The European wind turbine rotor blade market is experiencing significant growth, driven by the increasing demand for renewable energy sources and the ambitious targets set by the European Union for carbon emission reduction. Wind energy is a crucial component of this transition, and the demand for efficient and reliable wind turbines is on the rise. This, in turn, fuels the growth of the wind turbine rotor blade market, as these blades are essential for capturing wind energy and converting it into electricity. The European market is characterized by a strong focus on technological advancements and innovation, with manufacturers constantly striving to develop lighter, stronger, and more efficient blades. This is crucial for maximizing energy capture and reducing the cost of wind power generation. Furthermore, the market is witnessing a growing trend towards larger rotor blades, as these enable turbines to generate more electricity. This trend is particularly evident in the offshore wind sector, where larger turbines are being deployed to harness the abundant wind resources available in deeper waters. The European wind turbine rotor blade market is also influenced by government policies and incentives, which support the development and deployment of wind energy projects. These policies often include feed-in tariffs, subsidies, and tax incentives, which make wind energy more competitive with traditional energy sources. In addition to these factors, the market is also driven by the increasing awareness of environmental issues and the need to reduce reliance on fossil fuels. Wind energy is a clean and sustainable source of energy, and its adoption is seen as a key step towards mitigating climate change and ensuring energy security. The European wind turbine rotor blade market is poised for continued growth in the coming years, driven by the factors mentioned above. The market is expected to witness further technological advancements, increased investments, and supportive government policies, which will contribute to its expansion and solidify the role of wind energy in Europe's energy mix.

Europe wind turbine rotor blade market accounted for $3,813.1 million in 2020 and will grow by 9.0% annually over 2025-2030 driven by the increasing application of offshore wind turbines, decreasing levelized cost of electricity (LCOE) of wind energy, rising height and capacity of wind towers, and rising demand for renewable sources of energy. The European wind turbine rotor blade market is experiencing a surge in demand, driven by a confluence of factors that are reshaping the energy landscape. Market trends point towards larger rotor blades, increased use of carbon fiber, and a growing emphasis on offshore wind farms. These trends are fueled by the market drivers of ambitious renewable energy targets set by the European Union, supportive government policies and incentives, and increasing awareness of environmental concerns. Trade programs such as feed-in tariffs, subsidies, and tax incentives further stimulate market growth by making wind energy more competitive. The market is also witnessing a rise in technological advancements, with manufacturers constantly innovating to produce lighter, stronger, and more efficient blades. This focus on innovation is crucial for maximizing energy capture and reducing the levelized cost of energy (LCOE) of wind power. Furthermore, the market is influenced by the increasing demand for reliable and sustainable energy sources, as well as the need to reduce dependence on fossil fuels. These factors are creating a favorable environment for the growth of the European wind turbine rotor blade market, with significant investments and capacity additions expected in the coming years.

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The Europe wind turbine rotor blade market is segmented by location of deployment into onshore and offshore wind farms. Currently, the onshore segment dominates the market due to several factors. Onshore wind farms are generally less expensive to develop and operate compared to offshore wind farms. This is primarily because onshore locations often have easier access for transportation and installation of wind turbines, as well as less challenging environmental conditions. Additionally, onshore wind projects typically require less complex infrastructure and permitting processes, which can reduce project timelines and costs. However, the offshore segment is expected to witness significant growth in the coming years. Offshore wind farms offer several advantages, including higher capacity factors due to stronger and more consistent winds, reduced visual impact on landscapes, and minimal competition for land use. As technology advances and costs associated with offshore wind development decrease, more and more projects are being planned and implemented in European waters. This trend is driven by the need to harness the vast wind resources available offshore and to meet the growing demand for clean and sustainable energy. Furthermore, supportive government policies and targets for offshore wind capacity are contributing to the expansion of this segment. While onshore wind will continue to play a significant role in Europe's renewable energy mix, the offshore segment is poised to become a major contributor to wind power generation in the future. The development of larger and more powerful turbines specifically designed for offshore conditions, along with advancements in installation and maintenance techniques, will further drive the growth of the offshore wind turbine rotor blade market.


The Europe wind turbine rotor blade market is segmented by blade material into glass fiber and carbon fiber. 1 While glass fiber has been traditionally used due to its cost-effectiveness and well-established manufacturing processes, carbon fiber is increasingly gaining traction due to its superior properties. Carbon fiber offers a higher strength-to-weight ratio compared to glass fiber, enabling the production of lighter and longer blades. 2 This is crucial for maximizing energy capture, especially for larger turbines and in offshore environments where wind conditions are more demanding. Although carbon fiber is more expensive than glass fiber, its benefits in terms of performance and durability are driving its adoption in the market. The use of carbon fiber allows for the design of more efficient blades that can withstand higher wind speeds and loads, leading to increased power generation. 3 Furthermore, carbon fiber blades have a longer lifespan and require less maintenance compared to glass fiber blades, resulting in lower operational costs over the long term. 4 As technology advances and the cost of carbon fiber decreases, its adoption in the European wind turbine rotor blade market is expected to increase further. However, glass fiber will continue to be used, particularly in smaller turbines and onshore applications where cost considerations are more critical. The market is also witnessing research and development efforts to explore new materials and composite structures that can further enhance the performance and durability of wind turbine blades.

