It’s only since the arrival of plastic composite blades in the 1980s that wind power has become the source of a toxic waste product that ends up in landfills.

New wood production technology and design makes it possible to build larger wind turbines almost entirely out of wood again – not just the blades, but also the rest of the structure. This would solve the waste issue and make the manufacturing of wind turbines largely independent of fossil fuels and mined materials. A forest planted in between the wind turbines could provide the wood for the next generation of wind turbines.

How Sustainable is a Windmill Blade?

Wind turbines are considered to be a clean and sustainable source of power. However, while they can indeed generate electricity with lower CO2-emissions than fossil fuel power plants, they also produce a lot of waste. This is easily overlooked, because roughly 90% of the mass of a large wind turbine is steel, mainly concentrated in the tower. Steel is commonly recycled and this explains why wind turbines have very short energy payback times – the recycled steel can be used to produce new wind turbine parts, which greatly lowers the energy required during the manufacturing process.

However, wind turbine blades are made from light-weight plastic composite materials, which are voluminous and impossible to recycle. Although the mass of the blades is limited compared to the total mass of a wind turbine, it’s not negligible. For example, one 60 m long fiberglass blade weighs 17 tonnes, meaning that a 5 MW wind turbine produces more than 50 tonnes of plastic composite waste from the blades alone.

Windmill-blade

A fiberglass reinforced plastic blade. Source: Gurit.

A windmill blade typically consists of a combination of epoxy – a petroleum product – with fiberglass reinforcements. The blades also contain sandwiched core materials, such as polyvinyl chloride foam, polyethylene terephtalate foam, balsa wood (intertwined in fibers and epoxy) and polyurethane coatings. [1-4]

Unlike the steel in the tower, the plastic in blades cannot be recycled to make new plastic blades. The material can only be “downcycled”, for instance by shredding it, which damages the fibers and makes them useless for anything but a filler reinforcement in cement or asphalt production. Other methods are being investigated, but they all run into the same problem: nobody wants the “recycled” material. Some architects have re-used windmill blades, for example to build benches or playgrounds. But we cannot build everything out of wind turbine blades.

Because of the limited options for recycling and re-use, windmill blades are usually landfilled (in the US) or incinerated (in the EU). The latter approach is not less unsustainable, because incinerating the blades only partially reduces the amount of material to be landfilled (60% of the scrap remains as ash) and converts the rest into air pollution. Furthermore, given that fiberglass is incombustible, the caloric value of the blades is so limited that little or no power can be produced. [1-4]

Dealing With Waste – 25 Years Later

Most of the roughly 250,000 wind turbines now in operation worldwide were installed less than 25 years ago, which is their estimated life expectancy. However, the rapid growth of wind power over the last two decades will soon be reflected in a delayed but ever increasing and never-ending supply of waste materials. For example in Europe, the share of installed wind turbines older than 15 years increases from 12% in 2016 to 28% in 2020. In Germany, Spain and Denmark, their share increases to 41-57%. In 2020 alone, these countries will each have to dispose of 6,000 to 12,000 wind turbine blades. [5]

Windmill-sails

Old-fashioned windmills had sails made entirely from recyclable materials. Image: Rasbak (CC BY-SA 3.0)

Discarded blades will not only become more numerous but also larger, reflecting a continuous trend towards ever larger rotor diameters. Wind turbines built 25 years ago had blade lengths of around 15-20 m, while today’s blades reach lengths of 75-80 m or more. [3] Estimates based on current growth figures for wind power have suggested that composite materials from blades worldwide will amount to 330,000 tonnes of waste per year by 2028, and to 418,000 tonnes per year by 2040. [1]

These are conservative estimates, because numerous blade failures have been reported, and because constant development of more efficient blades with higher power generating capacity is resulting in blade replacement well before their estimated lifespan. [1][6] Furthermore, this amount of waste results from wind turbines installed between 2005 and 2015, when wind power only supplied a maximum of 4% of global power demand. If wind would supply a more desirable 40% of (current) power demand, there would be three to four million tonnes of waste per year.

