The energy dynamic around renewables is changing so quickly in Colorado that Zach Pierce, a senior campaign representative for the Sierra Club, can hardly keep up with it. “I feel like we’re having to rewrite the talking points on the drawing board every month in Colorado,” he said.

In December, the state’s largest utility — Xcel Energy — released a short report summarizing the responses to the solicitation it had issued to power suppliers for bids to bring new sources of electricity to the grid. The utility received 430 bids, and 350 of those were for renewable energy projects.

That was remarkable on its own, but what surprised people even more were the bids for projects that added battery storage to the mix. They were cheaper than anyone expected.

“It’s a testament to how quickly the market is changing,” Pierce said.

Changing attitudes

For years, renewable energy advocates have pushed utilities and regulators to consider adding battery storage to their electrical generation portfolios for flexibility and to reduce intermittency problems that come with solar and wind. Until recently, it wasn’t considered a realistic option: Batteries were expensive and largely untested by utilities, and risk-averse regulators mostly let grid managers ignore them in their bids, statements and long-term planning documents.

Analysts say that’s starting to change as batteries come down in price, as momentum builds behind renewables and as renewables create a natural market for storage. Utilities increasingly look at batteries as a tool for leveling out power available over the course of the day and for replacing bulky and expensive peaking power plants that have high costs but only occasionally run at or near full capacity to meet peak demand (in the Southwest, this might be one hot day in the summer when everyone has their air conditioning turned up).

NEC Energy Solutions announced that they have completed and commissioned an energy storage system for Germany-based EnspireME, a joint venture between Eneco, a Netherlands-based renewable energy company and Mitsubishi Corp.

The 48 MW energy storage system located in Jardelund, Germany has over 50 MWh of storage capacity and will generate revenue from the primary reserve market by providing reactive power to stabilize the transmission grid.

NEC provided turnkey engineering, procurement and construction services which included its GSS end-to-end grid energy storage solution and its AEROS proprietary energy storage controls software to build the largest energy storage system in Europe. The 48 MW energy storage system built for Germany-based EnspireME, a joint venture between Eneco and Mitsubishi Corp., has over 50 MWh of storage capacity. The system will generate revenue from the primary reserve market by providing reactive power to stabilize the transmission grid.

Transmission system operators (TSOs) in Europe are required to secure a certain number of capacity reserves to prepare for sudden power loss or an extensive blackout. The storage capacity from the system will be sold to the German electricity market through weekly common auctions where European grid operators purchase the reserve capacity they require in the primary reserve control market to guarantee the 50 Hz (Hertz) frequency on the grid. The energy storage system can also take over the role of primary reserve provider and become a more sustainable alternative to coal and gas fired plants.

In addition, Eneco and Mitsubishi Corp. will investigate connecting the battery to local wind farms, providing further value for wind farm owners by storing excess electricity generated during periods of curtailment.

California is generating a ton of solar power–some days, more than people can use. It could power the whole state soon, except for one problem: There’s no way to hold on to all that energy at night.

Some of the country’s biggest energy companies are trying to figure out how to store the power. They’re buying giant lithium batteries, and imagining ways to tap the batteries in electric cars. But there’s another option.

Today on the show, we visit the world’s largest battery, built out of a mountain and a lake.

European Commission vice president for energy, Marcos Sefcovic has referred to an EU action plan for ‘green batteries’ to be made in Europe, citing the technology as vital for renewable energy integration as well as giving the continent a ‘competitive edge’.

At an industrial forum hosted at the Intersolar Europe conference centre in Munich on Thursday, Sefcovic was the invited guest of trade group Solar Power Europe, which hosted the event. His appearance followed opening remarks from SPE chief Christian Westermeier, who said that despite enormous progress and successes in the deployment of solar PV in the continent, there had historically been not enough effort made to support the whole value chain including manufacturing.

Conversely, measures such as trade disputes with China on module imports had backfired, resulting in sluggish downstream activity in some areas, while not having the desired effect of boosting upstream manufacturing, Westermeier said. Nonetheless, Westermeier credited the European Commission’s Renewable Energy Directive for its role in getting EU member states to a 100GW installed base of PV capacity today.

Westermeier also applauded the recent creation of an EU Battery Alliance, referring to batteries and energy storage as “vital” to the progress, development and deployment of solar. Westermeier concluded with the remark that EC Industrial Strategy legislation could bring about an “industrial renaissance”.

The EC’s Sefcovic, having called PV an “unlimited clean source of energy”, agreed that while there have been renewables success stories in Europe, there had also been failures, namely in that aforementioned lack of support for manufacturing across the whole value chain, meaning European makers have lost out “to our competitors”, Sefcovic said.

As with other shows in Europe this year, Sefcovic said it was good and important to see emphasis on sector coupling, where synergies between the areas of electricity, heat, cooling and transport can be fully capitalised upon.

