风力发电纺织品市场报告：2030 年趋势、预测与竞争分析

风力发电纺织趋势与预测

全球风力发电纺织品市场的未来充满希望，风力涡轮机叶片市场也充满机会。预计2024年至2030年全球风力发电纺织品市场将以6.1%的复合年增长率成长。该市场的主要驱动因素是对风力发电机的需求不断增加、纺织工程的技术进步以及对可再生能源的日益重视。

• 按产品类型划分，Lucintel 预计纺织纱线在预测期内将出现高速成长。
• 从应用来看，风力涡轮机叶片预计将出现强劲成长。
• 从地区来看，亚太地区预计将在预测期内实现最高成长。

风力发电纺织品市场的策略性成长机会

风力发电产业的纺织品提供了许多扩张机会。这些机会受到可再生能源消耗增加、技术进步以及效率和永续性宣传活动发起等因素的影响。以下段落详细介绍了可能塑造市场的五个机会。

• 海上风力发电开发：离岸风力发电开发进展迅速，为耐腐蚀、耐极端天气、海洋环境等纺织品的消费铺平了道路。用于海上涡轮机叶片的纺织品必须具有良好的机械性能并且重量极轻。随着离岸风电产业在欧洲、日本和美国等重点地区的发展，对这些先进纺织解决方案的需求将持续存在，市场创新和成长的机会将是无限的。
• 采用回收和永续材料：随着新型风力发电机叶片继续以更环保的方式设计，回收纺织品的使用代表了一个重大机会。透过使用可回收且环保的原材料，製造商可以在生产风力发电机时满足永续性要求，而不会增加碳排放。打算生产环保复合材料的公司将受益于寻求清洁能源生产解决方案和处理废弃叶片的行业趋势。
• 生产方法的技术发展：由于自动化和数位技术的引入，风力发电机的建设将增加对纺织产品的需求。例如智慧製造技术的出现，包括3D列印、自动化织造技术，以及支援涡轮螺旋桨叶片生产的技术，使它们更有效率、降低成本并缩短前置作业时间。这些进步使得以低成本大量生产复杂的高性能织物成为可能，风力发电机零件市场对这种织物的需求日益增长。
• 对设计和製造中使用的工程或顶级性能的需求不断增加：随着风力发电机变得越来越大，对更强、更轻和更耐用的叶片的需求也在增加。能够增强风力发电机叶片机械性能的纺织品具有巨大的成长潜力。混合纤维的开发以及碳纤维和玻璃纤维的结合将使工业能够满足大型涡轮机的技术需求。对于陆上和海上市场尤其如此，更大、更有效率的涡轮机正在成为常态而不是例外。
• 重点在新兴国家建立风力发电产业：除印度等地区外，风力发电纺织应用的进一步成长地区包括巴西和东南亚。这些国家热衷于提高其可再生能源产能，从而推动风力发电机纺织材料生产的实用性和可负担性。这些市场为公司提供了扩大影响力的机会，特别是在风力发电潜力充足但缺乏现代风力发电机材料行销的地区。

这些成长机会可能有助于风力发电市场中纺织品市场的有效成长。这些产业可以利用新材料、新製造技术并促进永续性，不仅提倡转向可再生能源，而且还有助于改善风力发电机并降低成本。

风力发电纺织品市场驱动因素与挑战

经济、技术或监管等重要因素决定了纺织品在风力发电市场中的地位。这些市场驱动因素/挑战定义了整体环境，并决定了技术进步速度和市场成长率。下面列出了一些驱动因素和挑战。

