风力涡轮机复合材料市场机会、成长动力、产业趋势分析及 2025 - 2034 年预测

2024 年全球风力涡轮机复合材料市场规模将达到 143 亿美元，预计 2025 年至 2034 年期间将以 6.5% 的强劲复合年增长率增长。复合材料在风力涡轮机叶片、机舱和其他关键零件的设计和生产中发挥着重要作用。它们具有出色的强度、轻盈性和耐用性，使其成为风力涡轮机恶劣运行条件的理想选择。这些材料不仅有助于提高涡轮机的性能和使用寿命，而且还有助于提高风能的成本效益和永续性。随着再生能源专案在全球的扩张，风力涡轮机製造对复合材料的需求将会增加，从而加速产业成长。

风力涡轮机复合材料市场主要按纤维类型细分，其中碳纤维、玻璃纤维和其他纤维是主要类别。其中，玻璃纤维引领市场，2024年创造92亿美元的收入。玻璃纤维具有优异的抗拉强度、耐腐蚀性和轻量化设计，这些都是生产高效耐用的涡轮叶片和机舱的关键特性。随着风能产业越来越注重提高涡轮机的性能，对更长、更耐用的叶片的需求也越来越大，这反过来又推动了玻璃纤维增强复合材料的采用。

另一个关键的细分市场是基于製造方法，包括手工铺层、真空注塑、预浸料等。其中，真空注塑成型占据最大的市场份额，2024 年占 44.3%。真空注塑成型在製造涡轮叶片方面特别有效，因为它具有提高能源效率所需的精度、耐用性和轻量化特性。此外，该技术可增强树脂渗透性，减少材料浪费，并加快生产速度，满足风能领域对可扩展且经济高效的製造日益增长的需求。

在美国，风力涡轮机复合材料市场的价值在 2024 年将达到 42 亿美元。联邦政策，包括对风能项目的税收抵免和激励措施，在促进风电场安装方面发挥了重要作用，从而推动了对涡轮机生产中使用的复合材料的需求。此外，製造技术的进步和国内复合材料供应商的存在进一步支持了市场扩张，提高了成本效率并确保了美国风能产业的持续成长

目录

第 1 章：方法论与范围

• 市场范围和定义
• 基础估算与计算
• 预测计算
• 资料来源
  • 基本的
  • 次要
    • 付费来源
    • 公共资源

第 2 章：执行摘要

第 3 章：产业洞察

• 产业生态系统分析
  • 影响价值链的因素
  • 利润率分析
  • 中断
  • 未来展望
  • 製造商
  • 经销商
• 供应商概况
• 利润率分析
• 重要新闻及倡议
• 监管格局
• 衝击力
  • 成长动力
    • 再生能源需求不断成长
    • 复合材料的技术进步
    • 降本增效
  • 产业陷阱与挑战
    • 初期投资高
    • 耐用性和长期性能
• 成长潜力分析
• 波特的分析
• PESTEL 分析

第四章：竞争格局

• 介绍
• 公司市占率分析
• 竞争定位矩阵
• 战略展望矩阵

第 5 章：市场估计与预测：按纤维类型，2021-2034 年

• 主要趋势
• 玻璃纤维
• 碳纤维
• 其他（芳纶纤维、玄武岩纤维）

第 6 章：市场估计与预测：按技术，2021 年至 2034 年

• 主要趋势
• 真空注塑
• 预浸料
• 手工铺层
• 其他（热压罐成型、纤维缠绕）

第 7 章：市场估计与预测：按应用，2021 年至 2034 年

• 主要趋势
• 风力叶片
• 机舱
• 其他（内部组件、旋转器和轮圈盖）

第 8 章：市场估计与预测：按地区，2021 年至 2034 年

• 主要趋势
• 北美洲
  • 我们
  • 加拿大
• 欧洲
  • 英国
  • 德国
  • 法国
  • 义大利
  • 西班牙
  • 俄罗斯
• 亚太地区
  • 中国
  • 印度
  • 日本
  • 韩国
  • 澳洲
• 拉丁美洲
  • 巴西
  • 墨西哥
• 中东及非洲
  • 南非
  • 沙乌地阿拉伯
  • 阿联酋

第九章：公司简介

• AOC Aliancys
• Evonik Industries
• Gurit Holding
• Henkel
• Hexcel Corporation
• Hexion
• Huntsman
• Mitsubishi Chemical
• Owens Corning
• SABIC
• SGL Carbon
• Solvay
• Teijin Limited
• Toray Industries
• Zoltek Companies

The Global Wind Turbine Composite Materials Market reached USD 14.3 billion in 2024 and is expected to grow at a robust CAGR of 6.5% from 2025 to 2034. As the world's demand for renewable energy solutions continues to rise, the need for innovative materials to produce efficient wind turbines becomes increasingly critical. Composite materials play an essential role in the design and production of wind turbine blades, nacelles, and other key components. Their remarkable combination of strength, lightness, and durability makes them ideal for the harsh operating conditions faced by wind turbines. These materials not only help improve the performance and longevity of turbines but also contribute to making wind energy more cost-effective and sustainable. With renewable energy projects expanding globally, the demand for composite materials in wind turbine manufacturing is set to increase, accelerating industry growth.

