Wind Turbine Scrap Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Recycling Process (Mechanical Recycling, Thermal Recycling, Chemical Recycling, Landfilling), By Component (Blades, Nacelle, Tower, Generator, Gearbox, Others), By Application (Construction, Automotive, Aerospace, Energy, Others), By Region & Competition, 2020-2030F

Market Overview

Global Wind Turbine Scrap Market was valued at USD 8.46 billion in 2024 and is expected to reach USD 14.26 billion by 2030 with a CAGR of 8.93% during the forecast period.

The Wind Turbine Scrap Market refers to the industry focused on the recovery, recycling, and repurposing of materials from decommissioned or damaged wind turbines, including components such as blades, towers, nacelles, and generators. With the global expansion of wind energy over the past two decades, a significant number of turbines are now approaching or have reached the end of their operational life, creating a substantial volume of waste.

This market primarily addresses environmental concerns related to turbine disposal, especially the non-biodegradable composite materials used in blades, while also unlocking economic opportunities through the extraction of valuable metals such as steel, copper, and aluminum. The market is witnessing a surge in activity due to increased investments in circular economy practices, stringent environmental regulations regarding landfill restrictions, and advancements in recycling technologies such as pyrolysis, mechanical processing, and chemical recovery.

Additionally, the emergence of second-life applications for recovered materials in construction, automotive, and consumer goods industries is driving further growth. Government policies in Europe and North America promoting zero-waste and extended producer responsibility are accelerating the adoption of structured turbine dismantling and recycling programs. Furthermore, wind farm operators and original equipment manufacturers are increasingly entering partnerships with recycling firms to ensure sustainable end-of-life management and reduce their environmental footprint.

The market is also supported by the rapid installation of new wind farms, which ensures a consistent flow of end-of-life turbines in the future. Innovations in blade recycling, such as cement co-processing and reuse in infrastructure projects, are expanding the potential of this market beyond traditional scrap management. In addition, the Asia Pacific region is emerging as a significant growth area, driven by high wind energy installations in countries such as China and India and their evolving regulatory frameworks around industrial waste. As the global push for clean energy intensifies, the Wind Turbine Scrap Market is expected to rise steadily, turning a potential environmental burden into a value-driven opportunity for sustainable growth.

Key Market Drivers

 Increasing Decommissioning of Aging Wind Turbines

The global wind energy sector has seen substantial growth over the past few decades, resulting in a significant number of wind turbines approaching the end of their operational lifespans, typically 20-25 years. As these turbines are decommissioned, the volume of scrap materials, including metals, composites, and other components, is rising, driving the demand for specialized scrap management and recycling services.

The surge in decommissioning is fueled by the rapid expansion of wind energy installations in the early 2000s, particularly in regions like Europe and North America, where early-generation turbines are now being retired. Governments and energy companies are prioritizing sustainable disposal and recycling to mitigate environmental impacts, aligning with global sustainability goals. This trend is amplified by the need to replace older, less efficient turbines with advanced models, further increasing scrap volumes.

The Wind Turbine Scrap Market benefits from this cyclical turnover, as operators seek cost-effective and environmentally responsible solutions for end-of-life turbine management. Technological advancements in recycling processes, such as mechanical and thermal methods, are enhancing the feasibility of handling complex composite materials, making the market more viable. Additionally, regulatory frameworks are pushing for responsible waste management, compelling operators to engage with scrap market services to comply with environmental standards.

The International Renewable Energy Agency (IRENA) reports that global wind power capacity reached 837 gigawatts by 2022, with approximately 30% of installed turbines over 15 years old. By 2030, an estimated 100,000 turbines worldwide will require decommissioning, generating over 10 million tons of scrap materials, including 2.5 million tons of composite blades, necessitating robust scrap management solutions.

Stringent Environmental Regulations and Sustainability Goals

Governments worldwide are implementing stringent environmental regulations to address waste management and promote a circular economy, significantly driving the Wind Turbine Scrap Market. Policies mandating the responsible disposal and recycling of wind turbine components, particularly composite blades, are pushing operators to adopt sustainable practices. These regulations aim to minimize landfill use and environmental pollution caused by decommissioned turbine materials. For instance, the European Union’s Waste Framework Directive emphasizes recycling and reuse, compelling wind farm operators to partner with specialized scrap management firms.