Windmill Blades Through History

Yet a look at the history of wind power shows that plastic is not an essential material. The use of wind for mechanical power production dates back to Antiquity, and the first electricity generating windmills – now called wind turbines – were built in the 1880s. However, fiberglass blades only took off in the 1980s. For some two thousand years, windmills of whatever type were entirely recyclable.

Old-fashioned windmills had towers built out of wood, stone, or brick. Their “blades” or “sails” were usually made of a wood framework covered with canvas or wood boards. In later centuries, parts were increasingly made from iron, also a recyclable material.

Lacour1a

The first wind turbines in Europe, built by Paul La Cour in Denmark, had traditional slatted wooden sails. Image:Paul La Cour Museum.

When new types of sails were invented in the eighteenth and nineteenth centuries (such as spring, patent, and rolling-reefer sails), as well as in the twentieth century (Dekkerized and Bilau sails), the design changed but the materials remained the same (eventually including aluminum). [7] Furthermore, contrary to modern wind turbines, which need to be replaced regularly and in their entirety, old-fashioned windmills could last for many decades or even centuries through regular repair and maintenance.

The first wind turbine in the US, built by Charles F. Brush, had a 17 m diameter annular sail with 144 thin blades made of cedar wood. The first wind turbine in Europe, built by Paul La Cour in Denmark, had four traditional slatted wooden sails with a rotor diameter of 22.8 m. La Cour’s design was copied by local enterprises in Denmark, resulting in thousands of wind turbines operating on Danish farms between 1900 and 1920. Dozens of experimental wind turbines were built during the first half of the twentieth century, including some with steel blades, such as the 1939 Smith-Putnam wind turbine in the US. [8]

Gedser2

The three-bladed Gedser wind turbine relied on an air frame superstructure for blade stiffening.

In 1957, Johannes Juul – a student of Paul La Cour – built the three-bladed Gedser wind turbine. It had a rotor diameter of 24 m and relied on an air frame superstructure of steel wires for rotor and blade stiffening. The blades were built from steel spars, with aluminium shells supported by wooden ribs.

The Gedser turbine remained the most successful wind turbine until the mid-1980s. It ran for 11 years without maintenance, generating up to 360,000 kWh per year, but was not repaired when a bearing failed. When the turbine was refurbished and tested in the late 1970s, it performed better than the first wind turbines with fiberglass blades. [8-9]

Size Matters

The first wind turbine with fiberglass blades was installed in 1978 in Denmark, where it powered a school. With its 54 m diameter rotor, the Tvind turbine was at the time the largest wind turbine ever built. After 1980, fiberglass blades became standard in Denmark and the “Danish design” was later copied all over the world. The plastic blade, so it seems, is what defines the modern wind turbine. This presents us with a dilemma.

The switch to fiberglass blades was mainly driven by the desire to build larger wind turbines. Larger wind turbines lower the cost per kilowatt-hour of generated electricity, for two reasons: the wind increases with height, and the doubling of the rotor radius increases power output four times. The desire to build larger wind turbines has driven the wind industry ever since. Rotor diameters increased from around 50 m in the 1990s to 120 m in the 2000s. Today’s largest off-shore wind turbines have rotor diameters of more than 160 m, and a 12 MW turbine with a 220 m rotor diameter is being constructed in the Netherlands. [3][6][10]

Detail-windmill-sail

Improved windmill blade from the 1940s, built and designed by P.L. Fauel. Image: Rasbak (CC BY-SA 3.0)

However, with increasing size, the mass of the rotor blade also increases, which requires lighter materials. At the same time, larger blades deflect more, so that their structural stiffness is of increasing importance to maintain optimal aerodynamic performance and to avoid the blade hitting the tower. In short, larger wind turbines with longer blades place ever higher demands on the materials used, and these exceed the capacities of recyclable materials. [11-12] Wind turbines have become more efficient, but also less sustainable.

