Eddie Obropta

A new analysis from solar lifecycle management software provider Raptor Maps has found that PV system anomalies affected the performance of 2.63% of the 20 GW of solar power output studied – up from 1.85% in 2020.

Using machine learning to analyze data from unmanned and manned aircraft inspections across 20 GW of utility and C&I systems, Raptor Maps’ fourth annual report on system underperformance spans 66 million modules in 32 countries. Classifications in the report span functional units including off-nominal inverters, environmental conditions (including overgrown vegetation) and module or sub-module findings (including activated bypass diodes). 

The data suggest that the increase in affected performance from 2018 to 2021 was driven by string, inverter, combiner, module and tracker anomalies.

“Our inspection data shows that solar assets are becoming more anomalous each year,” explains Eddie Obropta, CTO and co-founder of Raptor Maps. “These findings – against the backdrop of increased costs of capital and supply chains – underscore the need to use advanced technology to maximize power output. Operational excellence is no longer enough. Solar financiers, asset owners and asset managers must leverage data and analytics to make intelligent decisions that reduce soft costs.”

Raptor Maps’ report finds that companies sought more in-depth inspections data in 2021. The percentage of drone inspections that were “Comprehensive” – the most granular inspection level – increased from 21% in 2020 to 24% in 2021.

Increasingly more parties are also accessing PV inspection data, according to Raptor Maps. Inspection data owners shared findings with an average of 27 additional users in 2021 – indicating increased communication and collaboration.

Aerial inspections are used across all phases of the solar lifecycle. Asset owners and EPC firms require inspections during commissioning to de-risk assets, remediate issues, create a quantitative baseline and avoid liquidated damages. O&M companies integrate aerial inspections into annual preventative maintenance. Counterparties such as module manufacturers, engineers, financiers and others use aerial inspections for warranty claims, insurance claims, project benchmarks, due diligence and more.

The Raptor Maps report is available for download here.

Continue reading

Small-scale battery storage pilot for Michigan utility Consumers Energy. Image: Consumers Energy.

Michigan should target 2,500MW of energy storage deployments by 2030, a new report funded by the US state’s Department of Environment, Great Lakes and Energy (EGLE) has recommended. 

That would enable the retirements of fossil fuel plants, enable investments in renewable energy planned by its utilities and make Michigan the 10th US state to adopt a formal deployment target or aspirational goal, according to the ‘Energy Storage Roadmap for Michigan’, published today. 

The roadmap was produced by the Institute for Energy Innovation with partners the Michigan Energy Innovation Business Council, consulting firm 5 Lakes Energy and Annick Anctil, a professor at Michigan State University.

The partners responded to an EGLE solicitation issued in 2020 to create the document, which the state government said should be used “to determine energy storage potential in Michigan and develop recommendations to inform investment and policies regarding energy storage”.

Multiple benefits of energy storage in decarbonisation drive

In September 2020, Governor Gretchen Witmer issued an Executive Directive which set the state a goal of economy-wide carbon neutrality by 2050, with an interim goal to reduce greenhouse gases (GHGs) to less than 28% of 2005 levels, by 2025. 

This followed commitments to net zero carbon emissions by major Michigan utilities DTE Energy and Consumers Energy, set in 2019 and earlier in 2020 respectively. According to the US Energy Information Administration (EIA) however, in 2020, only 11% of Michigan’s total in-state generated electricity came from renewables, mostly from wind.

At least 7GW more solar and wind are expected to be installed by 2040 according to commitments by DTE Energy and Consumers Energy, bringing the state’s renewable capacity to more than 10GW. 

Meanwhile the Midcontinent Independent System Operator (MISO) grid that spans 11 US states including Michigan has some of the lowest shares of renewable energy but among the highest levels of curtailment in the country already.

The issue of the EGLE request for proposals (RfP) for a roadmap followed the finding of consensus across electricity system stakeholders that energy storage offered multiple benefits to the network and for consumers, at a hearing held by the regulatory Michigan Public Service Commission (MPSC) in August 2021. 