The global push for net-zero carbon emissions by 2050 further accelerates demand for recycling services, as stakeholders seek to align with sustainability targets. This regulatory pressure is coupled with growing public and corporate awareness of environmental impacts, encouraging investments in advanced recycling technologies. The market is responding by developing innovative solutions to process difficult-to-recycle materials like fiberglass and carbon fiber, ensuring compliance and fostering long-term sustainability. As a result, the Wind Turbine Scrap Market is positioned as a critical component of the renewable energy ecosystem, supporting the industry’s commitment to environmental stewardship.

According to the European Commission, by 2025, approximately 14,000 wind turbine blades will be decommissioned in Europe, generating 40,000 to 60,000 tons of composite waste. EU regulations require at least 85% of wind turbine materials to be recycled or reused, driving a projected 20% annual increase in demand for scrap processing services through 2030.

Technological Advancements in Recycling Processes

The development of advanced recycling technologies is a key driver for the Wind Turbine Scrap Market, enabling efficient handling of complex materials like composite blades, steel, and copper. Innovations in mechanical, thermal, and chemical recycling methods are improving the recovery rates of valuable materials, making scrap management economically viable. For example, thermal recycling processes, such as pyrolysis, allow for the breakdown of composite materials into reusable fibers and resins, which can be repurposed in industries like construction and automotive.

These advancements reduce the reliance on landfilling and enhance the circular economy by creating secondary raw materials markets. Companies are investing in research and development to optimize recycling efficiency, driven by the increasing volume of decommissioned turbines. The adoption of automation and artificial intelligence in sorting and processing scrap further streamlines operations, reducing costs and improving scalability. As these technologies mature, they attract more stakeholders to the Wind Turbine Scrap Market, fostering growth and ensuring the industry can handle the rising influx of end-of-life turbine materials.

The Global Wind Energy Council (GWEC) estimates that advancements in recycling technologies could recover up to 90% of composite materials from wind turbine blades by 2030. In 2024, over 500,000 tons of decommissioned turbine materials were processed globally, with 60% of metals and 30% of composites successfully recycled, boosting market growth.

Rising Global Wind Energy Capacity

The rapid expansion of global wind energy capacity is a significant driver for the Wind Turbine Scrap Market, as increased installations lead to a future surge in decommissioning needs. Countries like China, the United States, and India are leading the charge in wind farm development, supported by government incentives and renewable energy targets. As new turbines are installed, the eventual retirement of these units ensures a steady pipeline of scrap materials.

This growth is particularly pronounced in offshore wind, where larger turbines generate substantial scrap volumes upon decommissioning. The market is further driven by the replacement of older turbines with higher-capacity models, accelerating the scrapping process. The economic benefits of recycling valuable materials, such as steel and copper, also incentivize operators to engage with the scrap market. As wind energy continues to play a pivotal role in the global energy transition, the Wind Turbine Scrap Market is poised for sustained growth, driven by the sheer scale of wind power expansion.

The Global Wind Energy Council reports that global wind power capacity grew from 743 gigawatts in 2020 to 837 gigawatts in 2022, with projections to reach 1,900 gigawatts by 2025. This expansion is expected to generate 15 million tons of scrap materials by 2035, with 40% originating from offshore wind farms.

Download Free Sample Report

Key Market Challenges

Complexity in Blade Recycling Due to Composite Materials

One of the most pressing challenges facing the Wind Turbine Scrap Market is the technical and logistical complexity involved in recycling wind turbine blades, primarily due to the materials used in their construction. Unlike towers and nacelles, which are predominantly made of recyclable metals such as steel and copper, wind turbine blades are manufactured using composite materials such as fiberglass-reinforced polymers, carbon fibers, and epoxy resins. These materials are chosen for their strength-to-weight ratio, durability, and resistance to fatigue. However, these same properties pose substantial difficulties in mechanical or chemical breakdown at the end of the blade’s service life.

Traditional recycling methods, such as mechanical grinding or incineration, are often unsuitable for composite materials. Mechanical grinding reduces the material to filler-grade substances, which significantly diminishes their economic value and limits reuse applications. Incineration, on the other hand, can lead to the release of hazardous emissions and is not considered environmentally sustainable. While alternative methods such as pyrolysis, fluidized bed processing, and cement co-processing are being developed and piloted, they remain capital-intensive and have not yet achieved widespread commercial scalability. These processes often require high temperatures and complex machinery, and in some cases, they fail to retain the integrity of the recovered materials, making them unsuitable for high-value applications.