Right now, this trend is illustrated by the increasing use of carbon fiber reinforced plastic, which is even stronger, stiffer and lighter than fiberglass reinforced plastic. [11] The use of carbon fibers – which further complicates potential recycling – has become standard in the largest wind turbine blades, mainly in highly stressed locations such as the blade root or the spar caps. Consequently, we have again entered a new era in which blades are now so large that they cannot be made out of fiberglass reinforced composites alone anymore.

Reinventing the Windmill Blade

An industry that calls itself sustainable and renewable cannot send millions of tonnes of plastic waste to landfills each year. Consequently, could we revert to building wind turbine blades from recyclable materials alone? And how large could we build them? To which extent can efficiency and sustainability be reconciled?

Rees_-_Scholten-Mühle_03_ies

Improved windmill blade from the 1930s, designed by Kurt Bilau. The tower is made of stone, the sails are made of wood and aluminum. Image: Frank Vincentz (CC BY-SA 3.0).

Most research into the design of more sustainable wind turbine blades sticks with plastic as the main material. Thermoplastics can be melted and re-used, making it possible to recycle the blades into new wind turbine blades, even on-site. However, due to the material’s lower strength and stiffness, these blades have not been built larger than 9 m for now. [1][13]

Another area of development is the substitution of glass fibers for wood or flax fibers. These blades can be larger, but they have only small sustainability advantages over fiberglass-epoxy blades. [14-15] The petroleum-based epoxy is more harmful than the glass fiber, and natural fiber based composite materials absorb more of it. [16-17][12]

Wooden-blades-and-tower

A small wind turbine with solid wooden blades and tower. Image: InnoVentum.

Some engineers and scientists follow different paths and revert to more traditional wood construction. For small wind turbines, blades can be carved out of solid wood. For larger wind turbines, the blades can be composed of a hollow aerodynamic shell and an internal framework of ribs and stringers supported by a beam called the spar – all built from laminated veneer wood boards, beams and panels.

Laminated Veneer Lumber

Laminated veneer lumber – in which the wood is peeled off the tree and then glued back together in thin layers – is a wood product that appeared in the 1980s, and which has an important advantage in relation to solid wood components. The consistency of wood can vary within a single tree. Therefore, the length of the wood spars used in pre-industrial windmills was limited by the availability of large tree trunks of consistent quality.

The largest traditional windmill ever built – the 1900 Murphy mill in San Francisco – had a rotor diameter of 35 m. In contrast, the process of veneering spreads out defects such as knots, giving better and more predictable stiffness properties. This allows to build larger wooden blades. [12]

Windlust _Burum _juni_2014_05

Patent sails with Dekker leading edges, 1940s. Image: Reboelje.

Wood laminates offer substantial cost and weight reductions as compared to fiberglass. Although the strength and stiffness are lower, much of the load that the blade must support is a consequence of its own weight, so a wood blade doesn’t need to be as strong as a fiberglass blade. [12] Nevertheless, the low stiffness of wood makes it difficult to limit the elastic deflections for very large rotor blades.

In a 2017 study of a 5 MW wind turbine with 61.5 m long blades, conducted at UMassAmherst in the US, it was calculated that in order to be stiff enough and withstand the forces that it’s exposed to, a blade made of laminated wood veneer panels would be 2.8 heavier than a plastic blade (48 versus 17 tonnes) and have a laminate of over 50 cm thick. [12] Although this suggests that it’s technically possible to build a wooden blade more than 60 m long, it’s not very practical. With heavier blades, the wind turbine needs to be built much stronger, which increases the costs and the use of resources.

Smaller Wind Turbines?

