quickly on Russian fossil fuels after its invasion of Ukraine.

As more renewable resources come onto the German grid, this will increase market volatility which in turn creates an opportunity for battery storage to capitalise in short-term trading markets. Delta-EE anticipates thatthis ramp-up in storage will start in 2025 although the numbers it is expecting are still far below what is needed. It expects around 450MW of additions in 2025 growing (with a dip in 2026) to around 800MW in 2030.

But even before any ramp-up of renewable resource deployment happens – it’s still early days – the existing revenue opportunities for storage have increased substantially, says Georg Gallmetzer, managing director of ECO STOR. And that is despite a revenue source that has historically made up half of the value stack for big batteries no longer being available for projects being commissioned after 2022.

He says that the prices in the auxiliary (ancillary) service markets and spreads in short-term trading have multiplied so much recently that the business model is stronger than last year, even with a 30% increase in material costs due to supply chain constraints (lithium-ion batteries, transformers, concrete and building work etc).

Fallant partially agrees: “The frequency response and energy trading markets have increased recently, but most owners go for frequency response because it ages the battery less quickly because of shallowercycling. But the outlook is that batteries will do more energy trading, although no one knows exactly where the prices will go.

Because growth in energy storage will never keep up with growth in renewables, according to Gallmetzer, opportunities for storage in trading and grid services will continue to increase until the 2030s or2040s when batteries may eventually begin to cannibalise their revenue opportunities.

This is an extract of an article which appears in Vol.32 of PV Tech Power, Solar Media’s quarterly technical journal for the downstream solar industry. Every edition includes ‘Storage & Smart Power,’ a dedicated section contributed by the team at Energy-Storage.news. Subscribe to the journal and read the newest (Q3 2022) edition and all previous issues here.

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GameChange Solar has unveiled the terrain-following Genius Tracker TF. This system allows for greater slope change, allowing the tracker system to follow the undulations of the ground. This allows installers to drop construction costs by reducing or eliminating civil grading work as confirmed through real-world testing.

“Customers have been asking for terrain following capabilities for our leading Genius Tracker system,” states Andrew Worden, CEO of GameChange Solar. “Not only have we met their requests, but we have leapfrogged all other tracker companies to give our customers the greatest post to post slope change and other needed topography related allowances in the industry. We feel this can meaningfully reduce grading costs and help our customers improve their project ROIs.”

GameChange Solar is a manufacturer of fixed tilt and tracker solar racking systems, with over 21 GW sold.

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Terra-Gen’s EdSan 1A solar project on Edwards Air Force Base in Kern County, Calif.

Independent renewable energy provider Terra-Gen LLC has completed financing on the second phase of its Edwards Sanborn Solar Storage facility in Kern County, Calif.  This phase of the Edwards Sanborn Solar Storage facility is composed of 410 MW AC of nameplate solar capacity (358 MW AC at the point of interconnection) and 1,786 MWh of battery storage.  The first phase of the Edwards Sanborn project was financed in July 2021 and its 345 MW of solar and 1,505 MWh of storage are now fully operational.

The financing for the second phase includes $959 million senior secured credit facilities comprising a $460 million construction and term loan facility, a $403 million tax equity bridge facility, and a $96 million construction and revolving letter of credit facility. U.S. Bank is providing the tax equity commitment for the project, with BNP Paribas, CoBank, ING and Nomura Securities leading the construction and term financing. 

“Consistent with the first phase of the Edwards Sanborn project, the second phase deploys an innovate offtake structure that has been well received in the financing markets and allows us to raise the capital necessary to progress the construction of this transformative project,” says Jim Pagano, Terra-Gen’s CEO. “Once complete, Edwards Sanborn will play a significant role in helping California meet its carbon reduction goals and ensure electricity reliability through the use of stand-alone and collocated energy storage.”

Terra-Gen’s Edwards Sanborn project is located in Kern County on land leased from Edwards Air Force Base as well as on adjacent private land. Mortenson is the full engineering, procurement and construction contractor on both the solar and energy storage scopes with First Solar supplying the solar modules and LG Chem, Samsung and BYD supplying the batteries.

Terra-Gen expects the solar portion of the second phase to come on-line in the third and fourth quarters of 2022 with the battery storage scheduled to be fully operational by the third quarter of 2023. Terra-Gen is advancing development on future phases of this project that will include over 2,000 MW of incremental solar and energy storage to be interconnected to the CAISO grid. Subsequent phases will begin to be financed in 2023 and begin to come on-line in 2024.

