PVEL QE-Labs Drone EL testing

PV Evolution Labs (PVEL) and Quantified Energy Labs Pte. Ltd. (QE-Labs) have signed an exclusive agreement to provide drone inspection services in the U.S. solar market. PVEL will be the provider of QE-Labs’ autonomous drone electroluminescence (EL) imaging technology for conducting front-end field inspections. The back-end data processing will be handled by QE-Labs in Singapore.

EL imaging is an inspection method that can reveal defects and microcracks of solar cells inside a photovoltaic (PV) module. It is widely used as a tool for quality control in PV manufacturing. For years, PVEL has used a manual daytime EL tester conducting field EL inspection of more than 2 GW of underperforming or damaged PV systems. Currently, EL imaging is only conducted on a sampling basis due to the speed and cost limitations of manual inspection technologies. With this new agreement, PVEL will expand their field testing services to perform faster inspection of large-scale solar assets.

“We are impressed with QE-Labs’ technology, which completed the world’s largest EL inspection in Singapore with a much faster and more cost-effective solution than what is available in the market today,” states Jenya Meydbray, CEO of PVEL. “By leveraging this proprietary technology, PVEL looks forward to bringing this innovative autonomous drone EL solution to the downstream solar community in the U.S.”

The collaboration between QE-Labs and PVEL will provide project developers, asset owners and investors with a comprehensive testing service that will help ensure quality assurance and quality control of solar PV power plants across their 25-year lifecycle.

The drone EL imaging services can assist with identification and evaluation for insurance and/or warranty claim for damaged and/or underperforming PV modules as well as technical due diligence prior to PV asset transaction or leasing. They help with initial site-acceptance-testing (SAT) to exclude physically damaged PV modules caused by poor workmanship and detection of early failures before the defect liability period (DLP) ends, including excessive light induced degraded (LID) PV modules. In addition, annual PV module quality health checks closely monitor up to 100% of the PV system.

“With established success in our home market, we are ready to deploy our autonomous drone solution in more regional markets to support the growth of the global PV industry,” comments Dr. Wang Yan, CEO of QE-Labs. “This collaboration with PVEL is QE-Labs’ first step towards global expansion based on our drone-enabled Data-as-a-Service business model. Together with our partners, QE-Labs will establish a global service network for our clients to use the innovative autonomous drone EL inspection at anytime and anywhere. As global PV installations cross the 1 TW milestone, we hope these innovative services can help drive further investment in and expansion of solar PV projects worldwide.”

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How operations at the site could look. Image: ABB.

ABB will provide technical expertise on the development of a lithium extraction facility in Portugal, which targets zero emissions status by 2030. 

The Switzerland-headquartered automation and engineering technology company has signed a Memorandum of Understanding (MoU) with Savannah Resources, owner of the Mina do Barroso Lithium Project in northern Portugal. 

The spodumene lithium project has the potential to offer high quality concentrates and Savannah has been granted a mine lease for 27Mt mineral resources, value until 2036 and extendable. The operation could be expanded at a later date.

It could be a useful resource for Europe’s battery industry in reducing dependence on imported materials, mostly from China. Savannah wants to implement nearly 240 measures to ensure responsible development and mitigate environmental impacts as it moves to establish the site as carbon neutral by 2030. 

Operations would be mostly powered by locally generated hydro, solar and wind energy.

Meanwhile ABB will look at how the Barroso site can be electrified, automated and digitalised, while its engineers will formulate production control and process solutions that could eliminate emissions.

It is one of a number of zero carbon emissions lithium extraction plants that have been in development around the world: another in Europe is planned for Germany’s Upper Rhine Rift region by Vulcan Energy Resources, which would take lithium from deposits in brine pumped up from the ground using renewable energy. 

As reported by Energy-Storage.news, LG Energy Solution signed an offtake agreement for battery grade lithium chemicals from Vulcan’s site, which intends to begin commercial supply in 2025. 

In the US, California’s inland Salton Sea, a landlocked body of highly saline water, is being seen as a potential site for extracting lithium from geothermal brine. Developer Controlled Thermal Resources (CTR) wants to build the lithium extraction facility and a geothermal power plant to start coming online in 2023 and 2024. 