推动风力发电领域纺织品市场的因素包括：

• 材料科学的技术进步：材料科学的技术进步：得益于材料科学，特别是高强度、轻质纺织品的新应用，风力发电领域正在不断扩大。风力发电机叶片的发展可生产出更轻、更好的叶片，从而提高发电效率并降低能源成本。纺织复合材料的持续进步对于满足现代风力发电机性能标准至关重要，特别是在海上风力发电机和大型风力发电机应用中。
• 再生能源来源消耗的增加：旨在减少排放和向可再生能源过渡的全球政策是风力发电机生产中使用纺织品的关键驱动力。随着越来越多的政府投资风力发电，对提高涡轮机效能和效率的先进材料的需求不断增长。随着对永续性的日益关注，也有更多资金被用于收购风力发电领域的纺织品。
• 降低生产成本：风力发电市场竞争激烈，降低风电成本是重要目标。纺织品透过减轻涡轮叶片的重量并降低运输和安装成本来实现这一目标。随着纺织材料製造技术的进步，纺织材料的成本效益得到了提高，导致它们在风力发电产业的使用增加。
• 扩大海上风力发电领域：离岸风力发电计划的激增为耐海洋暴露的纺织材料创造了机会。这些织物对于生产轻质、耐用且耐腐蚀的涡轮叶片以实现有效的海上部署至关重要。随着离岸风力发电计划的稳定增加，尤其是欧洲和亚洲市场，纺织製造商的市场潜力巨大。
• 环境法规和永续性目标：环境影响政策和协议的软化正在鼓励风力发电产业变得更环保。开发这种生态学永续且可回收的纺织材料将有助于工业遵守法规，并为对抗污染和碳足迹做出贡献。随着永续性变得更加重要，对这些纺织品的需求预计将会成长。如果税收和污染法规允许，工业界可能会采用更环保的材料。

风力发电领域的纺织品市场面临的挑战是：

• 初始投资成本高：虽然纺织品具有很大的多功能性，但其初始生产成本高于传统替代材料。这可能会阻碍广泛采用，特别是在财政资源有限的地区和市场。随着製造流程的改进，成本预计会随着时间的推移而下降，但初始资本投资仍然是一个主要障碍。
• 供应链限制：政治、贸易问题和自然灾害可能会扰乱碳纤维和玻璃等纺织原材料的国际采购。这些中断可能导致原材料短缺和价格上涨，减缓风力发电机叶片的生产并影响风力发电市场。
• 扩大生产规模的技术挑战：事实证明，增加高性能纺织品的产量以满足风力发电市场不断增长的需求非常困难。製造商正在努力调整大规模生产技术，以高效地进行大量、高品质和一致的生产。需要付出巨大努力来开发扩大生产规模的能力，包括以更自动化的方式製造这些材料。

儘管风力发电纺织品市场受到多项强劲驱动因素的支撑，但也面临重大挑战。虽然技术发展和可再生能源在世界上日益重要的角色是主要驱动力，高成本和供应链问题仍然是障碍。克服这些挑战对于确定纺织品在风力发电市场的未来至关重要。

风力发电市场纺织企业名单

市场上的公司透过其提供的产品品质进行竞争。该市场的主要企业专注于扩大製造设施、投资研发、开发基础设施以及利用整个价值链的整合机会。透过这些策略，风电市场的纺织企业正在应对不断增长的需求，确保竞争力，开发创新产品和技术，降低生产成本，扩大基本客群。本报告重点关注的风电纺织企业有：

• 欧文斯康宁
• Jushi Group
• 重庆国际复合材料有限公司
• 泰山玻纤
• 台湾玻璃集团
• 日本电气硝子
• 四川微博
• 3B 玻璃纤维公司（戈尔玻璃纤维）
• 约翰曼维尔公司
• 日东纺绩

目录

第一章执行摘要

第二章全球风力发电纺织品市场：市场动态

• 简介、背景、分类
• 供应链
• 产业驱动因素与挑战

第三章 2018-2030年市场趋势及预测分析

• 宏观经济趋势（2018-2023）与预测（2024-2030）
• 全球风力发电纺织品市场趋势（2018-2023）与预测（2024-2030）
• 全球风力发电纺织品市场：依产品类型
  • 编织粗纱
  • 编织线
• 全球风力发电纺织品市场：依应用分类
  • 风车叶片
  • 其他的