Furthermore, the size and structure of turbine blades, which can exceed 80 meters in length, pose logistical hurdles in transportation and dismantling. Specialized equipment, trained labor, and careful dismantling protocols are required, particularly when blades are located in remote or offshore wind farms. This increases operational costs, delays project timelines, and reduces the overall profitability of recycling operations. The lack of standardized blade designs across manufacturers also adds variability, requiring customized recycling approaches that further complicate economies of scale. Consequently, a significant portion of decommissioned blades still ends up in landfills, undermining sustainability goals and limiting market potential. Until scalable, cost-effective, and environmentally sound solutions for composite blade recycling are developed and implemented, this issue will remain a major impediment to the growth of the Wind Turbine Scrap Market.

Regulatory Inconsistencies and Lack of Global Standardization

The Wind Turbine Scrap Market is also hindered by regulatory inconsistencies and a lack of global standardization regarding wind turbine decommissioning, waste classification, and recycling protocols. Across different regions and jurisdictions, there is a wide disparity in how wind turbine components, particularly composite materials, are categorized within waste management systems. In some countries, wind turbine blades are treated as industrial waste without specific regulations, whereas in others, they are subject to stringent environmental handling procedures. This regulatory fragmentation creates uncertainty for stakeholders and discourages cross-border collaboration and investment in recycling infrastructure.

For example, while the European Union has introduced regulations encouraging producer responsibility and landfill avoidance, many countries in Asia and Latin America lack specific legislative frameworks to address wind turbine waste. This results in inconsistent enforcement, limited accountability, and a lack of incentives for manufacturers and operators to proactively invest in end-of-life solutions. In the absence of harmonized policies, recycling companies face difficulties in forecasting market potential and return on investment, which hinders long-term planning and scalability.

Moreover, the absence of clear guidelines regarding material recovery targets, allowable recycling technologies, and certification standards further complicates the development of a unified and transparent market. This inconsistency affects not only recycling service providers but also original equipment manufacturers, wind farm operators, and local governments, leading to fragmented efforts and missed opportunities for collaborative solutions. Additionally, customs and trade barriers associated with exporting or importing scrap components for recycling across borders create logistical inefficiencies and legal complexities, especially in the case of offshore turbines located in international waters.

The current lack of a coordinated international approach also inhibits the development of centralized data systems and tracking mechanisms for end-of-life turbines, which are essential for establishing circular economy practices. Without these frameworks, the Wind Turbine Scrap Market remains reactive rather than proactive, undermining its ability to scale and contribute meaningfully to the sustainability agenda. Addressing this challenge will require intergovernmental cooperation, industry-led standard-setting, and the integration of circularity principles into energy policy.

Key Market Trends

Emergence of Cement Co-processing as a Blade Recycling Solution

One of the most notable trends in the Wind Turbine Scrap Market is the increasing adoption of cement co-processing as a viable solution for recycling wind turbine blades. Traditional recycling methods struggle to efficiently process the composite materials used in blade construction, such as fiberglass and epoxy resins. Cement co-processing presents a practical alternative by utilizing shredded turbine blade materials as a substitute for raw materials and fossil fuels in cement kilns. This process not only diverts composite waste from landfills but also contributes to energy savings and a reduction in carbon dioxide emissions within the cement industry.

Major recycling companies and cement manufacturers are now forming strategic collaborations to establish supply chains that support this process. For instance, several leading wind turbine original equipment manufacturers in Europe and North America have entered into agreements with cement firms to manage end-of-life blades through co-processing. These partnerships allow for the integration of sustainability goals across industries and align with the principles of the circular economy.

Moreover, regulatory bodies in Europe are increasingly recognizing cement co-processing as an environmentally responsible disposal method. This has led to the implementation of supportive policy frameworks that incentivize its use and provide the necessary environmental approvals. As a result, cement co-processing is gaining traction as a scalable and economically feasible solution in regions where landfill restrictions are tightening and environmental accountability is becoming more stringent.

Despite the progress, logistical challenges such as blade transportation and preprocessing remain. Nevertheless, the growing number of demonstration projects and full-scale commercial operations using cement co-processing indicate a clear market shift toward this technique. The long-term trend suggests that this method will become an integral component of turbine blade recycling strategies, especially as regulatory pressure and environmental awareness continue to rise. Overall, cement co-processing is positioned to play a central role in shaping the future of wind turbine blade disposal and recycling within the Wind Turbine Scrap Market.