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Rendering of the 200MWh BESS at Kogan Creek, Queensland. Image: CS Energy.

A 100MW/200MWh battery energy storage system (BESS) comprising Tesla Megapacks will be built by a state-owned power company in Queensland, Australia.

The state government announced today that generation company CS Energy will install the grid-scale project at a site near the town of Chinchilla, in Queensland’s Western Downs Region, about 300km inland from Brisbane.

The project will cost around AU$150 million (US$112.6 million) and will create up to 80 jobs during construction and 10 operations roles once commissioned. Queensland Treasurer and Minister for Trade and Investment Cameron Dick said the project should be operational by the end of 2023. 

“Queensland has the natural resources of wind, sun and water to be a renewable energy superpower. As we work towards our target of 50% renewable energy by 2030, we can also support more jobs in new industries right across regional Queensland,” Dick said. 

The BESS will be part of an energy hub CS Energy is developing at the site of Kogan Creek Power Station, a 750MW black coal power plant fed by a neighbouring coal mine, both of which the company owns. The system will be connected to the Western Downs 275kV substation of network operator Powerlink. 

CS Energy is also building a green hydrogen demonstration plant at the hub which will be charged from an onsite 2MW solar PV power plant and will have its own smaller 2MW/4MWh battery system to help feed the 700kW hydrogen electrolyser and fuel cell.

The demonstration plant will have onsite hydrogen storage capacity of about 750kg and through an offtake deal with Sojitz Corporation, hydrogen produced at the plant will be exported to the Republic of Palau. 

Queensland authorities stepping in where federal government has ‘done little’

The renewable energy hub marks the latest plan by an Australian power company to leverage an existing coal power plant site for its land and infrastructure and use it for battery storage and other clean energy technologies. Connection to the grid, as well as access to water and workforce are among the direct advantages. 

Yallourn coal plant in Victoria, which is scheduled for retirement in 2028, will be host to a 350MW/1,400MWh BESS built by the plant’s owner, EnergyAustralia. Eraring coal power plant in New South Wales is planned for closure by owner Origin Energy by 2025 and will be host to a 700MW BESS.

Australia’s biggest generation and electricity retail company AGL recently got approval for a 500MW/2,000MWh BESS to be built for a renewable energy hub at Liddell power station, a coal power plant set for retirement by the end of April 2023 in New South Wales.

 In the case of the CS Energy Kogan Creek site, CEO Andrew Bills said the BESS project would give power plant employees the chance to learn about the new technology as the energy industry adapted to the low carbon energy transition. 

Adding the new project to its portfolio would enable CS Energy to compete better in the National Electricity Market (NEM), as it evolves to favour the competitiveness of fast-responding battery storage and inverter-based renewables, Bills said.

Queensland Minister for Energy, Renewables and Hydrogen Mick de Brenni took a bit of a shot at Australia’s federal government, headed up by Scott Morrison, stating that the federal budget —announced today and slammed by the national Clean Energy Council for its continued lack of ambition on climate issues — did little for the state. 

Hence Queensland’s government was instead stepping in to fund the BESS, which he said represented “further diversification of energy and modernisation of Queensland publicly-owned power generation”.

Investment in energy storage solutions will enable the continued uptake of rooftop solar in the state, de Brenni said, allowing more Queenslanders “to enjoy the savings” that cheap renewable energy could bring. 

Australian solar and storage market research group Sunwiz recently reported that the country installed more than 1GWh of energy storage in 2021, the first time that figure has been exceeded for a year’s deployments. However, Queensland represented a fairly small wedge of that, accounting for just 8% of the entire market and for 14% of operating commercial and grid-scale storage capacity to date across Australia.

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U.S. Secretary of Commerce Gina Raimondo

The enforcement and compliance arm of the U.S. Department of Commerce intends to investigate whether imported solar cells and modules from Vietnam, Malaysia, Thailand and Cambodia are circumventing federal antidumping and countervailing duty orders on crystalline silicon photovoltaic cells from China.

The decision was prompted by a request from U.S.-based solar company Auxin Solar, which in February reached out to the department and asked that regulators look into whether solar cells or modules produced or assembled in those Southeast Asia countries use parts or components from China.

If so, those cells and modules may be subject to the same or similar antidumping and countervailing duties, adding significant downstream costs to these products and, in turn, potentially increasing the cost of solar installations overall.