The market for wind turbine composite materials is primarily segmented by fiber type, with carbon fiber, glass fiber, and others as the key categories. Of these, glass fiber leads the market, generating USD 9.2 billion in revenue in 2024. This segment is also expected to experience the fastest growth due to its cost-effectiveness and exceptional versatility. Glass fiber offers superior tensile strength, corrosion resistance, and a lightweight design, which are critical attributes for producing efficient and durable turbine blades and nacelles. As the wind energy sector increasingly focuses on improving turbine performance, there is a growing demand for longer, more durable blades, which in turn drives the adoption of glass fiber-reinforced composites.

Another key market segment is based on manufacturing methods, which include hand lay-up, vacuum injection molding, prepreg, and others. Among these, vacuum injection molding commands the largest market share, accounting for 44.3% in 2024. This manufacturing process is gaining traction due to its ability to produce large-scale components with superior mechanical properties and fewer defects. Vacuum injection molding is particularly effective in crafting turbine blades, as it offers precision, durability, and the lightweight characteristics necessary to improve energy efficiency. Furthermore, the technique allows for enhanced resin penetration, reduced material waste, and faster production speeds, meeting the growing demand for scalable and cost-efficient manufacturing in the wind energy sector.

In the United States, the wind turbine composite materials market was valued at USD 4.2 billion in 2024. This market is experiencing impressive growth, fueled by the nation's strong push toward renewable energy adoption and its commitment to transitioning to a low-carbon economy. Federal policies, including tax credits and incentives for wind energy projects, have played a significant role in boosting wind farm installations, thus driving the demand for composite materials used in turbine production. In addition, advancements in manufacturing technologies and the presence of domestic suppliers of composite materials have further supported market expansion, enhancing cost-efficiency and ensuring the continued growth of the wind energy industry in the U.S.

Table of Contents

Chapter 1 Methodology & Scope

• 1.1 Market scope & definitions
• 1.2 Base estimates & calculations
• 1.3 Forecast calculations
• 1.4 Data sources
  • 1.4.1 Primary
  • 1.4.2 Secondary
    • 1.4.2.1 Paid sources
    • 1.4.2.2 Public sources

Chapter 2 Executive Summary

• 2.1 Industry synopsis, 2021-2034

Chapter 3 Industry Insights

• 3.1 Industry ecosystem analysis
  • 3.1.1 Factor affecting the value chain
  • 3.1.2 Profit margin analysis
  • 3.1.3 Disruptions
  • 3.1.4 Future outlook
  • 3.1.5 Manufacturers
  • 3.1.6 Distributors
• 3.2 Supplier landscape
• 3.3 Profit margin analysis
• 3.4 Key news & initiatives
• 3.5 Regulatory landscape
• 3.6 Impact forces
  • 3.6.1 Growth drivers
    • 3.6.1.1 Increasing demand for renewable energy
    • 3.6.1.2 Technological advancements in composite materials
    • 3.6.1.3 Cost reduction and efficiency improvement
  • 3.6.2 Industry pitfalls & challenges
    • 3.6.2.1 High initial investment
    • 3.6.2.2 Durability and long-term performance
• 3.7 Growth potential analysis
• 3.8 Porter’s analysis
• 3.9 PESTEL analysis

Chapter 4 Competitive Landscape, 2024

• 4.1 Introduction
• 4.2 Company market share analysis
• 4.3 Competitive positioning matrix
• 4.4 Strategic outlook matrix

Chapter 5 Market Estimates & Forecast, By Fiber Type, 2021-2034 (USD Billion) (Kilo Tons)

• 5.1 Key trends
• 5.2 Glass fiber
• 5.3 Carbon fiber
• 5.4 Others (aramid fiber, basalt fiber)

Chapter 6 Market Estimates & Forecast, By Technology, 2021-2034 (USD Billion) (Kilo Tons)

• 6.1 Key trends
• 6.2 Vacuum injection molding
• 6.3 Prepreg
• 6.4 Hand lay-up
• 6.5 Other (autoclave molding, filament winding)

Chapter 7 Market Estimates & Forecast, By Application, 2021-2034 (USD Billion) (Kilo Tons)

• 7.1 Key trends
• 7.2 Wind blades
• 7.3 Nacelles
• 7.4 Others (internal components, spinners and hub covers)

Chapter 8 Market Estimates & Forecast, By Region, 2021-2034 (USD Billion) (Kilo Tons)

• 8.1 Key trends
• 8.2 North America
  • 8.2.1 U.S.
  • 8.2.2 Canada
• 8.3 Europe
  • 8.3.1 UK
  • 8.3.2 Germany
  • 8.3.3 France
  • 8.3.4 Italy
  • 8.3.5 Spain
  • 8.3.6 Russia
• 8.4 Asia Pacific
  • 8.4.1 China
  • 8.4.2 India
  • 8.4.3 Japan
  • 8.4.4 South Korea
  • 8.4.5 Australia
• 8.5 Latin America
  • 8.5.1 Brazil
  • 8.5.2 Mexico
• 8.6 MEA
  • 8.6.1 South Africa
  • 8.6.2 Saudi Arabia
  • 8.6.3 UAE

Chapter 9 Company Profiles

• 9.1 AOC Aliancys
• 9.2 Evonik Industries
• 9.3 Gurit Holding
• 9.4 Henkel
• 9.5 Hexcel Corporation
• 9.6 Hexion
• 9.7 Huntsman
• 9.8 Mitsubishi Chemical
• 9.9 Owens Corning
• 9.10 SABIC
• 9.11 SGL Carbon
• 9.12 Solvay
• 9.13 Teijin Limited
• 9.14 Toray Industries
• 9.15 Zoltek Companies