Integration of Digital Platforms for Lifecycle Tracking and Asset Recovery

Another significant trend in the Wind Turbine Scrap Market is the growing integration of digital technologies for lifecycle tracking, asset management, and optimization of decommissioning processes. As wind turbines approach the end of their operational lifespan, stakeholders are increasingly turning to digital platforms and data-driven tools to ensure efficient and transparent scrap recovery. These platforms facilitate real-time monitoring of turbine components, enabling predictive maintenance, scheduling of dismantling operations, and accurate valuation of scrap materials.

The use of blockchain technology and cloud-based systems is gaining prominence in this space. These technologies are being deployed to create digital twins of wind turbine components, which track their usage history, maintenance records, and material composition. Such detailed data helps recyclers assess the condition of parts before decommissioning, enhancing recovery outcomes and reducing operational inefficiencies. Furthermore, these platforms improve traceability and compliance with environmental regulations by maintaining secure, tamper-proof documentation of waste handling processes

Several wind farm operators and recycling companies have begun to invest in these digital ecosystems to gain competitive advantage. The ability to forecast scrap volumes and material grades allows companies to streamline logistics, reduce waste, and better align with recycling partners. Additionally, integration with circular economy platforms enables the resale or repurposing of non-damaged components, adding further economic value to the scrap market.

Governments and environmental agencies are also showing interest in such systems for monitoring compliance and ensuring the accountability of wind energy operators. The standardization of data formats and interoperability of platforms are being promoted to facilitate cross-border collaboration and information sharing, particularly in regions with dense wind energy infrastructure.

As wind energy infrastructure continues to expand globally, the need for sophisticated end-of-life management tools becomes more pressing. The increasing reliance on digital platforms in the Wind Turbine Scrap Market is transforming how scrap materials are identified, recovered, and processed, contributing to a more sustainable and economically efficient recycling ecosystem.

Rise of Circular Economy Models in Wind Turbine End-of-Life Management

The Wind Turbine Scrap Market is undergoing a strategic transformation driven by the growing adoption of circular economy models. Unlike traditional linear disposal approaches, circular economy frameworks prioritize the reuse, refurbishment, and recycling of wind turbine components to minimize waste and extend material life cycles. This paradigm shift is encouraging wind farm operators, original equipment manufacturers, and policy-makers to rethink how turbines are designed, operated, and eventually decommissioned.

One of the key enablers of this trend is the incorporation of design-for-recyclability principles into the manufacturing of new wind turbines. Manufacturers are now considering end-of-life implications during the design phase, opting for materials that are easier to disassemble and recycle. This approach not only facilitates future recycling efforts but also reduces the long-term environmental footprint of wind energy projects.

Furthermore, there is a noticeable increase in initiatives aimed at refurbishing and repurposing wind turbine components. Instead of disposing of entire systems, companies are salvaging usable parts such as gearboxes, generators, and control systems for resale in secondary markets, particularly in developing regions. These practices extend the economic life of turbine components and reduce demand for virgin raw materials.

Policy developments are also reinforcing this trend. In regions such as the European Union, regulatory measures are being introduced to promote producer responsibility, requiring manufacturers to account for the full lifecycle of their products. Incentives such as tax benefits, recycling credits, and subsidies for circular operations are fostering innovation and investment in sustainable decommissioning technologies

The rise of specialized circular economy consultancies and service providers is further fueling the adoption of these models. These entities assist wind farm operators in planning decommissioning strategies that prioritize environmental stewardship and cost-efficiency. Moreover, circular economy practices are becoming integral to corporate sustainability reporting, aligning with investor expectations and environmental, social, and governance benchmarks.

As global wind energy capacity continues to grow, the transition to circular economy models is expected to redefine end-of-life management in the Wind Turbine Scrap Market. This trend not only addresses the environmental challenges of turbine disposal but also opens new business opportunities and drives long-term value creation across the wind energy supply chain.

Segmental Insights

Recycling Process Insights

In 2024, the mechanical recycling segment dominated the Wind Turbine Scrap Market and is expected to maintain its dominance during the forecast period. Mechanical recycling involves physically breaking down wind turbine components, particularly metal-based parts such as towers, nacelles, and internal mechanical systems, into reusable materials without altering their chemical composition. This process is highly preferred due to its cost-effectiveness, technological maturity, and minimal environmental impact when compared to other recycling methods.