第四章 2018-2030年区域市场趋势及预测分析

• 全球风力发电纺织品市场区域分布
• 北美风力发电纺织品市场
• 欧洲风力发电纺织品市场
• 亚太风力发电纺织品市场
• 其他地区风力发电纺织品市场

第五章 竞争分析

• 产品系列分析
• 业务整合
• 波特五力分析

第六章 成长机会与策略分析

• 成长机会分析
  • 按产品类型分類的全球风力发电纺织品市场成长机会
  • 全球风力发电织物市场成长机会（按应用）
  • 全球风力发电纺织品市场成长机会（按地区）
• 全球纺织品在风力发电市场的新趋势
• 战略分析
  • 新产品开发
  • 扩大全球风力发电纺织品市场产能
  • 全球风力发电纺织品市场的合併、收购与合资
  • 认证和许可

第七章主要企业概况

• Owens Corning
• Jushi Group
• Chongqing Polycomp International Corporation
• Taishan Fiberglass
• Taiwan Glass Group
• Nippon Electric Glass
• Sichuan Weibo
• 3B the Fiber Glass Company（Goa Glass Fiber）
• Johns Manville Corporation
• Nitto Boseki

Woven Textile in Wind Energy Trends and Forecast

The future of the global woven textile in the wind energy market looks promising with opportunities in the windmill blade markets. The global woven textile in wind energy market is expected to grow with a CAGR of 6.1% from 2024 to 2030. The major drivers for this market are the increasing demand for wind turbines, technological advancements in textile engineering, and the growing emphasis on renewable energy.

• Lucintel forecasts that, within the product type category, woven yarn is expected to witness higher growth over the forecast period.
• Within the application category, windmill blade is expected to witness higher growth.
• In terms of regions, APAC is expected to witness the highest growth over the forecast period.

Gain valuable insights for your business decisions with our comprehensive 150+ page report.

Emerging Trends in the Woven Textile in Wind Energy Market

The woven textile market in the wind energy market is moving at a rapid pace, with significant changes driven by factors such as improvements in materials science, enhancements in sustainability, and the development of manufacturing optimization, including digital technologies. The following five trends are emerging and provide evidence of how this market will grow in the future:

• Incorporation of Carbon Fiber in Woven Textiles: Wind turbine blade manufacturers are increasingly using woven textiles that include carbon fiber composites. These materials offer high strength-to-weight ratios, enabling higher turbine efficiency by reducing the weight of the blades without compromising strength. This trend is especially noticeable in high-end wind turbines, where carbon fiber blades help achieve greater length and improved aerodynamic parameters.
• Sustainable Practices Enable Circular Textile Manufacturing: With the growing emphasis on sustainability, the wind energy sector is adopting environmentally safe and recyclable woven textiles. This involves the search for composites and other materials that are environmentally responsible at every stage of a product's life cycle, including packaging. Other companies are exploring textile recycling solutions as part of waste management in support of the circular economy. These eco-friendly materials help reduce the environmental impact of wind power generation and support the global transition to greener energy production.
• Advancements in Hybrid Fiber Technology: The incorporation of natural fibers with synthetic ones has led to the development of hybrid fibers, which are gaining traction in the wind energy sector. These composite materials enhance the properties of woven fabrics, offering better performance than composites made from individual fibers alone. The use of hybrid fiber technology is on the rise, as wind turbine blades made from hybrid fibers provide reasonable performance and cost benefits, while also reducing their environmental impact.
• Smart Textile Integration for Performance Monitoring: The use of smart textiles, which incorporate monitoring systems and sensors, has gained traction as one of the key trends in the wind energy sector. These textiles can cover turbine blades, providing real-time information on operational parameters such as stress, wear, and fatigue, and indicating when the material is nearing damaging levels. Recent innovations in textile technology have also reduced the maintenance needs of wind turbines.
• Automation and 3D Printing in Textile Manufacturing: Automation and 3D printing technologies are improving productivity and lowering costs in the production of woven textiles for wind energy. Automated weaving and knitting technologies, along with 3D printing, allow for the fast production of textile parts for wind turbine prototypes. The Final Assembly System Integrated Non-Destructive Testing Unit is an example of how these technologies are evolving.