The Europe wind turbine rotor blade market is experiencing a significant shift towards longer blade lengths, driven by the increasing demand for higher capacity wind turbines. Longer blades enable turbines to capture more wind energy, resulting in increased power generation and improved efficiency. This trend is particularly prominent in the offshore wind sector, where larger turbines are being deployed to harness the abundant wind resources available in deeper waters. As blade length increases, manufacturers face several challenges, including the need for stronger and lighter materials, as well as innovative designs to ensure structural integrity and aerodynamic performance. Carbon fiber is increasingly being used in longer blades due to its superior strength-to-weight ratio compared to traditional glass fiber. Additionally, advanced manufacturing techniques and sophisticated blade designs are being employed to optimize blade performance and minimize fatigue. The trend towards longer blades is expected to continue in the coming years, as wind turbine technology advances and the demand for clean energy grows. This will drive further innovation in blade materials, manufacturing processes, and design, leading to even more efficient and cost-effective wind power generation.

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Manmayi Raval

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The Europe wind turbine rotor blade market is segmented by installation type into onshore and offshore. Currently, onshore installations dominate the market due to a combination of factors. Onshore wind farms generally benefit from lower development and operational costs compared to their offshore counterparts. Accessibility for transportation of turbine components, including the large rotor blades, is typically easier on land, simplifying logistics and reducing expenses. Furthermore, onshore sites often present fewer environmental challenges and require less complex permitting processes, leading to quicker project timelines. The established infrastructure and expertise in onshore wind farm development also contribute to its current market dominance. However, the offshore segment is poised for significant growth in the coming years. Offshore locations offer several key advantages that are driving this expansion. Consistent and stronger wind resources available offshore translate to higher capacity factors and increased energy production. Additionally, offshore wind farms have a reduced visual impact on landscapes, minimizing concerns about aesthetics and land use. The vast potential of offshore wind resources in European waters, coupled with advancements in turbine technology and decreasing costs associated with offshore development, are fueling this growth. While onshore installations will continue to play a crucial role, particularly for repowering existing sites and in specific geographic locations, the offshore segment is expected to become a major contributor to Europe's wind energy capacity as nations strive to meet ambitious renewable energy targets and decarbonize their energy systems. This shift towards offshore installations will drive demand for larger, more advanced rotor blades designed specifically for the challenging marine environment.

The European wind turbine rotor blade market is experiencing robust growth across various countries, each with its own unique dynamics. Germany, a pioneer in wind energy, boasts a well-established onshore wind sector and is increasingly focusing on expanding its offshore capacity. The country's strong manufacturing base and supportive policies contribute to its market leadership. In the United Kingdom, the focus is heavily on offshore wind development, driven by abundant North Sea resources and ambitious government targets. The UK is home to some of the world's largest offshore wind farms, creating significant demand for advanced rotor blades. Spain, with its favorable wind conditions, is witnessing a resurgence in wind energy development, particularly in onshore projects. The country's commitment to renewable energy and supportive regulatory framework are driving investments in the sector. France, while having a smaller wind energy market compared to other European countries, is steadily increasing its capacity, with a growing emphasis on offshore wind. The French government's support for renewable energy and initiatives to streamline permitting processes are expected to boost market growth. Other European countries, such as Denmark, the Netherlands, Sweden, and Poland, are also contributing to the market's expansion, with investments in both onshore and offshore wind projects. The diverse landscape of the European wind turbine rotor blade market, with its mix of mature and emerging markets, presents significant opportunities for manufacturers and suppliers.