The significant volume of recyclable metals such as steel, aluminum, and copper present in wind turbine structures contributes to the widespread adoption of mechanical recycling. Additionally, mechanical recycling infrastructure is already well-established across major industrial economies, enabling efficient processing and recovery of valuable resources. Furthermore, mechanical recycling is often the first choice for turbine owners and decommissioning firms due to its lower capital investment and operational complexity relative to thermal or chemical recycling.

While composite materials such as blades pose challenges to this method, the recyclable metallic components, which represent a large share of the total turbine mass, continue to drive the dominance of mechanical recycling.

The growing emphasis on circular economy models and material recovery, combined with supportive government regulations encouraging landfill avoidance and metal reuse, further reinforces the segment's leadership in the market. Moreover, mechanical recycling aligns with environmental, social, and governance benchmarks, making it attractive to both investors and corporate stakeholders seeking to enhance sustainability credentials. As the global installed base of wind turbines continues to expand and reach end-of-life, the demand for scalable and economically viable recycling solutions is anticipated to increase. Mechanical recycling, with its proven reliability and established logistics, is well-positioned to capitalize on this growing demand, thereby ensuring its continued dominance in the Wind Turbine Scrap Market throughout the forecast period.

Component Insights

In 2024, the tower segment dominated the Wind Turbine Scrap Market and is expected to maintain its dominance during the forecast period. Wind turbine towers are the largest and heaviest structural components of a wind turbine, typically constructed from high-grade steel and accounting for a significant proportion of the turbine's total mass. Due to their substantial steel content, towers offer high recyclability and economic value, making them highly attractive to scrap processing companies. The recovery and resale of steel from towers provide consistent revenue opportunities for recyclers, which contributes to the strong preference for processing this component over others.

Additionally, the dismantling and transportation of towers are relatively more straightforward compared to components such as blades, which are often composed of complex composite materials that are more difficult and costly to recycle. The existing infrastructure and global market demand for recycled steel further support the dominance of the tower segment, as steel recovered from turbine towers can be reintegrated into various industrial and construction applications with minimal processing. Moreover, as the global wind energy sector continues to expand and a growing number of turbines reach the end of their operational life, the volume of decommissioned towers is expected to rise steadily, reinforcing the segment’s dominant market position.

The increasing focus on circular economy principles and sustainability reporting has also led to a surge in demand for components that offer high recycling potential, with towers being prioritized due to their material composition and recovery efficiency. Furthermore, regulatory mandates in regions such as Europe and North America encourage the reuse and recycling of large metallic structures, positioning the tower segment as a cornerstone in the waste management strategies of wind energy operators. Given these advantages in terms of volume, material value, and regulatory alignment, the tower segment is projected to retain its leading position in the Wind Turbine Scrap Market throughout the forecast period.

Download Free Sample Report

Regional Insights

Largest Region

In 2024, Europe dominated the Wind Turbine Scrap Market and is expected to maintain its dominance during the forecast period. This regional leadership is primarily attributed to Europe's early and large-scale adoption of wind energy, which has resulted in a significant number of wind turbines reaching the end of their operational life. Countries such as Germany, Denmark, Spain, and the Netherlands were among the pioneers in deploying wind energy infrastructure during the late 1990s and early 2000s. As a result, a substantial volume of wind turbines in the region are now entering decommissioning phases, generating considerable quantities of scrap materials, including metals and composite components.

Moreover, Europe has established a robust regulatory framework that supports environmental sustainability, circular economy practices, and waste management compliance. European Union directives on landfill restrictions, extended producer responsibility, and mandatory recycling targets have pushed wind farm operators and original equipment manufacturers to implement structured recycling programs. In addition, the region boasts advanced recycling infrastructure and innovative technologies, particularly in mechanical and thermal recycling processes, which enable efficient recovery of valuable materials from decommissioned wind turbines.

Public and private investments in green technologies, coupled with collaborations between wind energy firms and recycling companies, have further accelerated market maturity. The presence of specialized firms with expertise in blade recycling, cement co-processing, and metal recovery has also strengthened Europe’s position as a global leader in this market.

Furthermore, growing societal awareness and government incentives for sustainable end-of-life management of renewable energy assets have encouraged proactive measures by stakeholders across the wind energy value chain. With continued expansion of wind capacity, high rates of turbine replacement, and progressive environmental regulations, Europe is well-positioned to retain its dominance in the Wind Turbine Scrap Market over the forecast period. The region’s comprehensive approach to sustainable energy asset management sets a benchmark for global market development.