As reported by Energy-Storage.news at the time, Consumers Energy, DTE, commission staff, trade group Advanced Energy Economy and others offered their input and the two utilities were ordered to carry out small pilot projects to test energy storage technologies against multiple use cases. 

4000MW/16,000MWh by 2040

The roadmap authors noted that Michigan was one of many US states in which policies still lag behind industry trends around the fast development of energy storage, which enables the increasing use of renewable energy and electrification of buildings and transport, as well as bi-directional flows of power on the grid. 

Modelling the impact of both behind-the-meter (BTM) customer-sited energy storage and front-of-the-meter (FTM) utility-scale storage, the authors recommended that the state set a short-term target for 1,000MW of FTM energy storage by 2025. 

By 2030, that need is expected to grow to 2,500MW of FTM storage and 4,000MW by 2040, if the state is to avoid curtailment of renewable energy generation and maintain reliability of the electric grid, the roadmap said. 

The study was modelled around the costs of four-hour duration energy storage systems, meaning that in capacity terms, that would be 16,000MWh of storage by 2040. 

The roadmap also recommended that a ‘value of storage’ study should now be conducted to quantify the benefits of energy storage. 

The state government should also undertake a number of measures, including installing BTM storage at public buildings to “lead by example,” figure out how to employ enough people for the energy storage sector and provide financing through Michigan’s energy efficiency and renewable energy revolving loan fund.

Regulators meanwhile should start requiring utilities to include accurate evaluations of the energy storage opportunities in their service area and how they could meet storage targets, if established. The regulatory Michigan Public Service Commission (MPSC) should also require utilities to conduct competitive energy storage procurements with a level playing field for third-part ownership models. 

Other recommendations for regulators included requiring utilities to produce maps of publicly available hosting capacity for energy storage which developers could use in their decision-making and to support the implementation of FERC Order 841 and Order 2222, which order regional transmission operators (RTOs) and independent system operators (ISOs) to enable energy storage to participate in wholesale electricity markets. 

See the full roadmap here.

Continue reading

Nyrstar’s zinc smelting plant in Balen where the battery storage system will be. Image: Nyrstar / Nala Renewables.

Construction has started on what will be the largest battery storage project in Belgium at 25MW/100MWh when completed later this year.

Nala Renewables’ lithium-ion battery energy storage system (BESS) will come online at metals conglomerate Nyrstar’s zinc smelting operation in Balen, in Belgium’s Flemish region, by the end of 2022.

Nala Renewables is a joint venture (JV) between commodity trader Trafigura and IFM Investors and is investing €30 million (US$33 million) in the Balen project. The local Flemish government is also providing €1m of Strategic Ecology Support funding.

“The international energy crisis and Russia’s invasion of neighbouring Ukraine make it clearer than ever that we need to invest heavily in clean energy production close to home in order to reduce our dependence on foreign countries. Unfortunately, renewable energy is not available every minute of the day, so it is crucial to provide for its storage,” said Zuhal Demir, Flemish Flemish Minister of Energy and Environment who attended the project’s construction launch ceremony.

The Balen site will provide grid-balancing and stability-enhancing services to Belgium’s grid in addition to shifting renewable energy production to peak demand periods. It recently scored a win in Belgium’s capacity auction held by grid operator ELIA, one of four BESS projects to do so.

It is the joint-largest battery storage project in Belgium under development along with with one in Ruien being developed by a Japanese-Belgian JV, which also won in ELIA’s auction.

Nala Renewables aims to have 4GW of of renewable energy projects “operating, in construction, or in late-stage development by 2025,” it says. It has doubled its target from one year ago.

Nyrstar is a portfolio company of Trafigura and the companies have said Nala will build and operate projects adjacent to Trafigura’s mining, port and smelting infrastructure projects.

Battery storage projects in Belgium have taken off quicker than in the rest of mainland Europe thanks to more storage-friendly market rules. The market has some strong drivers for storage including a lack of grid flexibility and good interconnection with other markets.

Continue reading

Part of France’s largest BESS to date, supplied by Saft for its parent company TotalEnergies. Image: TotalEnergies.