These new developments in woven textiles in the wind energy market mark a turning point toward more eco-friendly, cost-effective, and innovative materials. The growing use of carbon structures, hybrid textiles, smart materials, and complex manufacturing techniques is reshaping wind energy systems in a way that maintains performance while minimizing environmental impact.

Recent Developments in the Woven Textile in Wind Energy Market

There are several developmental shifts in the woven textile in the wind energy market that need to be considered in the future of turbine development and production. The goals of these developments include higher efficiency, lower cost, and greater sustainability of the wind energy systems. Below are five key developments in the sector.

• Development of Advanced Composite Blades: Durability is one quality that has been improved. The manufacturers of wind turbine blades are also improving on recent woven textile composites for high-performance wind turbines. More resources are being committed to the designing and construction of atmospheric wind turbines. The advancements so far are combining advanced woven fabric and carbon and glass in turbine blades. These developments lead to blades that have higher efficiency and can produce more energy. As the dimensions of wind turbine generators enlarge to enclose more forceful airflow this becomes important for optimization of the performance.
• Enhanced Allocation Towards Waste Management Technologies: The wind energy industry is very much oriented towards finding solutions to the environmental problem of turbine blades, especially towards the end of life of the blades. Woven textile manufacturers are investing in recycling technologies that are aimed at the production of stronger and more efficient wind turbine blades. Some companies are also developing processes that aid in handling waste composite structures and fiber reuse, supporting the wind industry's efforts towards a circular economy. Such a transition towards green manufacturing is very significant because it helps the industry to achieve its environmental aspirations.
• Partnerships between Wind Energy and Woven Textile Companies: Companies engaged in the wind energy sector collaborate with research universities to develop innovative woven textile technologies. The research aims to obtain novel next-generation materials, which are stronger, more eco-friendly, and more durable than conventional materials. Such partnerships lead to advances in textile science, the new materials developed making wind turbines more efficient in energy conversion as well as more eco-friendly. This type of applied research is important in sustaining the long-term development and viability of the wind energy industry.
• Striving for An Increment in Offshore Wind Development: The offshore wind farm textile requires the use of specialty woven textile materials which are largely demanding for advanced woven textile technologies. Japanese, European, and American firms are at the forefront of producing corrosion-resistant, lightweight, and durable offshore textile composite materials. Such development is paramount since offshore wind energy areas have proven to be one of the best clean energy sources for most coastal towns due to their constant and regular flow rates.
• Deployment of Modern Technologies in the Manufacturing Process of Textile: The use of automatons in the production of woven fabrics for wind energy projects is increasing efficiency and decreasing cost at a fast rate. Prototypes of the above-mentioned cicada systems allow composite materials of turbine blades to be manufactured in a shorter time and with greater accuracy. Such reconstructions are also possible due to the design of the woven textiles that will fit any turbine thus, productivity will increase. This development is critical for the fulfillment of the requirements that accompany the prospects for large-scale and efficient manufacturing within short time frames and low cost, thus making renewable energy options economically viable.

All these developments once incorporated the wind energy will promote a change in the woven textile industry within the wind energy sector through technology enhancement, climate change mitigation and performance as well as affordability of wind turbines. These advancements will promote the sustainability of renewable energy usage in the wind energy region and beyond.

