It looks brilliantly simple. Why are onshore wind turbines smaller than offshore ones? Because you have to move them to their location by road, over bridges, through tunnels and around curves. That limits their size. As Michael Purton, writing for WEF, explains it’s why the company Radia is building the world’s biggest aeroplane called WindRunner (12 times the volume of a Boeing 747), big enough to carry turbine blades over 100m long. And the plane only needs a short unpaved runway. Onshore, the power market is 20 times bigger. And bigger turbines mean locations with lower wind speeds become commercially viable. Mass deployment will bring down power prices and accelerate the renewables GW rollout. Radia says this new approach can triple the acreage in the world where wind deployment can happen. WindRunner is still in development, but Radia say a fairly sizable fleet will be operating before 2029, with the initial flights happening well before that.
Ask people what they think of when they hear the words “flying” and “climate” and their answers are likely to involve negative environmental impacts.
Mark Lundstrom is working to rewrite this narrative, as the founder and CEO of Radia, a company building the world’s biggest aeroplane. Known as WindRunner, it will enable the transportation of gigantic wind turbine blades to onshore locations.
Why? To facilitate GigaWind, a new generation of massive onshore wind turbines that could significantly increase grid capacity, lower energy prices and avoid vast amounts of carbon emissions.
In a recent episode of the World Economic Forum’s Meet the Leader podcast, Lundstrom talked to Linda Lacina about the development of this ambitious craft and turbines, and the drivers behind his work in the clean energy space. Here are some key messages from the conversation.
GigaWind: offshore-sized wind turbines deployed onshore
GigaWind is Radia’s name for gigantic onshore wind turbines, which are significantly more powerful than traditional turbines. This is chiefly due to their larger rotor blades, which allow them to capture far more wind energy, along with being able to operate at greater heights and in lower wind speeds.
The company says that with a conservative WindRunner fleet, GigaWind could add up to 216GW to the United States’ grid, and supply up to 40% of total US electricity generation by 2050, according to a recent report by consulting firm DeSolve LLC.
GigaWind could also lower US energy prices by up to 16%, reduce grid emissions by 15-31%, and avoid up to 760 million metric tons of CO2 emissions per year, Radia adds.
“Imagine offshore-sized wind turbines deployed onshore. What this enables you to do is have a path to the cheapest energy in the world and the cheapest green energy in the world – and it’s done by using basically existing technology,” Lundstrom said.
“The world knows how to make offshore scale wind turbines. They’re just deployed in the ocean. And there’s this opportunity to bring gigantic turbines to onshore locations where the market is 10 or 20 times bigger and to be able to reduce the cost of onshore wind by about a third, and to be able to triple the acreage in the world where wind is economically viable.
“If one reads the analyst reports about where our energy needs to come from to meet the Paris Accord goals, there’s uniformity in the opinion that onshore wind needs to be one of the biggest contributors to our primary power source.
“So we need to figure out how to make cheaper onshore wind, and the best way to do that is to use existing established technologies and be able to redeploy those great inventions that have been made for offshore wind to onshore locations.”
Explaining how the concept of GigaWind was born, Lundstrom added: “About seven years ago, a couple of the largest wind turbine manufacturers in the world together issued some industry press saying that they and the industry know how to make offshore-sized turbines, and they’re just frustrated they can’t move it to where the market is 10 or 20 times bigger.
“And so Radia responded to that request and started working with both of these arch rivals on a vision for GigaWind.”
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A conservative GigaWind fleet in the US could potentially avoid up to 760 million metric tons of CO2 emissions per year / IMAGE: Radia
Transporting huge turbines by land is the problem
It’s a question of size, Lundstrom explained: “The only thing that’s standing between us and GigaWind, offshore-sized turbines onshore, is having a transportation issue solved.
“Today, the turbines are simply too big to get under bridges, through tunnels, around curves – and that’s why blades are typically limited in the 70-metre range or so onshore, whereas offshore they’re well over 100 metres in length – Eiffel Tower-sized machines.”
WindRunner: 12 times bigger than a 747
Still in development, WindRunner is the world’s largest plane.
“This is the first time that an aircraft has been designed to optimise on volume instead of weight, and so it’s very unique in the sense that it can still move a lot of mass, 70 tons, but it has a volume that’s about 12 times bigger than a 747 aircraft,” Lundstrom said.
This means the cargo hold can carry a 100-metre-plus blade – and because wind farms are typically built in remote locations, the plane will be capable of landing on short, unpaved airstrips.
“We intend to have a fairly sizable fleet operating before 2029, and with the initial flights happening well before that,” Lundstrom said.
“After the initial fleet of aircraft are manufactured, we’ll have operating bases around the world that will be servicing different land masses. And then from those operating bases, we will be able to deliver to a 2,000km range, and then our goal is to continue to build the fleet and to continue to deliver more and more of the turbines of the world, making them bigger and bigger, and have it have the biggest carbon impact that we can by deploying more larger turbines.”
Although WindRunner is “very unique” due to its size and landing capabilities, “there’s no new aerospace technology that’s being used”, Lundstrom said.
“We’ve basically taken off-the-shelf components that are already certified and already in mass production, and have designed an aeroplane around that,” he said. “And so the risk is quite a bit lower than most aircraft projects, because we’re using things that are already flying and already certified today.”
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WindRunner, the world’s largest plane and still in development, has been designed to optimise volume rather than weight / IMAGE: Radia
Making more land economically viable for onshore wind
The DeSolve LLC report figures speak for themselves in terms of the potential of GigaWind – made possible by WindRunner – to deliver more clean energy.
Lundstrom added: “By being able to deploy larger turbines, we can triple the acreage in the world where wind is economically viable.
“We will have a lot more flexibility in terms of the characteristics of a site, because when you drop the average wind speed from seven metres per second that’s required today, down to five metres per second that we can enable with GigaWind, you increase the landmass in the world by a factor of three – and so you open up many, many new sites that, that don’t exist today.”
What inspired GigaWind and WindRunner?
Originally an aerospace engineer, Lundstrom became a technology entrepreneur 30 years ago, and addressing the climate crisis has always been a motivation.
“The necessity to fight climate change is something that’s a big motivating factor,” he said.
“It’s very unique to be able to have an aerospace solution to climate change, as opposed to contributing to the problem. And so for an aerospace engineer or for an aerospace company to be able to contribute their skills to fighting climate change, instead of just optimising passenger seat miles or making a defence product, this is a unique opportunity for the aerospace industry to both get exposure into the energy world, and also be able to take many percentage points of CO2 out of the world.”
And Lundstrom’s ambitions for WindRunner to be a positive force extend beyond just wind turbines. “Being able to fly a very large amount of material into a dirt strip after a natural disaster, for example, is a capability that’s very interesting to the humanitarian organisations in the world,” he said.
The World Economic Forum’s Global Future Council on the Future of Energy Transition champions the transition to renewable energy. As we face the convergence of global energy shortages, climate change, economic challenges and geopolitical conflicts, it asks: how can energy transition strategies be significantly accelerated to achieve sustainability affordably and securely?
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Michael Purton is a Senior Writer at Forum Agenda
This article is republished in accordance with the Creative Commons Attribution-Non Commercial-No Derivatives 4.0 International Public License