Close to 900MW of publicly announced battery storage projects will be online in continental France by the end of next year and although the country lags behind its nearest northern neighbour, the business case for battery storage is growing. 

As shown by the work of our colleagues at Solar Media Market Research, the UK has roughly 1.5GW of large-scale battery storage. Its market has grown rapidly: before a 200MW tender for grid services held by transmission system operator (TSO) National Grid in 2016, the UK had almost nothing.  

Now that the ability to stack revenues from multiple streams including ancillary services, arbitrage and the Balancing Mechanism and Capacity Market structures have propelled the UK into something of a leading position among regional markets.

A similar, but different, energy storage market revolution seems imminent in France. We speak with Corentin Baschet, analyst at energy storage consultancy Clean Horizon, on why that is. 

Firstly, we should make the distinction between continental France and its various island territories. There is quite a lot renewables-plus-storage on French islands like Guadeloupe and Martinique, from dispatchable renewable energy tenders. 

Those represent a small but significant recurring market of course, but within mainland European French borders, there were just a couple of megawatts of commercial installations as recently as 2019, Baschet says. That grew within the past three years to about 300MW.

From tallying figures from publicly announced projects, Clean Horizon has identified that adding together already operational systems along with those announced, or in construction to be completed by 2023 year-end, brings the market to almost 900MW.

Image: Clean Horizon Consulting.

This is all the more encouraging because unlike the UK, there are only two revenue streams available for battery storage assets in France today.

One is long-term contracted revenues from the capacity market — France held a dedicated low carbon capacity market auction in 2019, awarding seven-year contracts to winning bidders for 235MW of storage, announced the following year.

The other is frequency control reserve (FCR), aka primary control reserve (PCR), what could be seen as the first rung of the ancillary services ladder. Assets in FCR react to short-term frequency imbalances on the grid within 30 seconds of receiving a grid signal and able to cover up to 15 minutes per incident.

A third revenue stream, automated frequency restoration reserve (aFRR), aka secondary reserve, is expected to open in near future. It had been due to open in November and in fact auctions had begun, but was halted due to the European electricity crisis, which sent prices spiralling upwards. 

“The resulting prices were so high that the regulator has asked for the transmission system operator RTE to stop the auction, because it was resulting in too expensive prices,” Baschet says. 

“Essentially RTE was paying €155 per megawatt per hour for secondary reserve and procuring about 750MW every single day. That means that we’re talking about millions spent every single day for secondary reserve.”

Previously, the regulated secondary reserve market gave large generators a mandate to provide the grid service at a price defined by the regulator, around €19/MW/hr. Instead, RTE was paying €155 x 24 hours x 750MW = €2.79 million every day, about 10x more than it had been paying under the regulated structure. 

“Electricity prices were going through the roof at the same time, and our government was trying to limit the impact of electricity prices,” Baschet says and along with reducing taxes on electricity and locking in prices for end customers, the temporary stop was called to the aFRR auctions.

It is however, tentatively expected to go live once again in July this year. A temporary setback, says Baschet, which hadn’t yet really impacted battery storage — the auctions were so new, no batteries had had time to pre-qualify to participate. However, plenty of battery developers are interested in the potential revenues. 

Baschet recently told Energy-Storage.news that battery storage could capture about a third of the opportunity for aFRR across the interconnected European market by 2025.

Unexpected leaders with a ‘peculiar’ business model

Energy-Storage.news reported a while back on the completion of an expansion at continental France’s largest battery energy storage system (BESS) project. BESS capacity at the TotalEnergies refinery site in Dunkirk, northern France, is now 61MW/61MWh over two phases, with the most recent 36MW/36MWh addition completed shortly before the end of 2021. 

The energy major has 103MW of capacity market contracted energy storage online or coming online in France. Interestingly however, despite presiding over the single biggest project in the country, TotalEnergies sits second in Clean Horizon’s chart of France’s most prolific (publicly announced) battery storage project owners and developers.  

The leading player is NW Storage, a subsidiary of renewable energy company NW Group and Corentin Baschet points out that the company’s business model is “very peculiar”. 