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Another Greenbacker Renewable Energy Co. LLC solar project in Washington

Greenbacker Renewable Energy Co. LLC (GREC), a green energy investment company and independent power producer, has entered into a senior credit agreement of $186.2 million with KeyBank N.A. and Fifth Third Bank. KeyBank served as administrative agent for the lenders, and KeyBanc Capital Markets and Fifth Third Bank, National Association served as joint lead arrangers.

The transaction is one of Greenbacker’s largest standalone debt financings to date, providing a construction loan facility to build two of the biggest solar projects in company history.

The MTSun and Fall River solar farms – which make up GREC’s Ponderosa portfolio – are each 80 MW AC. Both assets have long-term power purchase agreements in place with local investment-grade utilities, MTSun with Northwestern Energy and Fall River with Black Hills Power Inc.

“We’re thrilled to partner with KeyBank and Fifth Third Bank on this senior credit agreement to build projects that will drive a clean energy future in a very real way,” says Spencer Mash, CFO of GREC. “Once complete, they’ll deliver cheaper renewable energy to tens of thousands of households across Montana and South Dakota.”

“The Ponderosa transaction illustrates our ongoing commitment to grow the renewable energy industry by deploying capital in high-quality assets,” states Gregory Berman, director of Utilities Power & Renewables at KeyBanc Capital Markets. “This represents our seventh financing with Greenbacker, and we look forward to supporting their continued growth as a leader in the energy transition.”

The two assets are located in Yellowstone County, Mont. and Fall River County, S.D., respectively.

“Fifth Third Bank’s commitment to financing renewable energy technologies is well-known and steadfast,” comments Kyle Kuhn, renewable energy executive director at Fifth Third Bank. “We are pleased to be a part of this milestone transaction with Greenbacker that will support the clean energy transition.”

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QuickBOLT has named Jared Wiener as president. QuickBOLT is a division of Quickscrews International Corp. Founded in 1987 as a local wholesaler of products for the cabinet and furniture trades, Quickscrews has evolved into the fastener supplier. Facing a deep recession in 2009, Quickscrews launched its QuickBOLT solar division.

“My focus as president is to build upon the foundation the company has created over the past 35 years while guiding the company towards the future. Of course, this includes greater expansion into the solar mounting and racking industry,” says Wiener. “I’ve been part of many different teams throughout my life, and this is one of my favorites because of how dedicated to hard work everyone here is. It is inspiring after a long day to look around and see my teammates right there with me, putting in the effort to help our customers and each other. I enjoy the bonus of working with my family, which has been very rewarding for me.”

Wiener was exposed to Quickscrews at a young age, packing screws in the warehouse and working in various departments during summers and school breaks. After graduating from Cal Poly SLO in 2012, he moved to Taiwan to learn about fastener manufacturing. Between 2014-2018, he pursued an MBA while leading the marketing team; during that time, he led the company through a rebranding of its Wood and Solar divisions. The solar division alone went from a few thousand QuickBOLTs sold to over 3 million in just a few years.

“The company’s strong foundation is in good hands, as leadership strengthens with the next generation,” comments CEO and founder Greg Wiener. “I’m very proud to see Jared step into his new role, and am confident in his vision.”

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Prospect14, a solar energy developer, has partnered with a group of energy investors and operators with expertise in power generation and quantitative trading to launch Ampliform, a joint venture that will originate, develop, build, operate and optimize utility-scale solar and solar + storage projects in the United States. Ampliform is backed by a significant equity commitment from a consortium of investors led by the Jones Family Office, alongside Barings, the George Kaiser Family Foundation and others.

Prospect14, led by Carl Jackson, Geoff Underwood and Charles Silio, will provide greenfield origination, development and construction services to Ampliform. Also investing in Ampliform and serving on its executive leadership team on behalf of Greens Ledge Renewable Partners (GLRP) are Brad Romine and Steve Culliton, who previously led North American power generation investments, power trading and asset optimization for Castleton Commodities International; John Vivenzio, who previously served as chief technology officer of King Street Capital Management, a global alternative asset manager; and Mikael Andren, who serves as CEO and president of the Jones Family Office and related entities.

“We are very excited to partner with such experienced investors and power plant operators to drive the deployment and optimization of solar + storage projects at scale,” says Jackson, a partner at Prospect14. “Brad, Steve and John have had tremendous success optimizing power plants, managing quantitative energy trading operations, building robust trading and operational data analysis infrastructure, and putting in place innovative financing for energy projects. That experience combined with our ability to pinpoint interconnection opportunities and scale them quickly in targeted markets is unique within the industry and will be invaluable as Ampliform transitions towards a merchant model.”