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Table of Contents

  • 1 Introduction 6
  • 1.1 Industry Definition and Research Scope 6
  • 1.1.1 Industry Definition 6
  • 1.1.2 Research Scope 7
  • 1.2 Research Methodology 10
  • 1.2.1 Overview of Market Research Methodology 10
  • 1.2.2 Market Assumption 11
  • 1.2.3 Secondary Data 11
  • 1.2.4 Primary Data 11
  • 1.2.5 Data Filtration and Model Design 12
  • 1.2.6 Market Size/Share Estimation 13
  • 1.2.7 Research Limitations 14
  • 1.3 Executive Summary 15
  • 2 Market Overview and Dynamics 18
  • 2.1 Market Size and Forecast 18
  • 2.1.1 Impact of COVID-19 on World Economy 19
  • 2.1.2 Impact of COVID-19 on the Market 21
  • 2.2 Major Growth Drivers 23
  • 2.3 Market Restraints and Challenges 30
  • 2.4 Emerging Opportunities and Market Trends 33
  • 2.5 Porter’s Fiver Forces Analysis 37
  • 3 Segmentation of Europe Market by Location of Deployment 41
  • 3.1 Market Overview by Location of Deployment 41
  • 3.2 Onshore Wind Energy Power 43
  • 3.3 Offshore Wind Energy Power 45
  • 4 Segmentation of Europe Market by Blade Material 47
  • 4.1 Market Overview by Blade Material 47
  • 4.2 Carbon Fiber 49
  • 4.3 Glass Fiber 50
  • 4.4 Other Blade Materials 51
  • 5 Segmentation of Europe Market by Blade Length 52
  • 5.1 Market Overview by Blade Length 52
  • 5.2 < 45.0 Meters 54
  • 5.3 45.0-49.9 Meters 55
  • 5.4 50.0 - 54.9 Meters 56
  • 5.5 55.0 - 59.9 Meters 57
  • 5.6 60.0 - 69.9 Meters 58
  • 5.7 > 70.0 Meters 59
  • 6 Segmentation of Europe Market by Installation Type 60
  • 6.1 Market Overview by Installation Type 60
  • 6.2 New Installation 62
  • 6.3 Reinstallation & Replacement 63
  • 7 European Market 2020-2027 by Country 64
  • 7.1 Overview of European Market 64
  • 7.2 UK 67
  • 7.3 France 69
  • 7.4 Germany 71
  • 7.5 Spain 73
  • 7.6 Italy 75
  • 7.7 Sweden 77
  • 7.8 Rest of European Market 79
  • 8 Competitive Landscape 80
  • 8.1 Overview of Key Vendors 80
  • 8.2 New Product Launch, Partnership, Investment, and M&A 83
  • 8.3 Company Profiles 84
  • Aeris Energy 84
  • CARBON ROTEC GmbH and Co KG 86
  • China National Building Material Co., Ltd. 87
  • Enercon GmbH 88
  • Lianyungang Zhongfu Lianzhong Composites Group Co. Ltd. 89
  • LM Wind Power (a GE Renewable Energy business) 90
  • MFG Wind 91
  • Nordex SE 92
  • Senvion SA 93
  • Siemens Gamesa Renewable Energy SA 94
  • Sinomatech Wind Power Blade Co. Ltd 95
  • Suzlon Energy Limited 96
  • TECSIS-Tecnologia e Sistemas Avancados 97
  • TPI Composites Inc. 98
  • Vestas Wind Systems A/S 99
  • Related Reports and Products 100

Table 1. Snapshot of Europe Wind Turbine Rotor Blade Market in Balanced Perspective, 2020-2027 16
Table 2. Growth Rate of World GDP, 2020-2022 20
Table 3. Cumulative Installed Wind Power Capacity by Country, 2014-2020, MW 26
Table 4. Added Wind Power Capacity by Country, 2017-2020, MW 28
Table 5. Main Product Trends and Market Opportunities in Europe Wind Turbine Rotor Blade Market 33
Table 6. Europe Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 41
Table 7. Europe Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 47
Table 8. Europe Wind Turbine Rotor Blade Market by Blade Length, 2017-2027, $ mn 52
Table 9. Europe Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 60
Table 10. Europe Wind Turbine Rotor Blade Market by Country, 2017-2027, $ mn 66
Table 11. UK Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 68
Table 12. UK Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 68
Table 13. UK Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 68
Table 14. France Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 70
Table 15. France Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 70
Table 16. France Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 70
Table 17. Germany Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 72
Table 18. Germany Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 72
Table 19. Germany Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 72
Table 20. Spain Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 74
Table 21. Spain Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 74
Table 22. Spain Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 74
Table 23. Italy Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 76
Table 24. Italy Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 76
Table 25. Italy Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 76
Table 26. Sweden Wind Turbine Rotor Blade Market by Location of Deployment, 2017-2027, $ mn 78
Table 27. Sweden Wind Turbine Rotor Blade Market by Blade Material, 2017-2027, $ mn 78
Table 28. Sweden Wind Turbine Rotor Blade Market by Installation Type, 2017-2027, $ mn 78
Table 29. Aeris Energy: Company Snapshot 84
Table 30. Aeris Energy: Business Segmentation 84
Table 31. Aeris Energy: Product Portfolio 85
Table 32. Aeris Energy: Revenue, 2017-2019, $ mn 85