There’s two ways to solve this problem. The first is to design a blade largely made from laminated veneer lumber, but reinforced with carbon composite spars and covered with an outer layer of fiberglass composite. In the above mentioned study it was found that such a wood-carbon hybrid blade is stiff enough to reach a length of 61.5 m for a 5 MW turbine, and can be built 3 tonnes lighter than a fiberglass blade. [12] Another study for a wood-carbon blade of the same length comes to a similar conclusion, although in this case the wood-carbon blade is slightly heavier than the plastic blade. [14]

Wood-carbon blades contain less plastic composite material, and the plastic is not intertwined with wood throughout the blade but clearly separated from it, making blade re-use, recycling or incineration more attractive. However, according to the studies mentioned above, a wood-carbon blade still contains 2.5 tonnes [14] to 6.2 tonnes [12] of plastic composites, meaning that a three-bladed 5 MW wind turbine would produce 7.5 to 18.4 tonnes of unrecyclable waste – compared to 50 tonnes for a conventional blade.

Cross-section-wood-carbon-blade-borrmann-2016

A laminated wooden blade with carbon spar caps. Source: [14]

The environmental damage of the carbon-epoxy spars can be viewed as acceptable, if compared to the larger damage done by conventional wind turbine blades. However, the waste problem would not be solved, and further growth in wind power would still result in ever larger waste streams.

Alternatively, we could define sustainability in more ambitious terms, and build wind turbine blades completely out of wood again – even if this means that we have to build them smaller. There’s an extra argument to question our focus on efficiency: the decrease in sustainability not only shows in the blades. Other parts of wind turbines are also increasingly made from plastic composites – most notably the nose cone and the nacelle cover (the housing that protects the drivetrain and the auxiliary equipment from the elements). [1-4]

Other trends are the increased use of electronics, which are not suited for recycling, and of permanent magnet generators based on rare earth materials, which save costs compared to a mechanical gearbox but only at the expense of more destructive mining. Larger wind turbines also kill more birds and bats. [19]

By sacrificing some efficiency, we could gain a lot in sustainability. Wind power advocates may not agree, because it would make wind power less competitive with fossil fuels. However, more expensive wind power can always be counteracted by higher prices for fossil fuels. What’s really problematic is our choice of cheap fossil fuels as a benchmark to determine the viability of wind power. It’s by aiming to compete with fossil fuels – and thus by aiming to provide the energy for a lifestyle built on fossil fuels – that wind turbines have become increasingly damaging to the environment. If we would reduce energy demand, smaller and less efficient wind turbines would not be a problem.

Brush-wind-dynamo-f07e3438dc210438

The first wind turbine in the US, built by Charles F. Brush, had a 17 m diameter annular sail with 144 thin blades made of cedar wood.

How large could we build practical wind turbine blades from laminated veneer lumber alone? Nobody knows. I asked Rachel Koh, the scientist who calculated the requirements for the 61.5 m wood-only blade, but she couldn’t help me: “I only ran the model for the blades of a 5 MW turbine. It would be hypothetically possible to run another study to answer your question, but it’s not a small undertaking”. She also notes that it’s possible to further improve the stiffness of wood laminates with manufacturing innovations.

A Forest of Wind Turbines

Whether we opt for large wood-carbon blades or smaller wood-only blades, in both cases we could also build the tower and the nacelle cover from laminated wood products. In 2012, the German company TimberTower built a laminated wood tower 100 m tall for a 1.5 MW wind turbine. A wooden tower seems to be besides the point, because it replaces part of a wind turbine that’s already perfectly recyclable. However, a wind turbine of which the structure is almost completely built out of wood offers extra benefits.

Wooden-wind-turbines-detail

Illustration: Eva Miquel for Low-tech Magazine

Wood could make the production of wind turbines entirely independent of mined materials and of fossil fuels, except for the gearwork and the electric components (but further gains can be achieved, whenever possible, by using wind power for direct mechanical or direct heat production). [18] Furthermore, wooden wind turbines could become a carbon sink – sequestering CO2 from the atmosphere in their wood components.