Strategic Growth Opportunities for Woven Textile in Wind Energy Market

The woven textile in the wind energy industry offers a multitude of expansion opportunities. Such opportunities are influenced by factors such as the increase in renewable energy consumption, growth in technology, and initiation of efficiency and sustainability campaigns. In the paragraphs that follow, the five such opportunities that are likely to shape the market have been elaborated.

• Development of offshore wind energy: Offshore wind energy is developing rapidly and it paves the way for the consumption of woven textiles that are built for corrosion, extreme weather, marine environment, and so on. The blade textiles for offshore turbines must provide great mechanical properties and be very lightweight. These advanced textile solutions will continue to be in demand as the offshore wind industry develops in key regions such as Europe, Japan, and the USA and there will be an unlimited flow of opportunities for innovation and growth of the market.
• Incorporating Recycled and Sustainable Materials: As new blades for wind turbines continue to be designed in a more environmentally friendly manner, the use of recycled woven textiles presents a significant business opportunity. Using recyclable and eco-friendly raw materials, manufacturers can fulfill the requirements of sustainability without increasing the carbon emission level when producing wind turbines. Firms intending to manufacture environment-friendly composite materials will benefit from the industry trend that seeks cleaner energy production solutions and disposal of end-of-life blades.
• Technological Development in Production Mode: The construction of wind turbines increases the demand for woven textile products due to the introduction of automation and digital technologies. A few examples include smart manufacturing technologies including 3D printing, automated weaving technologies, and the advent of technologies that support turboprop blade manufacturing thus enhancing efficiency, cutting costs, and reducing lead time for blades. Such advances enable the production of complex, high-performance textiles with high volumes and lower costs which are increasingly required by the market for wind turbine components.
• Engineered or Top-Performers Used In Design and Beg Manufacturing Demand is Increasing: With the growing size of wind turbines, the need for stronger, lighter, and more durable blades increases as well. Woven textiles that can enhance the mechanical properties of wind turbine blades present a huge growth potential. With the development of hybrid textiles and their inclusion of carbon and glass fibers, the industries will be able to satisfy the technical demands of the bigger turbines. This especially crosses over to both onshore and offshore markets, where bigger and more efficient turbines are becoming more of a standard rather than an exception.
• Attention to Establishing Wind Energy Sectors in Developing Countries: Additional regions like India rendering additional growth regions for woven textiles applications in wind energy include Brazil and Southeast Asia. The countries, since they are eager to increase their renewable energy capacity, create an appetite for practicality and affordability in the production of textile materials for wind turbines. Such markets offer opportunities for businesses to increase their presence especially where there is adequate wind potential but the marketing of modern wind turbine materials is low.

These growth opportunities will help in the effective growth of the woven textile market within the wind energy market. These industries can take advantage of new materials, new manufacturing technologies, and fostering sustainability practices, which will not only advocate a shift to renewable energy but also help improve and reduce costs of the wind turbines.

Woven Textile in Wind Energy Market Driver and Challenges

There are certain key factors, whether economic, technological, or regulatory, that help position woven textiles in the wind energy market. These drivers and challenges dictate the overall environment and define the rate of technological advancement and growth of the market. Some of the driving forces and challenges are listed below.

The factors responsible for driving the woven textile market in the wind energy sector include:

• Technological Advancements in Materials Science: Thanks to materials science, particularly the new applications of high-strength, lightweight woven textiles, the wind energy sector is expanding. These developments in wind turbine blades result in higher efficiencies and lower energy generation costs since superior, lighter blades are produced. The continuous advancement of woven composite materials is critically important for meeting the performance criteria of modern wind turbines, especially in offshore and large-scale wind turbine applications.
• Rising Consumption of Renewable Sources: Global policies targeting emissions reduction and the shift to renewable energy are significant drivers for the use of woven textiles in wind turbine production. As more governments invest in wind energy, there is a growing demand for advanced materials that would increase turbine effectiveness and efficiency. Due to the increasing focus on sustainability, more funds are being directed toward the acquisition of woven textiles in the wind energy sector.
• Cost Reductions in Production: Competition within the wind energy market is intense, and lowering the cost of energy from wind is a key goal. Woven textiles contribute to this by making turbine blades lighter, which reduces transportation and installation costs. The cost-effectiveness of textile materials has improved due to advancements in the technologies used to manufacture these textiles, leading to their increased use in the wind energy industry.
• Expanding Offshore Wind Energy Sector: There has been a rapid increase in offshore wind energy projects, creating opportunities for woven textiles designed to withstand marine exposure. These textiles are essential for producing lightweight, durable, and corrosion-resistant turbine blades for effective offshore deployment. The market potential for woven textile manufacturers is significant, driven by the steady increase in offshore wind energy projects, especially in Europe and Asian markets.
• Environmental Regulation and Sustainability Objectives: The softening of environmental impact policies and agreements is driving the wind energy industry to become more eco-friendly. The development of these ecologically sustainable, recyclable woven materials helps industries comply with regulations and contributes to the fight against pollution and carbon footprints. The demand for these textiles is expected to grow as sustainability becomes more critical. Accepted taxation and pollution restrictions will encourage industries to adopt greener materials.

Challenges in the woven textile market in the wind energy sector include:

• High Cost of Initial Investment: Although woven textiles offer significant versatility, the initial production costs of these materials are higher than traditional alternatives. This may hinder widespread adoption, especially in regions or markets with limited financial resources. While there are expectations that costs will decrease over time due to improvements in the manufacturing process, the initial capital investment remains a major obstacle.
• Supply Chain Constraints: Politics, trade issues, and natural disasters can disrupt the international sourcing of raw materials for woven textiles, such as carbon fibers and glass. These interruptions can lead to material shortages and price increases, delaying the production of wind turbine blades and affecting the wind energy market.
• Technical Challenges in Scaling Production: Increasing the production of high-performance woven textiles to meet the growing demand in the wind energy market has proven challenging. Manufacturers are struggling to adjust mass production techniques to efficiently produce large, high-quality, and consistent volumes. Developing capabilities to scale production will require significant effort, including the use of more automated methods for fabricating these materials.

The woven textile market in wind energy is supported by several strong drivers, but it also faces significant challenges. Technological development and the growing role of renewable energy worldwide are major drivers, while high costs and supply chain issues are barriers. Overcoming these challenges will be critical in determining the future of woven textiles in the wind energy market.

List of Woven Textile Companies in Wind Energy Market

Companies in the market compete on the basis of product quality offered. Major players in this market focus on expanding their manufacturing facilities, R&D investments, infrastructural development, and leverage integration opportunities across the value chain. Through these strategies woven textile companies in wind energy market cater increasing demand, ensure competitive effectiveness, develop innovative products & technologies, reduce production costs, and expand their customer base. Some of the woven textile companies in wind energy market profiled in this report include-

• Owens Corning
• Jushi Group
• Chongqing Polycomp International Corporation
• Taishan Fiberglass
• Taiwan Glass Group
• Nippon Electric Glass
• Sichuan Weibo
• 3B the Fiber Glass Company ( Goa Glass Fiber)
• Johns Manville Corporation
• Nitto Boseki

Woven Textile in Wind Energy by Segment

The study includes a forecast for the global woven textile in wind energy by product type, application, and region.

Woven Textile in Wind Energy Market by Product Type [Analysis by Value from 2018 to 2030]:

• Woven Roving
• Woven Yarn

Woven Textile in Wind Energy Market by Application [Analysis by Value from 2018 to 2030]:

• Windmill Blades
• Others

Woven Textile in Wind Energy Market by Region [Analysis by Value from 2018 to 2030]:

• North America
• Europe
• Asia Pacific
• The Rest of the World

Country Wise Outlook for the Woven Textile in Wind Energy Market

The demand for woven textiles in the wind energy market is growing steadily due to the need for renewable energy, advancements in materials engineering, and the quest for new technology to improve wind turbines. Woven textiles, especially woven fabrics for wind turbine blades and composites, are also becoming important elements in weight reduction, structural reinforcement, and performance enhancement. In major global markets including the United States, China, Germany, India, and Japan, there are interesting trends in the use of woven textiles for wind energy purposes, showing progress in material science as well as changing energy technology. The gradually evolving statement should be contextualized with a systematic assessment of current achievements in these countries.

