The global wind power industry entered a new era of accelerated growth in 2023, with a record-setting 117 GW of new capacity installed—making it the most successful year to date, as reported by the Global Wind Energy Council (GWEC) in its 2024 Global Wind Report. This unprecedented expansion underscores the industry’s rising momentum, driven by increasing political commitment and the rapid development of offshore wind projects. The report highlights that the global growth of wind power is not only broadening across continents, with 54 countries contributing to new installations, but also gaining significant traction in emerging markets and developing economies.
Several key factors are propelling this growth. The commitment made at COP28 to triple renewable energy capacity by 2030 has provided a powerful catalyst for wind energy expansion. Additionally, national industrial policies in major economies are fostering this growth through a combination of incentives, subsidies, and supportive regulatory frameworks. Technological advancements, particularly in turbine design and offshore wind development, have further enhanced the efficiency and cost-effectiveness of wind energy. Looking ahead, the Global Wind Report 2024 presents an optimistic outlook, forecasting a 10% increase in growth projections for 2024-2030, with an additional 1,210 GW of capacity anticipated. This robust trajectory positions wind power as a pivotal force in the global transition to a clean energy future.
The Future of Wind Power
Wind power is forecasted to play an even larger role in the future energy mix. By mid-century, wind energy is expected to account for 14% of the world’s primary energy supply, surpassing solar PV. Additionally, wind will provide 36% of global electricity generation by 2050, with two-thirds of this coming from onshore projects. This significant expansion underscores the importance of wind power in meeting global emissions reduction targets and ensuring a sustainable energy future.
The future development of wind power presents a significant opportunity in terms of providing low carbon energy. Wind power could prevent more than 1 billion tonnes of carbon dioxide from being emitted each year by dirty energy – equivalent to the emissions of Germany and Italy combined,Sven Teske, Greenpeace senior energy expert, had said.
Challenges in Wind Power
Despite its promising future, wind power faces several challenges. It must remain cost-competitive with fossil fuels and other renewable energy sources, particularly solar photovoltaics. Fortunately, wind energy costs have fallen rapidly in recent years and are expected to continue decreasing. Globally, the average cost of wind energy is $83 per megawatt-hour, compared to $84 for coal and $98 for gas. In the U.S., wind energy is priced even lower, averaging around 2 cents per kilowatt-hour, thanks to technological advancements and cost reductions.
However, the intermittency and variability of wind resources present challenges for integrating wind power into existing electricity networks. Wind turbine output can be unpredictable, which complicates grid management. Yet, these challenges can be mitigated through geographical diversity—aggregating the power output of wind farms over larger areas can significantly reduce the intermittency of wind generation.
In February 2021, Texas, the energy powerhouse of the U.S., experienced historic freezing conditions that crippled the state’s power infrastructure, including its 10,700 wind turbines. Nearly half of Texas’ wind power generation capacity was offline due to frozen turbines in West Texas, according to the state’s grid operators. Despite these challenges, the Electric Reliability Council of Texas (ERCOT), which manages the state’s electric grid, benefited from stronger-than-expected winds along the coast, where unfrozen turbines continued to operate and helped mitigate some of the power losses. However, the extreme cold also impacted other energy sources, including coal, gas, and nuclear facilities, leading to widespread power outages across the state.
The reliability of wind turbines is also a critical factor. Onshore turbines typically have availabilities of 98%, while offshore turbines have slightly lower availabilities (95-98%) but are improving due to advancements in operation and maintenance.
Onshore vs. Offshore Wind Farms
Wind farms can be located onshore (on land) or offshore (in sea or freshwater environments), each with distinct advantages and challenges. Onshore wind farms are significantly less expensive and are currently the most cost-effective form of renewable energy compared to offshore wind farms, solar, and nuclear power. However, they face limitations such as inconsistent wind speeds and physical obstructions like buildings or hills, which can reduce their efficiency. Onshore turbines are optimized for specific wind speeds, but the unpredictable nature of wind direction and speed in these areas can limit their overall performance.
Offshore wind farms, on the other hand, benefit from the more consistent and stronger winds found over open water, making them more reliable and efficient. These locations offer greater potential for future advancements in wind technology. Despite the higher costs and increased wear and tear due to harsh marine conditions, recent technological improvements have strengthened offshore turbines to better withstand the forces of waves and ice flows. Research by the University of Delaware has highlighted that offshore winds in the Northeastern U.S. are more powerful, but also more turbulent than expected. This turbulence can increase the power generated by bringing high winds down to the level of the turbines, but it also imposes additional stress on turbine blades. These findings suggest that future offshore wind farms may need to be designed differently, with careful consideration of turbine selection, spacing, and durability to account for these turbulent conditions.
Turbine availability, which measures the proportion of time a turbine is ready for operation, is a key indicator of reliability. Onshore turbines typically have high availability rates of around 98%, while offshore turbines, though slightly lower at 95-98%, are seeing improvements due to advancements in operation and maintenance practices.
Wind Farm Architecture
A wind farm is a collection of wind turbines situated in a single location to generate electricity. While some wind farms can span several hundred turbines across extensive areas of hundreds of square miles, the land between turbines is often utilized for agriculture or other purposes. Wind farms can be situated both onshore and offshore.