Figure 1. Research Method Flow Chart 10
Figure 2. Bottom-up Approach and Top-down Approach for Market Estimation 13
Figure 3. Europe Market Forecast in Optimistic, Conservative and Balanced Perspectives, 2020-2027 15
Figure 4. Europe Wind Turbine Rotor Blade Market, 2017-2027, $ mn 18
Figure 5. Impact of COVID-19 on Business 21
Figure 6. Primary Drivers and Impact Factors of Europe Wind Turbine Rotor Blade Market 23
Figure 7. Primary Restraints and Impact Factors of Europe Wind Turbine Rotor Blade Market 30
Figure 8. Investment Opportunity Analysis 34
Figure 9. Porter’s Fiver Forces Analysis of Europe Wind Turbine Rotor Blade Market 37
Figure 10. Breakdown of Europe Wind Turbine Rotor Blade Market by Location of Deployment, 2020-2027, % of Revenue 41
Figure 11. Contribution to Europe 2021-2027 Cumulative Revenue by Location of Deployment, Value ($ mn) and Share (%) 42
Figure 12. Europe Wind Turbine Rotor Blade Market: Onshore Wind Energy Power, 2017-2027, $ mn 43
Figure 13. Onshore Wind Net Capacity Additions by Country or Region, 2015-2022 44
Figure 14. Europe Wind Turbine Rotor Blade Market: Offshore Wind Energy Power, 2017-2027, $ mn 45
Figure 15. Offshore Wind Net Capacity Additions by Country or Region, 2016-2022 46
Figure 16. Breakdown of Europe Wind Turbine Rotor Blade Market by Blade Material, 2020-2027, % of Revenue 47
Figure 17. Contribution to Europe 2021-2027 Cumulative Revenue by Blade Material, Value ($ mn) and Share (%) 48
Figure 18. Europe Wind Turbine Rotor Blade Market: Carbon Fiber, 2017-2027, $ mn 49
Figure 19. Europe Wind Turbine Rotor Blade Market: Glass Fiber, 2017-2027, $ mn 50
Figure 20. Europe Wind Turbine Rotor Blade Market: Other Blade Materials, 2017-2027, $ mn 51
Figure 21. Breakdown of Europe Wind Turbine Rotor Blade Market by Blade Length, 2020-2027, % of Revenue 53
Figure 22. Contribution to Europe 2021-2027 Cumulative Revenue by Blade Length, Value ($ mn) and Share (%) 53
Figure 23. Europe Wind Turbine Rotor Blade Market: < 45.0 Meters, 2017-2027, $ mn 54
Figure 24. Europe Wind Turbine Rotor Blade Market: 45.0-49.9 Meters, 2017-2027, $ mn 55
Figure 25. Europe Wind Turbine Rotor Blade Market: 50.0 - 54.9 Meters, 2017-2027, $ mn 56
Figure 26. Europe Wind Turbine Rotor Blade Market: 55.0 - 59.9 Meters, 2017-2027, $ mn 57
Figure 27. Europe Wind Turbine Rotor Blade Market: 60.0 - 69.9 Meters, 2017-2027, $ mn 58
Figure 28. Europe Wind Turbine Rotor Blade Market: > 70.0 Meters, 2017-2027, $ mn 59
Figure 29. Breakdown of Europe Wind Turbine Rotor Blade Market by Installation Type, 2020-2027, % of Revenue 60
Figure 30. Contribution to Europe 2021-2027 Cumulative Revenue by Installation Type, Value ($ mn) and Share (%) 61
Figure 31. Europe Wind Turbine Rotor Blade Market: New Installation, 2017-2027, $ mn 62
Figure 32. Europe Wind Turbine Rotor Blade Market: Reinstallation & Replacement, 2017-2027, $ mn 63
Figure 33. Breakdown of European Wind Turbine Rotor Blade Market by Country, 2020 and 2027, % of Revenue 65
Figure 34. Contribution to Europe 2021-2027 Cumulative Revenue by Country, Value ($ mn) and Share (%) 66
Figure 35. Wind Turbine Rotor Blade Market in UK, 2017-2027, $ mn 67
Figure 36. Wind Turbine Rotor Blade Market in France, 2017-2027, $ mn 69
Figure 37. Wind Turbine Rotor Blade Market in Germany, 2017-2027, $ mn 71
Figure 38. Wind Turbine Rotor Blade Market in Spain, 2017-2027, $ mn 73
Figure 39. Wind Turbine Rotor Blade Market in Italy, 2017-2027, $ mn 75
Figure 40. Wind Turbine Rotor Blade Market in Sweden, 2017-2027, $ mn 77
Figure 41. Wind Turbine Rotor Blade Market in Rest of Europe, 2017-2027, $ mn 79
Figure 42. Growth Stage of Europe Wind Turbine Rotor Blade Industry over the Forecast Period 80
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Europe Wind Turbine Rotor Blade Market Outlook, 2030

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