Sefcovic mostly talked about batteries in context of electric vehicles (EVs), stating that European countries have to “be leaders in this important technology” and to “make sure the cleanest batteries are made in Europe”. Sefcovic said he was somehow taken aback that electric taxis in Brussels were Chinese made, making him think it was “high time we did something about that”.

June 22 (Renewables Now) – New York governor Andrew M Cuomo on Thursday unveiled a roadmap with a set of recommendations aimed at facilitating the state in reaching its goal of deploying 1,500 MW of energy storage by 2025.

The comprehensive plan is part of the measures addressed towards fighting climate change, improving power grid resilience and enhancing the benefits of renewables generation to meet peak demand for electricity. “This Roadmap is the next step to not only grow our clean energy economy and create jobs, but to improve the resiliency of the grid to keep our power running in the face of extreme weather and other emergency situations,” Governor Cuomo said.

The short-term recommendations include the provision of USD 350 million (EUR 301m) in incentives to speed up deployment of advanced storage systems, as well as additional funding storage capacity linked to solar projects developed under the NY-Sun initiative. The proposed measures also include regulatory changes to utility rates, solicitations and carbon values, facilitating the project permitting and siting process so as to cut indirect and soft costs, and modifications to wholesale market rules.

The plan was developed by the Department of Public Service and New York State Energy Research and Development Authority (NYSERDA).

Separately, the NY Green Bank has committed to provide at least USD 200 million for storage-related investments. The state-sponsored investment fund is also expected to launch a Request for Proposals (RfP) later this year for projects incorporating solar and energy storage technologies.

As the utility industry comes to grips with the coming of age of energy storage (see the T&D World April 2018 Energy Storage Supplement), residential storage also is ramping up.  According to the latest quarterly update of the U.S. Energy Storage Monitor from GTM Research/ESA, the  residential storage increase in the 4th quarter of 2017 was the highest on record and combined behind the meter energy storage for all customer categories accounted for 55% of the additions during 2017.

California and Hawaii lead the country for residential deployments in the 4th quarter, and GTM is predicting a breakout year for storage of all types in 2018.  Falling costs and favorable regulatory policies are part of the equation.  No doubt, FERC’s hugely significant decision that outlines a path for integrating energy storage resources into the U.S. wholesale markets is a big part of the optimism. However, GTM also suggests that storage may be negatively impacted by the tariffs imposed on solar cells and modules in early 2018.

Despite the solar tariff issue, there are a number of reasons to expect residential storage will continue to break records in 2018.  For one, the IRS issued a Private Letter Ruling in March (PLR 201809003) that permitted a customer to take the 30% solar Investment Tax Credit (ITC) for a storage system retrofitted to an existing solar PV system. Previously, residential storage retrofits could not claim the ITC. Consequently, we could see a significant uptick in the demand for retrofit targeted storage systems.

Legislation in a number of states for behind the meter (BTM) storage tax credits supports the case for greater residential storage demand.  Finally, when a major industry player decides to enter a particular market, it sends a strong signal that the market has growth potential.  Consider the new offering by ABB of a flexible, modular residential storage system. The system consists of the new REACT 2 inverter and a high-voltage lithium ion battery that can be installed in capacities of 4 kWh, 8 kWh and 12 kWh.  The system can be installed on both the AC and DC side of an existing or new photovoltaic system and it can be configured to provide backup power in an outage.

Interestingly, other companies have entered the residential energy storage market, presumably to compete with Tesla and its Powerwall offering, for the PV packaged system and PV backup system demand.   Mercedes-Benz started a new energy subsidiary last year with a modular home battery pack program that it installed itself and offered to solar companies.  In fact, Nissan, Audi and other auto companies with electric vehicle offerings all are attempting to lever their technology to break in to home storage and other markets.  Mercedes-Benz has already decided the home storage market is not a good fit for its battery technology and ended its new program in April.

Automakers like Daimler have been eager to leverage their battery operations connected with their electric vehicles (EV) programs. Late in 2016, Daimler hired Boris von Bormann, a former top executive at Sonnen, to launch Mercedes-Benz Energy Americas to market batteries to residential, commercial and utility consumers.

Daimler says the Elverlingsen facility will provide “efficient double usage of battery systems” that will improve “the life cycle assessment” and the life cycle costs of its EV program.

The facility, built in conjunction with GETEC ENERGIE and The Mobility House, will provide “active” storage of 1,920 lithium-ion battery modules at the ENERVIE AG power station site in Elverlingsen.

Daimler called it “a fountain of youth” for the battery systems used for its EVs.

Putting the batteries through deliberate, battery-conserving charging and discharging cycles at the plant prevents exhaustive discharge which can lead to battery defects before they are potentially used in Daimler EVs. At the same time, the energy storage system can provide “an attractive business case” by securing compensation for providing the grid with primary balancing power.