“What they do is that they develop 1MW projects — and they make a lot of them — because they’re planning to have more than 300 built by end of year in continental France.”

Whereas in neighbouring Britain it seems like the average BESS project is closer to 100MW than 1MW today, the business model appears to be to build a lot of smaller assets and then sweat them as much as possible. 

NW Storage is a small company but has gone in hard into the energy storage market, Baschet says, and in a leading position despite building only small sites, based on its own modular, plug n play energy storage system solution and often coupled with EV charging. 

Pros include the ability to quickly replicate projects from site to site, whereas the downside may be that NW Storage needs to find a lot of sites. But with FCR revenues averaging out at €17.8/MW/hr across 2021, the business case appears to be working.

‘Favourable economics’ but long-term risks to market

“At the moment, it’s very favourable,” says the Clean Horizon analyst, on the economics of battery storage in grid-connected France.

Adding together per-megawatt numbers for typical revenues earned from FCR and capacity market payments of roughly €20,000 per megawatt, close to €170,000 could have been earned last year for each megawatt at a one-hour duration battery storage asset.

Clean Horizon has modelled that in Europe a one-hour duration battery storage system needs to earn about €70,000/MW/yr. In other words, assets made a lot more last year than had been expected by their developers and owners.

On the other hand however, there is still a high market risk long-term. That €170,000 per year is unlikely to remain and earning at least €70,000 each year for the whole 10-15 year lifetime of a battery project is likely to be essential. 

“There’s a risk that these revenues shrink in the future, as more and more batteries get deployed. The French market depth for frequency regulation is 500MW. We can actually export some of this capacity, so 500MW is the need in France for FCR; we can export 150MW,” Baschet says.

“So it could be that there’s room for 650MW of batteries providing FCR in France, but once this threshold is reached, we’ll need to find other applications for storage. So hopefully secondary reserve will be open by then.”

Grid operator to launch tenders

Transmission operator RTE has already engaged in some trial activities through which storage is being deployed in continental France.

One is Project Ringo, which gauges the effectiveness of energy storage as a virtual transmission asset. Three energy storage systems totalling 32MW, including two-hour and three-hour duration batteries, act as absorbers of surplus renewable energy on the grid.

The other is a flexibility tender: RTE sought options in four strategic locations where surplus renewable generation and growth in load from EV uptake is causing grid congestion at substations.

At two of those locations, battery storage could be a good fit. However, due to their need to deal with a congested grid first and foremost, it may be difficult to stack revenues from other services for batteries in the technology agnostic tender. 

RTE owns and operates assets participating in Project Ringo, but is contracting with developers of projects for flexibility. Project Ringo allowed RTE to experiment with investments into energy storage that it could really dive into and see how the technology works. 

What this means longer term is that RTE is expected to use those projects and other findings as the basis for creating storage-dedicated tenders, Baschet says, as enabled by a change in law last year.

These could be for any need RTE can identify for storage on its grid. 

“So for now we don’t know what [services RTE will tender for]. It could be anything, but they have the capability of having this storage tender now. It is not any more a flexibility tender to deal with congestion [in which storage can take part], it is really a storage tender. A bit like there was in the long-term capacity market auction, which was really well designed for batteries.”

Another of France’s European neighbours, Belgium, is seeing its market open up for energy storage investment even more quickly and what is striking is the duration of projects. Four-hour duration battery projects are on the way from a number of players.

That is due, Baschet says, to Belgium already introducing its local version of the new pan-European aFRR secondary reserve market — which requires more energy than FCR — as well as better opportunities to do energy trading, and a higher-paid capacity market opportunity. 

In France, projects in construction and on the way nearly all remain one-hour, due to the business case for FCR’s shorter discharge requirements. Once aFRR is introduced, some BESS projects with two hours will likely be seen. 

However, uncertainty comes from the current supply chain and commodity pricing crunch, especially on lithium carbonate and other battery raw materials. The industry has seen pricing declines slow down before, but it isn’t used to seeing battery prices go up. 

“That has adversely impacted a lot of storage projects, which, for instance, were close to making an investment decision and had feedback from system integrators that the price had increased by up to 20% on the DC system part,” Baschet says.