At the heart of the issue is Auxin’s contention that U.S.-based solar manufacturers and assemblers cannot compete with low-priced solar products coming from China: the main driver behind the antidumping and countervailing duties themselves.

Opponents such as Auxin believe those tariffs, however, have little effect if Chinese solar manufacturers – Jinko Solar, Hanwha Q CELLS, Trina Solar, Yingli, JA Solar and others – can simply export materials and products to places like Vietnam, Malaysia, Thailand and Cambodia for final production and assembly, and thereafter exportation to the U.S., circumventing the tariffs.

The industry’s largest trade groups and advocates fall on the side of the larger supply chain, stressing that the commerce department’s decision to further investigate alleged circumvention and potentially expand solar tariffs would be profoundly adverse.

“This misstep will have a devastating impact on the U.S. solar market at a time when solar prices are climbing, and project delays and cancellations are adding up,” Solar Energy Industries Association (SEIA) president and CEO Abigail Ross Hopper said in a statement.

“President Biden has been clear that the best way to grow domestic manufacturing is to create a policy environment that encourages private investment. This decision directly contradicts that goal – more tariffs are not the answer,” she added.

The American Clean Power Association (ACP) echoed SEIA’s reaction.

“If its commitment to a clean energy future is real, the administration will reverse this decision immediately,” remarked ACP CEO Heather Zichal, noting that the Department of Commerce “drove a stake through the heart of planned solar projects and choked off up to 80 percent of the solar panel supply to the U.S.”

“Every day this investigation hangs over the solar community is a day of lost jobs and postponed solar projects critical to the administration’s climate agenda,” she added.

The department has not issued a formal set of actions or a timeline for its circumvention inquiries.

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Francesco La Camera

Short-term interventions addressing the current energy crisis must be accompanied by a steadfast focus on mid- and long-term goals of the energy transition. High fossil fuel prices, energy security concerns and the urgency of climate change underscore the pressing need to move faster to a clean energy system, says World Energy Transitions Outlook 2022.

Launched by the International Renewable Energy Agency (IRENA) at the Berlin Energy Transition Dialogue, the agency’s Outlook sets out priority areas and actions based on available technologies that must be realized by 2030 to achieve net zero emissions by mid-century. It also takes stock of progress across all energy uses to date, clearly showing the inadequate pace and scale of the renewables-based transition.

The outlook sees investment needs of $5.7 trillion per year until 2030 including the imperative to redirect $0.7 trillion annually away from fossil fuels to avoid stranded assets. But investing in the transition would bring concrete socioeconomic and welfare benefits, adding 85 million jobs worldwide in renewables and other transition-related technologies between today and 2030. These job gains would largely surpass losses of 12 million jobs in fossil fuel industries. Overall, more countries would experience greater benefits on the energy transition path than under business as usual, according to the Outlook.

“The energy transition is far from being on track and anything short of radical action in the coming years will diminish, even eliminate chances to meet our climate goals,” says Francesco La Camera, director-general of IRENA. “Today, governments are facing multiple challenges of energy security, economic recovery, and the affordability of energy bills for households and businesses. Many answers lie in the accelerated transition. But it’s a political choice to put policies in place that comply with Paris Agreement and the Sustainable Development Agenda. Investing in new fossil fuel infrastructure will only lock-in uneconomic practices, perpetuate existing risks and increase the threats of climate change.”

Renewables would have to scale-up massively across all sectors from 14% of total energy today to around 40% in 2030. Global annual additions of renewable power would triple by 2030 as recommended by the Intergovernmental Panel on Climate Change (IPCC). At the same time, coal power would have to resolutely be replaced, fossil fuel assets phased out and infrastructure upgraded.

“It is high time to act,” La Camera adds. “Recent developments have clearly demonstrated that high fossil fuel prices can result in energy poverty and loss of industrial competitiveness. Eighty percent of the global population lives in countries that are net-importers of fossil fuels. By contrast, renewables are available in all countries, offering a way out of import dependency and allowing countries to decouple economies from the costs of fossil fuels while driving economic growth and new jobs.”