The Elverlingsen plant is the third such storage facility for Daimler. The automaker opened a 12.8 MWh second life battery storage plant in Elverlingsen in 2016, and in 2017 brought a 17.4 MWh replacement part energy storage facility in Hanover online.

When available, former generating plants make good sites for large energy storage facilities because of their location at a critical juncture on the grid and their access to grid connections.

In 2016, Younicos selected the former Roosecote coal- and gas-fired station in Barrow-in-Furness, Cumbria, U.K., for a 49-MW battery storage system that will be owned and operated by Centrica and used for frequency regulation.

That same year, AES Energy Storage brought a 20 MW, 20 MWh storage facility online at the site of Indianapolis Power & Light’s former coal-fired Harding Street station in Indianapolis.

Daimler is not the only automaker to focus on energy storage.

FlexGen, an energy storage integrator, announced that Vistra Energy, an integrated power company, awarded a contract to design and integrate a 10-MW/42-MWh FlexGen energy storage system at the Upton 2 solar power plant in Texas.

When completed in late 2018, the energy storage system, using FlexGen’s Hybrid OS software, will allow Vistra to store inexpensive solar energy generated during the day and deliver it to customers during evening hours when demand is greatest, improving grid reliability.

The lithium-ion energy storage project at Upton 2 will be the largest in Texas, and the seventh largest in the United States.

“Vistra is leading our country’s transformation toward a reliable, low cost, sustainable energy mix and we’re thrilled to be supporting its storage strategy,” said Josh Prueher, FlexGen CEO. “The power grid of the future will see energy storage integrated on site with solar, wind, and gas generation, and the Upton solar plus storage project is a trailblazing example.”

FlexGen, backed by Altira Group, General Electric and Caterpillar, designs and delivers energy storage solutions to utilities, power companies and industrial customers worldwide. FlexGen products combine proprietary software, advanced energy storage and power conversion technologies to improve cost, reliability, quality, safety and sustainability of electrical power systems.

In order to combat the devastating effects of climate change and ensure a clean future for coming generations, massive investments and research are being undertaken in renewable energy solutions. Arguably, numerous advances have been made in solar and wind power – but these systems have a major drawback: they are most effectively used when the sun is shining or the wind is blowing.

This brings us to the biggest challenge the sector has to tackle: effective ways to store that energy for longer, so it can be used when the sun and wind are not available. Mass-scale energy storage does exist, but it is dominated by just one technology: pumped hydro, where excess electricity is used to pump water into a reservoir, and that stored water is in turn used to run turbines to generate extra power when needed. There are other technologies, such as batteries, electrochemical storage, etc., but these make up a small percentage of total capacity (less than 5% of the total, according to policy group REN21).

This gap hasn’t gone unnoticed: some of the biggest companies and several top investors are funneling money into research on mass-scale energy storage. And this is a market that will continue to grow as renewable energy as well as battery costs are set to drop further in coming years.

Powering the world

Growing concerns about dangerous levels of vehicular pollution are necessitating a global move to encourage less polluting forms of private and public transport, giving a major boost to electric vehicle technology—which depends massively on batteries. This in turn has boosted research and sales of energy storage systems.

But it’s not just cars that will need better and more effective storage. Residential, commercial and industrial establishments also have an urgent need for better storage, thus providing another driver to the sector.

To this end, many countries around the world have already seen major growth in the energy storage systems market. Key regions are Asia Pacific, North America, Europe and the Middle East and Africa. Asia Pacific retains the biggest share, with China’s potential as a battery manufacturing hub being the prime driver of growth.

Daimler, through its subsidiary Mercedes-Benz Energy and with partners, is turning a coal power plant into a large energy storage facility using over a thousand modules from its electric car battery packs.

Like Tesla and its ‘Tesla Energy’ division, Mercedes-Benz is leveraging its experience with battery packs for electric cars into making stationary energy storage projects.

They created a ‘Mercedes-Benz Energy’ subsidiary and launched several projects.

One of them was a residential battery pack to compete with Tesla’s Powerwall.

Earlier this year, the company killed the project after admitting that their product was too expensive and overengineered for its application.

While they got out of the residential market, they are still going strong with bigger-scale projects.

Their latest project was unveiled today and it consists of a 8.96 MW/9.8 MWh project using a total of 1,920 battery modules installed in Elverlingsen on the site of the former coal-fired power station that was built in 1912 and recently shut down – pictured above.

Daimler said about the site of the project:

“The large storage plant is therefore a symbol for the transformation in the storage and use of energy – away from fossil electricity grid supply and towards a sustainable extension of the e-mobility value chain that reduces CO₂.”

The battery modules would have normally found their ways into about 600 third generation electric smarts.

The project is going to be used for primary balancing power on the German grid, which has added a significant amount of renewable energy in recent years.