“It’s been increasing the decision time and making the decision-making process more complex, with price variation and raw material impacting the integrators to the vendors and the buyers, because it’s difficult to make investment decisions on a price which is changing every other day.”

Continue reading

Another Solar Alliance solar project in New Market, Tenn.

Solar Alliance Energy Inc. has commenced construction on a 500 kW solar project in Kentucky for Louisville Gas and Electric Co. (LG&E) and Kentucky Utilities Co. (KU), regulated utilities that serve more than 1.3 million customers.

The project represents section five of LG&E and KU’s Solar Share Program, a cost-effective option available to the utilities’ residential, business and industrial customers who want to support solar energy for as little as 20 cents per day.

“Our portfolio of tools and programs, like Solar Share, make it possible for customers to support renewable energy sources right here in Kentucky and the region,” said Eileen Saunders, vice president of customer services for LG&E and KU. “We’re providing information in near-real time, simplifying the processes and partnering with customers who are interested in finding cost-effective solutions to achieve their sustainability goals.”

The contract includes an option for LG&E and KU to select Solar Alliance to build an additional 500 kW system at the same location. A total of eight 500 kW Solar Share sections are planned for the Simpsonville facility, for a total of four MW. Under the terms of the contract, the identity of the customer was confidential until the commencement of construction.

“Solar Alliance is proud to be building another large solar project in Kentucky for this utility partner,” comments Solar Alliance CEO Myke Clark. “Our contracted pipeline of large solar projects is growing, and this is the latest example of the type of project we are consistently delivering for our customers.”

Continue reading

SVOLT’s energy storage system (ESS) solution. Image: SVOLT.

Lithium-ion battery producer SVOLT has announced an LFP-based energy storage system (ESS) solution having until now predominantly focused on battery cells for the electric vehicle (EV) market.

The Jiangsu-headquartered company with a presence in Europe says its Energy Storage Units (ESU) are now available and use lithium iron phosphate (LFP) technology.

It says its CE-Series ESU is a “highly modular and standardised energy storage solution” which can help with renewable energy integration, dynamic capacity expansion, demand-side energy management, distributed power generation, emergency power supply and fast charging of electric vehicles.

The solution has cells with 280 Ah and 3.2 V, it adds, and it has medium-scale systems available which boast advanced thermal management and fire protection mechanisms. The company also has a ‘cloud-based big data service platform for regional energy supply’ available.

“From 2023, modular liquid-cooled ESS components will then be launched on the market. In the same year, SVOLT also plans to offer accompanying Smart Energy Professional Services,” the press release said.

SVOLT is a spinout from Chinese sports and truck vehicle manufacturer Great Wall Motors. It has to-date mainly announced deals with the automative sector, including its former parent company.

It is the most recent example of a vertically integrated battery manufacturer adding BESS products to its range and thus becoming a direct competitor to system integrators like Fluence, Wartsila and Tesla. Others to have done this include BYD, LG Energy Solution, CATL and Samsung SDI.

SVOLT was the second-most funded battery storage company in the world last year after Swedish group Northvolt, according to Mercom. It raised US$2.6 billion over two fundraising rounds.

It has new gigafactories planned in Germany, India and China. It is says it is investing €2 billion (US$2.19 million) into its Saarland, Germany, site. Some two dozen companies are building lithium-ion gigafactories in Europe.

Continue reading

Connected Energy’s project for Umicore in Belgium, repurposing Renault Kangoo batteries as a frequency regulating grid asset. Image: Connected Energy / Umicore.

Following a recent announcement by carmaker Toyota that it will be exploring how to make batteries easier to recycle, more attention should also be paid to giving used EV batteries a ‘second life,’ argues Matthew Lumsden, CEO of Connected Energy. 

Toyota recently announced a bold plan to develop ‘green batteries’ – batteries that are low carbon, low in cost, and easy to recycle. 

Some ‘simple’ changes at the design stage of batteries could add significantly to their ‘reusability’ before end of life. 