The outlook sees electrification and efficiency as key drivers of the energy transition, enabled by renewables, hydrogen and sustainable biomass. End-use decarbonization will take center-stage with many solutions available through electrification, green hydrogen and the direct use of renewables. Notably electromobility is seen as driver of energy transition progress, growing the sales of electric vehicles (EV) to a global EV fleet 20 times bigger than today.

However, a comprehensive set of cross-cutting, structural policies covering all technological avenues and just transition objectives is needed to achieve the necessary deployment levels by 2030. Increasing ambition in the National Determined Contributions (NDC) and national energy plans under the Glasgow Climate Pact must provide certainty and guide investment strategies in line with 1.5°C.

Particularly the world’s largest energy consumers and carbon emitters from the G20 and G7 must show leadership and implement ambitious plans and investments domestically and abroad. They would need to support the global supply of 65% renewables in power generation by 2030. Climate finance, knowledge transfer and assistance would have to increase for an inclusive and equal world.

Finally, enabling a rapid transition that complies with climate and development goals requires political commitment to support the highest level of international cooperation. Achieving sustainable development goals and universal access to modern energy by 2030 must remain a vital pillar of a just and inclusive energy transition, the outlook emphasizes. A holistic global policy framework can bring countries together to enable international flow of finance, capacity and technologies.

Read IRENA’s World Energy Transitions Outlook 2022 here.

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Assembly Solar I

The Assembly II and Assembly III solar projects have reached commercial operation (COD), states D. E. Shaw Renewable Investments (DESRI) in partnership with Ranger Power, a Chicago-based utility-scale solar development company and the largest independent solar developer in Michigan.

Assembly Solar II is a 110 MW AC solar facility and Assembly Solar III is a 79 MW AC solar facility, both of which are located in Shiawassee County, Mich. The Assembly II project reached commercial operation in December 2021, while the Assembly III project reached commercial operation in March 2022.

“We are very pleased to reach COD at Assembly II and III and to continue to invest in cost-effective clean energy in Michigan,” says David Zwillinger, CEO of DESRI. “It was a pleasure to work with all of our business partners including our offtakers, lenders, tax equity investors and development partners at Ranger Power.”

“DESRI is thrilled to see Assembly II and III come online; these two solar projects have brought new construction jobs to Shiawassee County and have marked important contributions to DESRI’s portfolio in Michigan,” adds Chris Clevenger, COO of DESRI. “We appreciate the efforts of McCarthy and our other contracting partners for a smooth construction process.”

Assembly Solar II has two 25-year power purchase agreements (PPA) for a total of 110 MW AC with Michigan Public Power Agency (MPPA) and its largest member, Lansing Board of Water & Light (BWL). These PPAs are incremental to the two 25-year PPAs for 50 MW AC MPPA and BWL executed with Assembly Solar I that reached COD in 2020.

“It’s important that our solar projects are a win-win for communities, and we’re proud that the Assembly Solar Project will contribute to the economic growth of Shiawassee County and the region,” states Paul Harris, president of Ranger Power. “During the construction phase of Assembly II and III, our partners at McCarthy hired nearly 400 local workers – from entry-level laborers to journeyman electricians and their excellent work on this project will generate clean, renewable energy for decades to come.”

“The BWL is committed to being the cleanest utility in the State of Michigan by continuing to grow our renewable portfolio and invest in cleaner energy options,” comments Dick Peffley, general manager of Lansing Board of Water & Light. “This project allows us to continue providing our customers the clean energy they demand.”

“Public Power is thrilled to make this commitment to the residents and businesses we serve throughout the state of Michigan,” mentions Patrick Bowland, CEO of Michigan Public Power Agency.

Assembly Solar III has a 25-year PPA with DTE Energy. The facility is expected to generate enough clean energy to power approximately 15,800 homes each year, according to metrics provided by the Environmental Protection Agency.

“DTE Energy is excited to be part of Assembly Solar,” said Brian Calka, director of renewable solutions for DTE Energy. “We now have more than 50,000 residential customers, 460 business customers and 36 industrial customers enrolled in our MIGreenPower voluntary renewable energy program. Our participation in Assembly Solar will help us meet clean energy commitments from these customers.”

McCarthy Building Companies served as the engineering, procurement and construction contractor (EPC) for both phases. In addition, Novasource Power Services will provide ongoing operations and maintenance services.

