Global Structural Adhesive for Wind Turbine Blades Market Research Report, Competitive, Technology and Forecast Analysis 2025-2032

Market Overview

According to DIResearch＇s in-depth investigation and research, the global Structural Adhesive for Wind Turbine Blades market size will reach 707.68 Million USD in 2025 and is projected to reach 1,195.65 Million USD by 2032, with a CAGR of 7.78% (2025-2032). Notably, the China Structural Adhesive for Wind Turbine Blades market has changed rapidly in the past few years. By 2025, China＇s market size is expected to be  Million USD, representing approximately  % of the global market share.

Research Summary

Structural adhesives for wind turbine blades are specialized bonding materials used to join various components of the blade together, such as the spar caps, shear webs, and blade shells. These adhesives are designed to provide high strength, durability, and fatigue resistance to withstand the extreme forces experienced by wind turbine blades during operation. Typically, epoxy resins are used as the base material for these adhesives, combined with additives to enhance properties such as flexibility, toughness, and adhesion to composite materials like fiberglass or carbon fiber. The adhesives are applied in a controlled manner to ensure proper bonding and uniform distribution throughout the blade structure. Structural adhesives play a crucial role in ensuring the structural integrity and performance of wind turbine blades, contributing to the reliability and efficiency of wind energy generation.

The major global  manufacturers of Structural Adhesive for Wind Turbine Blades include Kangda New Materials, Westlake Chemical, Techstorm Advanced Material, Olin Corporation, Polynt-Reichhold, Aditya Birla Chemical, Sika, Huntsman, Henkel, Lord Corporation, H.B. Fuller, Bostik, etc. The global players competition landscape in this report is divided into three tiers. The first tier comprises global leading enterprises that command a substantial market share, hold a dominant industry position, possess strong competitiveness and influence, and generate significant revenue. The second tier includes companies with a notable market presence and reputation; these firms actively follow industry leaders in product, service, or technological innovation and maintain a moderate revenue scale. The third tier consists of smaller companies with limited market share and lower brand recognition, primarily focused on local markets and generating comparatively lower revenue.

This report studies the market size, price trends and future development prospects of Structural Adhesive for Wind Turbine Blades. Focus on analysing the market share, product portfolio, prices, sales, revenue and gross profit margin of global major manufacturers, as well as the market status and trends of different product types and applications in the global Structural Adhesive for Wind Turbine Blades market. The report data covers historical data from 2020 to 2024, based year in 2025 and forecast data from 2026 to 2032.

The regions and countries in the report include US, Germany, Japan, China, France, UK, South Korea, Canada, Italy, Russia, Mexico, Brazil, India, Vietnam, Thailand, South Africa and other regions, covering the Structural Adhesive for Wind Turbine Blades market conditions and future development trends of key regions and countries, combined with industry-related policies and the latest technological developments, analyze the development characteristics of Structural Adhesive for Wind Turbine Blades industries in various regions and countries, help companies understand the development characteristics of each region, help companies formulate business strategies, and achieve the ultimate goal of the company's global development strategy.    

The data sources of this report mainly include the National Bureau of Statistics, customs databases, industry associations, corporate financial reports, third-party databases, etc. Among them, macroeconomic data mainly comes from the National Bureau of Statistics, International Economic Research Organization; industry statistical data mainly come from industry associations; company data mainly comes from interviews, public information collection, third-party reliable databases, and price data mainly comes from various markets monitoring database.

Global Key Manufacturers of Structural Adhesive for Wind Turbine Blades Include:

Kangda New Materials

Westlake Chemical

Techstorm Advanced Material

Olin Corporation

Polynt-Reichhold

Aditya Birla Chemical

Sika

Huntsman

Henkel

Lord Corporation

H.B. Fuller

Bostik

Structural Adhesive for Wind Turbine Blades Product Segment Include:

Epoxy Structural Adhesive

Vinyl Structural Adhesive

Polyurethane Structural Adhesive

Structural Adhesive for Wind Turbine Blades Product Application Include:

Below 2.0 MW Wind Turbine Blades

2.0-3.0 MW Wind Turbine Blades

3.0-5.0 MW Wind Turbine Blades

Above 5.0 MW Wind Turbine Blades

Chapter Scope

Chapter 1: Product Research Range, Product Types and Applications, Market Overview, Market Situation and Trend

Chapter 2: Global Structural Adhesive for Wind Turbine Blades Capacity and Production Analysis

Chapter 3: Global Structural Adhesive for Wind Turbine Blades Industry PESTEL Analysis

Chapter 4: Global Structural Adhesive for Wind Turbine Blades Industry Porter's Five Forces Analysis

Chapter 5: Global Structural Adhesive for Wind Turbine Blades Major Regional Market Size (Sales, Revenue, Price) and Forecast Analysis

Chapter 6: Global Structural Adhesive for Wind Turbine Blades Competitive Analysis of Key Manufacturers (Sales, Revenue, Market Share, Price, Regional Distribution and Industry Concentration)

Chapter 7: Global Structural Adhesive for Wind Turbine Blades Sales, Revenue, Price and Forecast by Product Type

Chapter 8: Key Company Profiles (Product Portfolio, Sales, Revenue, Price and Gross Margin)

Chapter 9: Industrial Chain Analysis, Structural Adhesive for Wind Turbine Blades Different Application Market Analysis (Sales and Revenue), Sales Channel Analysis

Chapter 10: Research Findings and Conclusion

Chapter 11: Methodology and Data Sources Show more