It is our assessment that up to 30% of vehicle batteries can be re-used in second life energy storage systems. Second life applications must become ubiquitous across the world if an unacceptable waste of resources through premature end of life battery recycling is to be avoided. Vehicle manufacturers can help this to happen.

In China, second life use is translated as “cadence”, “gradient”, or “ladder” use, and this ladder analogy is a great way to think about the life of a battery, by considering if each step in the life cycle has been made to work with the next. Vehicle batteries are broadly speaking rectangular metal containers. But they vary and this variation can add difficulty and complication to the second life use. 

Connected Energy is the only company in the UK to use second life batteries in a practical way, supplying energy storage systems to Europe and the UK made from second life car and van batteries. 

Stacked together in bespoke containers we utilise our control systems so that the batteries are used exactly as they are in vehicles, this approach capitalises on all the R&D and safety systems invested in them by OEMs. This process could be made dramatically easier and universally considered with a few ‘simple’ design changes.

Committing to second life

A first basic would be to ensure that batteries are regular cuboids and stackable. Removing odd shapes or additional sections that protrude sounds simple, but would no doubt have some complications. However, these need to be designed out. Adding fixing holes and channelling into the external casing of the batteries could transform the ease with which they can be cost effectively installed and connected once outside a vehicle. 

To incorporate these simple yet highly effective changes into battery design, however, requires a real commitment to second life use whilst designing for the first life. 

Over its lifetime in operation, a second life BESS can save an additional 450 tonnes per MWh of CO2 equivalent compared to using first life batteries so we must ensure the use of second life batteries in energy storage systems. This will not just save carbon and use the embedded carbon better but reduce competition for raw materials. 

The world cannot afford all BESS to come from first life batteries so here’s the challenge: design for reuse as well as for recycling.

Batteries from Audi vehicles are used at this site in Germany, recently brought online by RWE. Image: RWE.

About the Author

Matthew Lumsden is CEO of Connected Energy, a UK-headquartered company working internationally to provide and enable second-life battery energy storage systems. The company’s E-STOR energy storage systems have been developed to enable thousands of batteries, with varied levels of degradation, to be aggregated, controlled and reused as one stationary energy storage system.

Continue reading

After six years of trying, a newly passed Indiana bill makes it more difficult for homeowners’ associations (HOA) to ban residents from putting solar panels to their homes, according to Sarah Bowman of Indianapolis Star.

With House Enrolled Act 1196, homeowners now have a process to petition their HOA boards if they wish to install solar panels and follow specific requirements. Gov. Eric Holcomb signed House Bill 1196 into law Thursday morning.

Senate co-sponsor Sen. Aaron Freeman, R-Indianapolis, proposed the legislation in 2017 and Rep. Mike Speedy, R-Indianapolis, joined as the House co-sponsor.

While a review Indianapolis Star did of HOAs found that many HOAs expressly prohibit all solar panels, the language in other associations’ bylaws is vague.

Read the full article here.

Image: Photo by Jeremy Bezanger on Unsplash

Continue reading

Sungrow’s ST2752UX liquid-cooled battery energy storage system, recently launched to the global market. Image: Sungrow.

Sungrow will supply a 16MW/64MWh battery energy storage system (BESS) to a customer in Israel, which will lower emissions and improve efficiency at one of the country’s biggest power plants. 

The energy storage division of the China-headquartered PV inverter manufacturer announced the deal with Israeli infrastructure solutions company Afcon yesterday. 

Sungrow will supply its newly-launched liquid cooled BESS unit for utility-scale applications, ST2752UX, together with the company’s SC5000UD-MV power conversion system (PCS), integrated in enclosures. Sungrow will also provide maintenance services for the battery equipment. 

It will be installed at the 912MW Dalia Power Station combined cycle gas turbine (CCGT) power plant, which is responsible for 8% of Israel’s entire electricity production. 

The batteries will improve efficiency and reduce the runtime of the plant’s turbines, allowing generators to be turned down quickly and improving the speed and flexibility of their response. 

Afcon’s EPC subsidiary is taking on the project for independent power producer (IPP) Dalia Power Energies, which owns and operates the gas plant. Afcon EPC Division is taking the lead on planning, procurement and execution as well as operations and maintenance (O&M) of the overall project. 