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Electric vehicles, stationary battery energy storage systems (BESS) and consumer electronics will push India into huge demand for batteries in the coming years. Image: Manz AG.

India will not be able to meet its aim of becoming a global leader in battery manufacturing unless it establishes a value chain that embraces recycling and proper end-of-life treatment as well.

A new report from environmental think tank Rocky Mountain Institute India (RMI India) highlights the need, opportunities and challenges for creating a sustainable battery manufacturing industry in the country.

It has been published a few days after India’s government announced the award of funding under its Production Linked Incentive scheme (PLI) for manufacturers of advanced chemistry cell (ACC) batteries to build 50GWh of annual production capacity in the country. Four different manufacturers’ gigafactory proposals were selected, including renewable energy company Reliance New Energy Solar, of Reliance Industries.

RMI India, together with Indian government technology and innovation think tank NITI Aayog published a previous report together in the same series, which explained the drivers for creation of a domestic battery making industry. 

That report, out in February, identified demand for batteries across India could reach between 106GWh and 260GWh by 2030 from all sectors including transport, energy and consumer electronics.

With India targeting 500GW new renewable energy capacity additions by that date, the need for stationary energy storage is likely to be a significant source of demand, albeit the majority will be accounted for by electric vehicles (EVs). India’s Central Electricity Authority has modelled the need for about 27GW/108GWh of stationary storage to integrate that mostly wind and solar capacity.

India could see fastest growth in demand

The sustainability report highlights that as well as ethical and environmental concerns over battery supply chains, there will also be scarcity issues for materials like lithium, cobalt and nickel. 

This is already happening worldwide, with one US-based expert having told Energy-Storage.news that supply chain issues are reaching a “crisis point” today, largely based on soaring lithium carbonate prices. 

RMI India quoted BloombergNEF research, which identified India as the region with the most expected demand growth for lithium-ion batteries from 2020 to 2030, even above bigger markets in China, the US and Europe. However, while India has ample reserves of magnesium and iron, it has minimal and insufficient reserves domestically of other key materials like lithium, graphite, cobalt and nickel. 

The country’s first lithium deposit was discovered in early 2021 and even with the other resource challenges, RMI India found that India will need to grow its domestic manufacturing capability to meet its storage needs and minimise energy security risks posed by being overly reliant on imported fossil fuels. 

Because of this, in order for India’s push to create a domestic battery manufacturing industry to succeed, circular economy principles need to be implemented, RMI India said. 

Recycled materials could meet more than 20% of India’s lithium-ion battery needs by 2030, if there is accelerated uptake of electric vehicles in the years leading to then, while even in a base case EV adoption scenario, around 5% of the essential minerals like lithium, nickel and cobalt used in India-made batteries could come from recycled materials.

Efficiencies for commercial recycling of lithium batteries are already very high at around 95% or even more, but the supply chain and circular economy strategies are not widely in place. Obtaining recycled minerals could potentially also be a lower carbon process than extracting them new.

Second life battery storage — BESS made with repurposed electric vehicle batteries — could also be a good way to reduce the cost of batteries, which usually make up about 40% of the total cost of a battery energy storage system. 

Reusing larger battery packs from e-buses as well as from passenger and commercial vehicles could provide for about 5% of the required BESS capacity India needs by 2030.

135% annual increase in recycling capacity needed to meet targets

India’s Ministry of Environment, Forest and Climate Change (MOEFCC) introduced draft rules for management of battery waste in 2020, having identified that existing management and handling policy was inadequate for the expected huge volumes of batteries to come by the end of this decade. 

The rules would apply to all kinds of batteries and call for collection of 30% of all end-of-life batteries by weight within two years of the policies being introduced, with the target increasing to 70% in the seventh year after implementation. 

RMI India said that meant if the 30% target were to be enacted in 2023, that would represent between 20,000 and 102,000 tonnes — or between 2.4GWh and 11.7GWh — of batteries being collected.

India’s annual recycling capacity would need to grow by at least 135% each year from 2021 to 2030 to succeed — a “substantial build out” of capacity — even in the think tank’s base case scenario for EV adoption.

Europe is currently seeking to adopt rules of its own on battery sustainability and supply chain security, mandating a gradual introduction of recycled content and carbon footprint labelling over a number of years. The European Union’s Battery Directive is at the stage of being negotiated with individual Member States to take its final form. 