Finally, the space between wind turbines on a wind farm, which is not suited as a residential area, should be used to grow a forest that will provide the wood for the next generation of wind turbines. The lumber could be sawed, processed and assembled on-site, which eliminates the energy use associated with the transport of wind turbine parts. The energy required for manufacturing the laminates and for constructing the turbines could come from the windmills, as well as from forest biomass. The wooden wind turbine could become a textbook example of the circular economy.

What about solar panels?

A forthcoming article investigates the sustainability of solar panels. Is toxic and unrecyclable waste inherent to solar PV power? Could we build solar panels using sustainable materials? And what would that mean for the affordability and efficiency of solar power?

Kris De Decker


References:

[1] Ramirez-Tejeda, Katerin, David A. Turcotte, and Sarah Pike. “Unsustainable Wind Turbine Blade Disposal Practices in the United States: A Case for Policy Intervention and Technological Innovation.” NEW SOLUTIONS: A Journal of Environmental and Occupational Health Policy 26.4 (2017): 581-598. [2] Wilburn, David R. Wind energy in the United States and materials required for the land-based wind turbine industry from 2010 through 2030. US Department of the Interior, US Geological Survey, 2011. [3] Jensen, Jonas Pagh. “Evaluating the environmental impacts of recycling wind turbines.” Wind Energy 22.2 (2019): 316-326. [4] Martínez, Eduardo, et al. “Life cycle assessment of a multi-megawatt wind turbine.” Renewable energy 34.3 (2009): 667-673. [5] Ziegler, Lisa, et al. “Lifetime extension of onshore wind turbines: A review covering Germany, Spain, Denmark, and the UK.” Renewable and Sustainable Energy Reviews 82 (2018): 1261-1271. [6] Lefeuvre, Anaële, et al. “Anticipating in-use stocks of carbon fiber reinforced polymers and related waste flows generated by the commercial aeronautical sector until 2050.” Resources, Conservation and Recycling 125 (2017): 264-272. [7] De Decker, Kris. “Wind powered factories: history (and future) of industrial windmills.” Low-Tech Magazine. Barcelona (2009). [8] The Rise of Modern Wind Energy: Wind Power for the World. Pan Stanford Publishing, 2013. [9] Lundsager, P., Sten Tronæs Frandsen, and Carl Jørgen Christensen. “Analysis of data from the Gedser wind turbine 1977-1979.” (1980). [10] Gupta, Ashwani K. “Efficient wind energy conversion: evolution to modern design.” Journal of Energy Resources Technology 137.5 (2015): 051201. [11] Brøndsted, Povl, Hans Lilholt, and Aage Lystrup. “Composite materials for wind power turbine blades.” Annu. Rev. Mater. Res. 35 (2005): 505-538. [12] Koh, Rachel. “Bio-based Wind Turbine Blades: Renewable Energy Meets Sustainable Materials for Clean, Green Power.” (2017). [13] Murray, Robynne, et al. Manufacturing a 9-meter thermoplastic composite wind turbine blade. No. NREL/CP-5000-68615. National Renewable Energy Lab.(NREL), Golden, CO (United States), 2017. [14] Borrmann, Rasmus. “Structural design of a wood-CFRP wind turbine blade model.” (2016) [15] Spera, David. “Wind Turbine Technology: Fundamental Concepts in Wind Turbine Engineering, Second Edition.” (2009) [16] Corona, Andrea, et al. “Comparative environmental sustainability assessment of bio-based fibre reinforcement materials for wind turbine blades.” Wind Engineering 39.1 (2015): 53-63. [17] The use of wood for wind turbine construction. Meade Gougeon, NASA. [18] De Decker, Kris. “Heat your house with a mechanical windmill.” Low-Tech Magazine. Barcelona (2019). [19] Loss, Scott R., Tom Will, and Peter P. Marra. “Estimates of bird collision mortality at wind facilities in the contiguous United States.” Biological Conservation 168 (2013): 201-209.Prinsenmolen-details-of-modernized-sails