“We’re partnering with Prospect14 on this joint venture because they have built a unique platform with a track record of using data-driven methods to site and develop solar + storage projects at scale in the nation’s most competitive energy markets,” states Romine, a partner at GLRP. “We are developing our projects with the intent to own and operate them efficiently, so we begin projects with the end in mind and implement creative, data-driven approaches to optimizing plant design, development and construction. This will make Ampliform faster and more efficient at every stage from greenfield development through to operations.”

Ampliform launches with more than 3 GW of early- and mid-stage projects under development, the first of which are expected to begin construction in 2023. Ampliform is actively pursuing additional greenfield project origination as well as acquisition opportunities of solar projects and interconnection capacity, with a plan to build a development pipeline of more than 10 GW by 2025.

“Solar energy is an increasingly important part of the U.S. energy mix. In Ampliform, we see a tremendous opportunity to build a leading, highly differentiated company to help drive the energy transition,” comments Paul Tudor Jones II. “Ampliform has a significant competitive advantage because of its ability to scale rapidly, leverage technology and data, and take innovative approaches in bringing its assets to market.”

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Mike Wight

Discover Battery, a SOLV4EX company headquartered in Richmond, British Columbia, has added Mike Wight and Troy Daniels to its growing solar team with for its energy storage systems.

Based in Utah, Wight joins Discover Battery as a solar sales engineer. He brings over 15 years of experience as an electrician, off-grid/micro-grid designer/builder, special operations and crew manager, and solar power system consultant. Wight graduated from Solar Energy International (SEI) as an engineering professional.

“Michael is an experienced system designer with a demonstrated history of working in various industries that need specialized expertise in solar and energy storage,” says David Norman, VP of product and business development for solar at Discover Battery. “Skilled in customer service, sales, strategic planning, research and management of new solar technologies, his unique skill set will help further our customer goals and ensure their energy needs are met and that we all are on the cutting edge and leaders in the industry.”

Colorado-based Daniels joins Discover as installer relations manager. He has years of experience in the solar industry and direct battery experience working for a lithium battery manufacturer.

“Troy’s experience building solar installer relationships allows Discover to reach our target audience faster and make a direct impact with installers,” states Norman. “His direct experience with lithium batteries and building installer support tools and training is invaluable to our business.”

With new product launches on the horizon, Discover is reinforcing its existing solar team to facilitate expected growth in this segment.

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Ambri’s liquid metal batteries are housed in stainless steel containers. Image: Ambri.

A liquid metal battery storage system has been commissioned at a Microsoft data centre, reducing the software giant’s use of fossil fuels and enabling it to access ancillary service energy markets.

Technology provider Ambri, which developed the proprietary high temperature battery, announced yesterday that the system has been successfully commissioned at an undisclosed data centre location, thought to be in the US.

The battery tech, spun out of labs at MIT by company founder Professor Donald Sadoway, is aimed at providing a low-cost, long-duration energy storage resource based on abundant materials and designed to be safe from the risk of thermal runaway, which can cause fires in lithium-ion batteries.

It uses anodes of liquid calcium alloy and a molten salt electrolyte with solid particles of antimony in the cathodes, arranged into stainless steel containers. Ambri received key UL1973 safety accreditation for its system in July.

The technology was recently picked out for a demonstration project by US utility company Xcel and Ambri received an order in June for a 300MW/1,400MWh project in South Africa.

At the Microsoft data centre, the battery system is integrated with a UPS solution provided by energy management and automation group Schneider Electric. Output and capacity of the system was also undisclosed.

“Ambri’s batteries will help improve Microsoft’s datacenter operations while delivering important environmental and commercial benefits,” Ambri’s chief commercial officer Adam Briggs said.

Microsoft’s Upshur Quinby, energy innovation manager at the company’s Datacenter Advanced Development team, said the project provides a pathway to achieving goals of running on 100% renewable power and replacing diesel backup generators by 2030, all while maintaining reliable service.

“Enhancing energy storage capabilities — including implementing long duration battery solutions for datacenters — is critically important to our mission. With this partnership, we are strengthening our commitment to sustainability and taking another step in our work to support the grid with ancillary services and shifting,” Quinby said.

In July, Microsoft also equipped a data centre site in Ireland with a grid-interactive battery storage system, that one based on lithium-ion technology.

Microsoft’s deployments of battery tech have echoes of a recent project by Google, which deployed a lithium-ion battery energy storage system (BESS) at a data centre in Belgium, with similar aims.

Both Microsoft and Google are members of the Long Duration Energy Storage Council (LDES Council), which seeks to advance the utilisation of LDES technologies. Additionally, Energy-Storage.news reported yesterday that Microsoft has signed up to the Energy Storage Solutions Consortium, which seeks to assess and maximise the greenhouse gas (GHG) reduction potential of the available technologies.

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