While the EU’s Battery Directive has been broadly welcomed by the industry for its intent, some groups have expressed concern that over-regulation could risk hampering the continent’s international competitiveness. 

The MOEFCC rules could reduce upstream battery production emissions by 50,000 to 180,000 tonnes by 2030. RMI India acknowledged the importance of the policy, but made several recommendations for bettering the draft rules:

Labelling and transport: the draft rules lack clear guidance on labelling for lithium batteries of various kinds, which could result in lithium battery and lead-acid battery waste becoming commingled. This could present a health and safety threat and standardised labels should be decided. 

Battery reuse: the draft rules only contain rules on battery collection, not reuse, and also mandate that collected items should go to designated recyclers. This does not afford room for EV batteries, many of which will often still be usable for stationary storage after a period of use for transport, to be given a second life. Meanwhile there are no standards or certifications for safe use of second life batteries, which should be introduced.

Performance standards and warranties: similarly, there is a lack of a transparent system for assessing used battery health or warranties ensuring performance standards for second life batteries, as there are for new systems. The industry should be able to make the choice of using second life batteries safety, RMI India said. 

Ways to pay for recycling efforts need to be determined that are fair and do not affect the competitiveness of the EV industry against internal combustion engine (ICE) vehicles by passing on costs. 

Consumers should be incentivised to comply with battery rules: for example, rebates for returned batteries or deposit systems. 

Enforcement: the rules need to be enforced and penalties applied when they are broken, but through a transparent and fair system. 

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CLOU Electronics’ energy storage system container. Image: CLOU Electronics.

Listed company Shenzhen CLOU Electronics says it has secured a contract with a “famous American energy company” to supply an energy storage system totalling 485MWh in South America.

It did not reveal the buyer or precise location but said that the project consists of 168 sets of its 20-feet energy storage container solution. It will be a 1500V system compliant with UL 9540A.

It said the American energy company has over 2,000 engineers working in power generation, energy storage systems and digital energy solutions and supplies solutions worldwide. CLOU became a qualified supplier to the company in 2021.

The two have already partnered before with agreements to supply a 3MWh system in December 2021 and a 69MWh one in January 2022, both in the US, the company added.

The company’s share price on the Shenzen Stock Exchange opened 10% higher on Monday, March 28, the first day of trading after the South America project announcement on Saturday.

The announcement was made by its CLOU Global segment which calls itself a ‘Comprehensive Energy Services Provider’ and says its product portfolio includes storage, electric meters and their accompanying infrastructure including testing equipment, enclosures and data acquisition solutions.

CLOU also has a separate website, CLOU Energy Solutions, which says the company has supplied utility-scale energy storage solutions across the US, as well as Costa Rica, Cabo Verde and Haifeng in China. It also details commercial & industrial site deliveries in China and microgrid solutions provided across Asia and one in Rwanda.

South America has not had a great deal of utility-scale deployments of energy storage to-date. This project from CLOU represents by far one of the largest ever to have been announced on the continent.

US-based energy infrastructure group AES Corporation’s Chile arm AES Andes started building a 112MW/560MWh battery energy storage system (BESS) in November 2020 and a year later announced plans to increase the country’s storage capacity to 300MW by 2023 in partnership with the government.

Much of South America’s other big news in storage has been in Chile too. Late last year, Statkraft announced it had won a tender in Chile to develop wind farms with up to 1GWh of BESS attached shortly before global system integrator Wärtsilä won its first battery project on the continent there.

The Chilean government is also set to launch a power auction later this contracting 5,250GWh/year for 15 years, which will involve storage paired with renewables.

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SDG&E’s 30MW lithium-ion BESS at Escondido, the largest in the world when it launched in 2017. Image: SDG&E.

Investor-owned utility SDG&E is turning its first lithium iron phosphate-based battery energy storage system (BESS) online today, while Stanford university says it has hit 100% renewable electricity with the offtake from Goldman Sachs’ recently-commissioned Slate solar-plus-storage project.