• United States: Americans are employing woven textiles to help make wind turbines, especially lightweight, high-strength materials, more efficient. The United States Department of Energy (US DoE) has also pursued research on advanced composite materials, such as woven textiles, to improve blade performance while lowering manufacturing expenses. GE Renewable Energy, Siemens Gamesa, and other companies are working on the implementation of these materials in future wind turbine blades. Furthermore, the potential for blades to be made from recovered textiles is being explored, aligning with broader trends of environmentally friendly manufacturing in the wind energy sector.
• China: As the largest country in terms of wind power turbine manufacturing in the world, China is focused on advancing its wind energy industry through investment in woven textile technologies. Advanced woven composites for turbine blades have been embraced by manufacturers in China to improve production efficiency. Almost all of them emphasize the importance of frame-out laminate programs, which focus on improving the tensile strength and durability of textiles.
• Germany: Germany is at the forefront of using the latest technology to develop renewable energy options, including wind energy. Over the past few years, German companies have been exploring innovative woven composites that make it possible to manufacture lightweight yet sturdy wind turbine blades capable of enduring extreme conditions. Hybrid woven composites under development incorporate advanced fibers such as carbon and glass with conventional fabrics to enhance functionality. The main objective of these developments is to increase blade sizes and improve efficiency.
• India: Wind power generation in India is growing quickly, and woven textile technology is expected to play an important role in this expansion. Industrial firms in India are utilizing woven composites to create more streamlined wind turbine blades capable of withstanding the tough wind regimes experienced in coastal areas. Collaborations between private companies and universities in the region are fostering creativity in this sector. At the same time, promoting the use of woven textile materials within the country, in line with the "Make in India" campaign, will reduce the reliance on foreign woven composites.
• Japan: Japan is leading the way in the adaptation of woven materials in the wind energy industry, particularly in offshore wind farms. Woven materials are essential in such applications to create lightweight, corrosion-proof materials that can withstand extreme ocean conditions. Japanese companies are also focusing on using woven materials in the internal structure of turbine blades to reduce weight without compromising strength. The market for such advanced textile composites is becoming increasingly important for Japan as it pursues larger offshore wind energy capacity to meet its ambitious renewable energy goals.

Features of the Global Woven Textile in Wind Energy Market

Market Size Estimates: Woven textile in wind energy market size estimation in terms of value ($B).

Trend and Forecast Analysis: Market trends (2018 to 2023) and forecast (2024 to 2030) by various segments and regions.

Segmentation Analysis: Woven textile in wind energy market size by product type, application, and region in terms of value ($B).

Regional Analysis: Woven textile in wind energy market breakdown by North America, Europe, Asia Pacific, and Rest of the World.

Growth Opportunities: Analysis of growth opportunities in different product types, applications, and regions for the woven textile in wind energy market.

Strategic Analysis: This includes M&A, new product development, and competitive landscape of the woven textile in wind energy market.

Analysis of competitive intensity of the industry based on Porter's Five Forces model.

