Germany builds the world’s first wind turbines with built-in hydroelectric storage

Story: 2016 C.E.  |  Last updated: January 1, 2016

High in Germany’s Swabian-Franconian forest, four towers are rising that do something no wind turbines have done before: store their own energy as water. Engineers are pumping water up inside the turbine structures themselves, turning each tower into a kind of gravity-powered battery — a solution to one of renewable energy’s most stubborn problems.

Key details

• Wind-hydro integration: Each turbine pumps water roughly 100 feet up inside its own structure when the wind is blowing, then releases it downhill to generate hydroelectric power when the wind stops — with basins around each base holding an additional 9 million gallons.
• Turbine height: At 809 feet (246.5 meters), the turbines in this project are the tallest in the world, with a combined capacity of 13.6 megawatts of wind power plus another 16 megawatts from the integrated hydroelectric plant.
• Project timeline: Developed by German firm Max Boegl Wind AG and GE Renewable Energy, the wind farm is scheduled to connect to the grid by 2017 C.E., with hydropower units completing by the end of 2018 C.E.

Why storing wind energy is so hard

Wind is abundant. The problem is timing. The wind blows when it blows — not necessarily when people need electricity.

Until now, most wind farms have had no practical way to store excess energy. When turbines produce more power than the grid can absorb, operators have two options: send the surplus into the grid at very low or even negative prices, or simply shut the turbines down. Both choices represent waste on a large scale.

Battery storage exists, but the cost has historically made large-scale deployment difficult to justify. Pumped-water storage — where water is pumped uphill when energy is cheap and released downhill to generate power when demand rises — is one of the most proven grid-scale storage technologies in the world. The innovation here is integrating that reservoir directly into the turbine structure, rather than treating generation and storage as two separate systems far apart.

What makes this design different

There are a handful of wind-and-pumped-water projects in the world, but none that physically merge the two technologies into a single unit the way this project does. By using the turbine tower itself as part of the storage infrastructure, Max Boegl and GE have reduced the footprint and cost of adding storage to a wind installation.

A man-made lake in the valley below collects water that flows down from the turbine basins. When wind returns, the turbines pump it back up again. The cycle can repeat continuously, smoothing out the variability that has always been wind power’s primary weakness.

Agora Energiewende, a German clean energy think tank, reported that Germany’s average renewable energy mix reached 33% in 2015 C.E. — impressive progress, but still well short of the country’s target. Germany has committed to drawing 45% of its electricity from renewables by 2030 C.E. and reaching 100% by 2050 C.E., an ambition its government calls the Energiewende, or energy transition.

Projects like this one matter because storage is the piece the transition most urgently needs. Generating renewable electricity is no longer the primary challenge — the International Energy Agency has noted that renewable capacity additions have accelerated dramatically worldwide. The challenge is matching supply with demand around the clock.

A template for the future

Max Boegl has said it plans to add one to two new wind-hydro projects in Germany each year after 2018 C.E. The technology can work with both fresh and saltwater, which opens up potential sites far beyond the forests of Bavaria and Franconia — including coastal regions and islands where both wind and water are plentiful.

If the system performs as expected, it could offer a replicable model for grid-scale renewable storage at a cost that conventional battery technology has not yet matched. The International Renewable Energy Agency has identified pumped hydro as the dominant form of grid-scale energy storage globally — this project essentially brings that technology inside the turbine itself.

The design also demonstrates that the solutions to clean energy’s hardest problems may come from combining proven technologies in new ways, rather than waiting for a single breakthrough technology to arrive.

Lasting impact

Beyond this specific project, the wind-hydro integration model points toward a broader shift in how engineers think about renewable infrastructure. Rather than treating generation and storage as separate problems requiring separate infrastructure, this approach embeds resilience directly into the power source.

Germany’s Energiewende has been watched closely by energy planners around the world since it began in earnest in the early 2000s C.E. Successes and failures in the German grid have directly shaped policy in Japan, the U.K., Australia, and elsewhere. A storage solution that proves viable at scale in the Swabian-Franconian forest could influence how wind farms are designed globally for decades.

The U.S. National Renewable Energy Laboratory and similar institutions in China, India, and the European Union have all identified integrated storage as a key research priority. This project is among the first to move that concept out of the laboratory and into a functioning installation.

Blindspots and limits

The project’s 2016 C.E. announcement came before construction was complete, and real-world performance data — efficiency losses, maintenance costs, long-term durability of combining water and mechanical systems at height — will take years to accumulate. The Swabian-Franconian forest site was chosen partly for its geography; not every wind-rich region has the elevation changes and available land this design requires. Scaling the model to flat coastal or offshore environments will require further engineering work that remains unproven.

Read more

For more on this story, see: Nepal Energy Forum

For more from Good News for Humankind, see:

• Renewables now make up at least 49% of global power capacity
• Indigenous land rights and 160 million hectares recognized at COP30
• The Good News for Humankind archive on the modern era

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