SDG&E adds first LFP BESS to grid

San Diego Gas & Electric (SDG&E) will today (29 March) cut the ribbon on the Kearny Energy Storage in north San Diego. The 20MW/80MWh BESS is the first energy storage project by the utility to use lithium iron phosphate (LFP) chemistry-based batteries.

The BESS is the latest in SDG&E’s pipeline which will bring its total storage portfolio to 145MW by the end of 2022. It recently ordered a six-hour BESS solution for one of its sites from Mitsubishi Power.

Its BESS projects are in response to the various mandates by the California Public Utilities Commission (CPUC) to procure more energy storage to mitigate the risk of near-term capacity shortages and help the state’s transition to a zero-emissions grid by 2045.

Seth Hilton, partner in the Energy Development practice of law firm Stoel Rives, told Energy-storage.news that very few projects will meet their deadlines of 2023 and 2024 due to interconnection issues on the California ISO grid and wider supply chain issues.

“I think a lot of energy is being focused on that very near-term procurement, but there’s a lot of difficulty in terms of there just not being enough projects to kind of meet some of that need and what you see now is projects getting shortlisted for multiple load-serving entities’ procurement,” he added.

California has three large investor-owned utilities. SDG&E andSouthern California Edison (SCE) have opted for owning their own BESS projects while the third Pacific Gas & Electric (PG&E) has tended to procure power from sites owned by other developers.

The direct ownership approach has, however, proved slightly controversial amongst independent developers according to a Hilton.

“So, SCE originally took the path of: “we’re going to develop our own projects,” primarily because of interconnection issues. So the deal with Ameresco (2.1GWh) was a way of getting around the interconnection issues,” he told Energy-storage.news.

“And there were some significant developer concerns about the fact that SCE was in a position where they could get around interconnection issues, and developers aren’t in a similar situation and how that should be appropriately handled. There were a lot of protests of what SCE was doing in terms of that Ameresco agreement.”

Stanford University’s offtake from Goldman Sachs project enables 100% renewable electricity transition

Stanford University has revealed that the 63MW of offtake it secured from the Slate solar-plus-storage project in Kings County, California, has completed its transition to 100% renewable electricity.

The project was completed and turned online by owner investment bank Goldman Sachs earlier this month. It comprises 300MW of solar PV paired with a 140MW/561MWh BESS and was bought by Goldman Sachs Renewable Power from Canadian Solar subsidiary Recurrent Energy just before construction started in January 2021.

“As this new solar plant comes online, Stanford will achieve the important milestone of producing enough renewable electricity to exceed what the university consumes,” said President Marc Tessier-Lavigne.

Stanford’s portion of Slate, the Stanford Solar Generating Station #2 (SSGS2), is its second major solar power site after the Stanford Solar Generating Station #1 in Rosamond, California, came online in 2016. The year before, the university campus was entirely powered by natural gas.

The university still needs to electrify its campus vehicle fleet, hospital water heating systems, its natural gas and steam appliances and its heating systems to achieve 100% renewable energy.

The other offtakers of the Slate project’s power are the San Francisco rapid transit system operator Bay Area Rapid Transit, electric utility Power and Water Resources Pooling Authority, and Community Choice Aggregators (CCAs) Silicon Valley Clean Energy and Central Coast Community Energy (formerly Monterey Bay Community Power).

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Clients HMS has worked with include Connected Energy, which creates stationary storage systems using second life EV batteries. Image: Connected Energy / Umicore.

Energy-Storage.news proudly presents this sponsored webinar with HMS Networks, looking at technologies and methods to bring all of the different elements together safely to ensure device protection at every step and intelligently connect battery energy storage systems (BESS) to the grid.

Today’s BESS often combine a variety of different devices, from different industries, within a single application. Flexibility in the selection of components and the resulting modular approach makes the whole system future-proof, flexible, and secures investment. Operational costs can be minimised and dependency on specific components or suppliers can be avoided.

This webinar looks at topics including:

– An overview of all aspects of networking in BESS applications

– How to use cost-effective and proven products from other industries in your BESS application

– What you need to consider when networking components inside your BESS application and into smart-grid environments

– Specific topology and protection requirements in CAN based networks

– How to bring data to the cloud and enable SCADA and Smart Grid applications

– Enabling remote data access to all system and device levels, while considering cybersecurity requirements

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You can also register to view the on-demand version and download presentation slides here.

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