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This report answers following 11 key questions:

• Q.1. What are some of the most promising, high-growth opportunities for the woven textile in wind energy market by product type (woven roving and woven yarn), application (windmill blades and others), and region (North America, Europe, Asia Pacific, and the Rest of the World)?
• Q.2. Which segments will grow at a faster pace and why?
• Q.3. Which region will grow at a faster pace and why?
• Q.4. What are the key factors affecting market dynamics? What are the key challenges and business risks in this market?
• Q.5. What are the business risks and competitive threats in this market?
• Q.6. What are the emerging trends in this market and the reasons behind them?
• Q.7. What are some of the changing demands of customers in the market?
• Q.8. What are the new developments in the market? Which companies are leading these developments?
• Q.9. Who are the major players in this market? What strategic initiatives are key players pursuing for business growth?
• Q.10. What are some of the competing products in this market and how big of a threat do they pose for loss of market share by material or product substitution?
• Q.11. What M&A activity has occurred in the last 5 years and what has its impact been on the industry?

Table of Contents

1. Executive Summary

2. Global Woven Textile in Wind Energy Market : Market Dynamics

• 2.1: Introduction, Background, and Classifications
• 2.2: Supply Chain
• 2.3: Industry Drivers and Challenges

3. Market Trends and Forecast Analysis from 2018 to 2030

• 3.1. Macroeconomic Trends (2018-2023) and Forecast (2024-2030)
• 3.2. Global Woven Textile in Wind Energy Market Trends (2018-2023) and Forecast (2024-2030)
• 3.3: Global Woven Textile in Wind Energy Market by Product Type
  • 3.3.1: Woven Roving
  • 3.3.2: Woven Yarn
• 3.4: Global Woven Textile in Wind Energy Market by Application
  • 3.4.1: Windmill Blades
  • 3.4.2: Others

4. Market Trends and Forecast Analysis by Region from 2018 to 2030

• 4.1: Global Woven Textile in Wind Energy Market by Region
• 4.2: North American Woven Textile in Wind Energy Market
  • 4.2.1: North American Market by Product Type: Woven Roving and Woven Yarn
  • 4.2.2: North American Market by Application: Windmill Blades and Others
• 4.3: European Woven Textile in Wind Energy Market
  • 4.3.1: European Market by Product Type: Woven Roving and Woven Yarn
  • 4.3.2: European Market by Application: Windmill Blades and Others
• 4.4: APAC Woven Textile in Wind Energy Market
  • 4.4.1: APAC Market by Product Type: Woven Roving and Woven Yarn
  • 4.4.2: APAC Market by Application: Windmill Blades and Others
• 4.5: ROW Woven Textile in Wind Energy Market
  • 4.5.1: ROW Market by Product Type: Woven Roving and Woven Yarn
  • 4.5.2: ROW Market by Application: Windmill Blades and Others

5. Competitor Analysis

• 5.1: Product Portfolio Analysis
• 5.2: Operational Integration
• 5.3: Porter's Five Forces Analysis

6. Growth Opportunities and Strategic Analysis

• 6.1: Growth Opportunity Analysis
  • 6.1.1: Growth Opportunities for the Global Woven Textile in Wind Energy Market by Product Type
  • 6.1.2: Growth Opportunities for the Global Woven Textile in Wind Energy Market by Application
  • 6.1.3: Growth Opportunities for the Global Woven Textile in Wind Energy Market by Region
• 6.2: Emerging Trends of the Global Woven Textile in Wind Energy Market
• 6.3: Strategic Analysis
  • 6.3.1: New Product Development
  • 6.3.2: Capacity Expansion of the Global Woven Textile in Wind Energy Market
  • 6.3.3: Mergers, Acquisitions, and Joint Ventures for the Global Woven Textile in Wind Energy Market
  • 6.3.4: Certification and Licensing

7. Company Profiles of Leading Players

• 7.1: Owens Corning
• 7.2: Jushi Group
• 7.3: Chongqing Polycomp International Corporation
• 7.4: Taishan Fiberglass
• 7.5: Taiwan Glass Group
• 7.6: Nippon Electric Glass
• 7.7: Sichuan Weibo
• 7.8: 3B the Fiber Glass Company ( Goa Glass Fiber)
• 7.9: Johns Manville Corporation
• 7.10: Nitto Boseki