Recent advancements in wind farm technology have led to increasingly sophisticated and efficient installations. One notable example is the Hornsea Project One, which, upon completion, will be the world’s largest offshore wind farm. Located 75 miles off the coast of Grimsby, this massive project is expected to cost at least £4.2 billion. The Hornsea Project One will feature 174 turbines, each standing 623 feet tall, collectively generating 1.2 gigawatts of power—enough to supply electricity to approximately one million homes.
The architecture of onshore and offshore wind energy farms is designed to optimize energy capture and operational efficiency. Onshore wind farms typically consist of multiple wind turbines strategically placed across expansive, open landscapes where wind flow is unobstructed. These turbines are connected to a central substation that collects and transmits the generated electricity to the grid.
Offshore wind farms, on the other hand, are constructed in bodies of water, usually on continental shelves. Their architecture involves more complex engineering due to harsh marine environments, requiring robust foundations like monopiles, jacket structures, or floating platforms for deeper waters. Offshore turbines are generally larger and more powerful, capitalizing on stronger and more consistent wind conditions at sea. Both onshore and offshore farms are integrated with sophisticated control systems to monitor performance, optimize output, and ensure grid stability, with offshore installations often relying on advanced subsea cabling to transmit electricity to onshore substations.
Technological Breakthroughs in Wind Power
Innovations in wind power technology are crucial for enhancing the efficiency and reducing the costs of wind energy. There are two primary strategies for increasing wind power generation in a given area. The first is to use larger rotors and blades that can sweep a wider area, thereby boosting the turbine’s capacity, or its maximum potential energy output. The second strategy is to elevate the turbine blades higher into the atmosphere, where wind speeds are more consistent, which enhances the turbine’s “capacity factor”—the proportion of actual power produced compared to its total potential (essentially, how often it operates at full capacity).
A wind turbine’s blades convert kinetic energy from the movement of air into rotational energy; a generator then converts this rotational energy to electricity. The wind power that is available is proportional to the dimensions of the rotor and to the cubing of the wind speed. Theoretically, when the wind speed is doubled, the wind power increases by a factor of eight.
However, these approaches present significant engineering challenges, particularly in developing designs and materials that can withstand the increased stresses associated with greater heights and stronger winds. Engineers are continuously innovating to overcome these challenges, ensuring that turbines remain both durable and efficient as they scale up in size and height.
A study by researchers from Berkeley Lab, the National Renewable Energy Laboratory (NREL), and the University of Massachusetts found that wind power costs could be reduced by 24 to 30 percent by 2030 due to advancements in turbine technology. These improvements include increased rotor diameter and hub height, which allow turbines to access more power, even in areas with lower wind speeds.
Next-Generation Wind Turbines: Bigger, Smarter, and More Efficient
One of the most significant advancements in wind power technology is the development of next-generation wind turbines. These turbines are not only larger but also more efficient, capable of generating more electricity from the same amount of wind.
Larger Turbine Blades: The trend toward larger turbines has been a key driver of increased wind energy production. Modern turbines feature blades that can exceed 100 meters in length, allowing them to capture more wind energy. The larger surface area enables these turbines to produce more power, even at lower wind speeds, making them viable in a wider range of locations.
For instance, onshore wind turbines, which in 2015 averaged a hub height of 82 meters and a rotor diameter of 102 meters, are expected to reach heights of 115 meters and diameters of 135 meters by 2030. Offshore turbines will see even more dramatic increases, Whereas today’s turbines have a hub height of 90m, a rotor diameter of 119m, and a power output of 4.1 MW on average, 2030’s offshore wind turbines will measure 125m and 190m in hub height and rotor diameter, respectively, and output an insane 11 MW on average—each.
Carbon Fiber Composites: Traditionally, wind turbine blades were made of fiberglass. However, innovations in carbon fiber composites are paving the way for lighter, stiffer blades. These materials not only allow for longer blades but also improve the overall durability of the turbines. Carbon fiber composites resist corrosion and wear, ensuring that turbines can withstand harsh environmental conditions over extended periods.
Smart Wind Turbines: The integration of artificial intelligence (AI) and advanced sensors has given rise to “smart” wind turbines. These turbines can monitor and adjust their operations in real time, optimizing energy capture and reducing maintenance needs. Predictive maintenance algorithms help identify potential issues before they become critical, reducing downtime and operational costs.
Offshore Wind Power: Harnessing the Ocean’s Potential
Offshore wind power is another area where technological breakthroughs are making a significant impact. Offshore wind farms have the advantage of tapping into stronger and more consistent winds found at sea, but they also present unique challenges. Recent innovations are overcoming these challenges, making offshore wind power a viable and increasingly attractive option.
Floating Wind Turbines: Traditional offshore wind turbines are anchored to the seabed, limiting their deployment to relatively shallow waters. However, floating wind turbines, which are anchored by mooring lines rather than fixed foundations, can be deployed in deeper waters. This technology expands the potential for offshore wind farms to regions previously considered unsuitable, opening up vast new areas for wind energy development.