The deal announcement comes not long after Sungrow was awarded an even bigger project in Israel. The company said at the beginning of this year that it has been contracted to supply 430MWh of BESS by developer and IPP Enlight Renewable Energy. 

That project will be installed in two phases, the first of 230MWh and the second of 200MWh. 

Sungrow’s country manager for the UK and Ireland, Andy Lycett, spoke with Energy-Storage.news for an interview published this week on the technology trends the company is expecting to see in energy storage in 2022 and over the next few years to 2030. 

Lycett said liquid cooling thermal management of the type used in the ST2752UX model will be a prevalent technology and could begin to dominate the market this year.

“This is because liquid cooling enables cells to have a more uniform temperature throughout the system whilst using less input energy, stopping overheating, maintaining safety, minimising degradation and enabling higher performance,” Lycett said. 

Israel could need 8GWh of storage by 2030

Israel is targeting getting 30% of its electricity from renewable sources by 2030, equating to about 12GW of solar PV. Its national electricity authority, PUA, modelled an expectation of a required 2GW/8GWh of energy storage to reach that goal. 

PUA has made a start on deployments with two tenders held in 2020 for solar-plus-storage. The first saw 168MW of solar PV and 672MWh of battery storage contracts signed, the second 608.95MW of PV and more than 2,400MWh of storage. Prices in the second auction for four-hour batteries paired with solar came in at a clearing price of 17.45 Shekel cents per kilowatt-hour (US$0.0544/kWh at that time).

In a webinar hosted by Energy-Storage.news in November in partnership with energy storage expert consultancy Clean Horizon in November ahead of the second auction, PUA regulatory department head Yossi Sokoler said that the 8GWh figure was not a target as such, but the modelled amount the authority believed Israel needed to integrate that 30% share of renewables. 

Israel is likely to reach that figure well ahead of 2030, Clean Horizon CEO Michael Salomon commented. 

Continue reading

The utility has completed three new BESS projects. Image: Duke Energy.

US utility Duke Energy has announced the completion of three battery energy storage system (BESS) projects totalling around 34MW/58MWh in Florida.

The three lithium-ion systems are in the Gilchrist, Gulf and Highlands counties and will improve grid reliability and critical services in the event of an outage.

The largest of the three at 18MW will be located at Duke’s 45MW Lake Placid Solar Power Plant in Highlands while the smaller two are standalone sites of 11MW and 5.5MW at Trenton and Gulf respectively. It says the colocated battery will make Lake Placid’s energy dispatchable by its grid operators – Duke Energy Florida is responsible for managing the grid in the state.

The company did not reveal the durations of the battery systems in the press release, but a report provided by the company to Florida’s public service commission in April last year revealed the systems’ guaranteed energy storage for a minimum of 10 years.

It says that Lake Placid will have a storage capacity of 34MWh making it a roughly two-hour system; Gulf County will 14.3MWh of energy making it about two-and-a-half hours; while it implies Trenton’s duration will be just under an hour, with a capacity of 10.1MWh on power of 11MW.

It adds, in reference to these and three other BESS projects: “These projects may serve a variety of purposes including, but not limited to substation upgrade deferral, distribution line reconducting deferral, power reliability improvement, frequency regulation, Volt/VAR support, backup power, energy capture, and peak load shaving.”

A press release photo indicates the batteries at at least one site are being supplied by CATL, the largest lithium-ion battery producer in the world.

By the end of 2022, Duke Energy says the six projects in Florida will have a combined 50MW power. The other three are in Jennings (5.5MW/5.5MWh), Micanopy (8.25MW/11.7MWh), and a 1.5MW/2.5MW solar-plus-storage microgrid at a school in Pinellas County. The company has previously said that installing storage is an economic alternative to building out its distribution grid.

Florida has been slower than other states like California and Texas when it comes to adding energy to its grid. But it did recently unveil the largest BESS to be be paired with solar PV late last year.

Duke Energy also recently announced a partnership with technology group Honeywell to set up microgrids across the US.

Continue reading