Hybrid Wind-Wave Energy Systems: Another promising innovation in offshore wind power is the integration of wind and wave energy systems. By combining wind turbines with wave energy converters, these hybrid systems can generate electricity from both wind and ocean waves, maximizing the energy output from a single installation. This approach not only increases efficiency but also reduces the overall environmental impact by utilizing shared infrastructure.
Advanced Anchoring Systems: As offshore wind farms move further from the coast, the need for robust anchoring systems becomes critical. New anchoring technologies, such as suction bucket foundations and dynamic cables, are being developed to secure floating turbines in deep waters while minimizing environmental disturbance.
The World’s First Floating Wind Farm Begins Energy Production
Floating wind farms, situated far from shore, offer significant potential for future energy generation. Unlike land-based turbines, which are limited by drag effects that reduce wind flow, turbines in offshore environments can be packed more densely. This arrangement allows for up to six megawatts of energy production per square kilometer, compared to the 1.5 megawatts achievable on land using the same turbines. Analysts suggest that three million square kilometers of floating wind turbines could meet the global energy demand.
The world’s first floating wind farm, Hywind Scotland, located in Buchan Deep, is now operational with five six-megawatt turbines generating electricity. To stabilize the variable output, a one-megawatt-hour lithium battery is used to smooth the power supplied to the grid. This concept is gaining traction, with similar projects being explored in California.
The Hywind Scotland project, a joint effort between Norwegian oil firm Statoil and Masdar Abu Dhabi Future Energy, features turbine towers that extend 253 meters, with 78 meters submerged in the North Sea. Each tower is anchored with three cables tethered to the seabed. The project cost $263 million and receives $185 per megawatt-hour in subsidies from the British government, in addition to $65 per megawatt-hour from wholesale electricity prices. Statoil aims to reduce the cost of floating wind farms to between $50 and $70 per megawatt-hour by 2030.
Self-Rising Towers: A Game-Changer for Wind Energy
As wind energy continues to expand, the demand for larger wind turbines on taller towers is increasing. However, the construction of these towering structures has been constrained by the availability of very high cranes. This is where self-rising lattice towers come into play. These innovative towers, suitable for both onshore and offshore applications, are designed to be erected without the need for large cranes. Instead, each tower subsection is raised from the previous lower section using frames, small-sized cranes, and cables.
The self-rising lattice design is particularly advantageous as it allows for the construction of taller wind turbine towers in remote or challenging locations where access to large cranes is limited. This method not only simplifies the installation process but also significantly reduces the costs associated with transporting and operating massive cranes.
Key EU Projects: HyperTower and SHOWTIME
Two significant EU projects are advancing the self-rising tower concept. The HyperTower project focuses on optimizing the design of self-rising lattice towers, specifically tailored for onshore wind farms. On the other hand, the SHOWTIME project is exploring hybrid tower designs that combine the benefits of both lattice and tubular structures. These hybrid towers are particularly suited for offshore applications, where the lower lattice section is connected to a tubular upper section via a transition piece designed to withstand both wind and wave loads.
Technological innovations are also driving cost reductions in offshore wind farms. A report by KIC InnoEnergy and BVG Associates concluded that technological innovations, such as larger turbines, more efficient rotors, and optimized wind farm layouts, could reduce the levelized cost of energy from offshore wind farms in Europe by as much as a third by 2030.
New materials for towers and support structures
Traditional wind turbine towers and support structures are primarily built from steel and concrete. Steel, often of the same grade used in general construction, provides a solid foundation but is heavy. Higher-grade steels can enhance structural performance by improving strength and buckling resistance, potentially leading to lighter and more efficient designs.
Innovative approaches are exploring hybrid solutions that combine steel and concrete to leverage the benefits of both materials. Additionally, alternative materials such as wood, aluminum, and particularly advanced composites—like reinforced materials or sandwich structures—are gaining attention. These new materials offer promising advantages, including reduced weight, increased durability, and potentially lower costs. By incorporating these advanced materials, the wind energy sector aims to improve the efficiency and sustainability of turbine towers and support structures, paving the way for more robust and adaptable wind farms.
GE bringing industrial Internet to wind farms
General Electric Co. has unveiled a groundbreaking wind farm technology that promises to boost output by 20 percent, potentially generating an additional $50 billion in revenue for the wind power industry. “This represents a major breakthrough for renewable energy, particularly wind power,” Steve Bolze, CEO of GE Power & Water, stated in a telephone interview with the Times Union. “With the same wind, we can achieve 20 percent more electrical output. That’s a substantial leap forward.”
The innovation, known as the Digital Wind Farm, has been under development for the past 18 months. It integrates GE’s two-megawatt wind turbines with advanced modeling software, sensors, and the industrial Internet. This integration enables turbines to exchange data and “communicate” with each other, optimizing performance and efficiency.
Key to this advancement are enhanced wind energy forecasting algorithms, grid-scale batteries embedded within the turbines, and real-time turbine networking and power management. The industrial Internet facilitates communication with grid operators to better predict wind availability and power requirements, thereby managing the variability of wind power and ensuring a more stable and predictable energy supply.