Emerging Region

In the forecast period, the Asia Pacific region is anticipated to emerge as the leading growth area in the Wind Turbine Scrap Market due to its accelerating transition toward renewable energy and the increasing number of aging wind turbines across several countries in the region. Nations such as China, India, Japan, South Korea, and Australia have witnessed rapid wind energy deployment over the past two decades, driven by policy mandates, economic development goals, and the urgent need to reduce dependence on fossil fuels. Many of the wind turbines installed during the early phases of this growth are now reaching the end of their operational lifecycle, resulting in a growing accumulation of scrap components that require structured disposal and recycling.

The Asia Pacific region is experiencing a significant shift in regulatory focus toward sustainable waste management and circular economy practices, prompting governments to formulate guidelines that encourage environmentally responsible decommissioning of renewable energy assets. China, in particular, holds a dominant position in regional wind energy capacity and has begun investing in recycling technologies to manage large-scale turbine scrappage. Simultaneously, India is establishing public-private partnerships to build end-of-life turbine recycling capabilities and reduce reliance on landfilling.

The region’s emergence is further supported by increasing foreign direct investment, technological collaboration with international recycling firms, and the development of specialized industrial zones dedicated to clean energy infrastructure management. Moreover, the growing emphasis on climate change mitigation and net-zero emission targets has created a favorable environment for policy innovation and infrastructure upgrades.

With rising awareness among wind farm operators and original equipment manufacturers about the economic and environmental implications of improper turbine disposal, the demand for recycling solutions is projected to surge. As a result, the Asia Pacific region is expected to experience the highest growth rate in the Wind Turbine Scrap Market during the forecast period, positioning itself as a vital contributor to the global wind energy circular economy.

Recent Development

• In July 2024, Veolia announced key leadership appointments to enhance its financial strategy and governance. Emmanuelle Menning was named Deputy Chief Executive Officer for Finance and Purchasing, effective September, bringing strengthened financial oversight. Additionally, Selma Bekhechi was appointed as Director of Investor Relations to support transparent stakeholder communication. These changes align with Veolia’s long-term strategic roadmap and aim to reinforce the company’s financial capabilities and corporate governance structure for sustainable growth and performance in the coming years.
• In June 2025, Veolia unveiled its plan to expand hazardous waste treatment capacity by 530,000 tonnes annually by 2030. This growth will be achieved through organic initiatives and five strategic tuck-in acquisitions, mainly in the United States, Japan, and Brazil, with a total investment of approximately €300 million. This initiative supports Veolia’s GreenUp ambition and reinforces its global leadership in hazardous waste management by addressing rising environmental demands and strengthening its operational presence across key international markets.
• In March 2025, Spanish investment firm CriteriaCaixa announced its commitment to acquire a 5 percent stake in Veolia, with a cap at 5.5 percent, valued at approximately €1.06 billion. This investment includes securing a position on Veolia’s board of directors. The strategic move highlights CriteriaCaixa’s long-term commitment to governance collaboration and reinforces its support for Veolia’s GreenUp strategy, aimed at advancing sustainable environmental solutions and strengthening Veolia’s leadership in global ecological transformation initiatives.
• In December 2024, Veolia signed a memorandum of understanding with Saudi Investment Recycling Company to strengthen regional leadership in waste management in alignment with Saudi Arabia’s Vision 2030. The partnership targets the development of infrastructure for organic, industrial, and hazardous waste treatment. This strategic collaboration not only enhances Veolia’s operational presence in the Middle East but also supports the region’s sustainability goals, positioning both entities as key contributors to Saudi Arabia’s transition toward a more circular and environmentally responsible economy.

Key Market Players

• Veolia Environnement S.A.
• LM Wind Power (a GE Renewable Energy business)
• Gurit Holding AG
• Suez S.A.
• TPI Composites, Inc.
• Carbon Rivers LLC
• Global Fiberglass Solutions Inc.
• EDF Renewables
• Neocomp GmbH
• Energy Wind & Renewables Group Ltd.

Report Scope:

In this report, the Global Wind Turbine Scrap Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

•  Wind Turbine Scrap Market, By Recycling Process:

o   Mechanical Recycling

o   Thermal Recycling

o   Chemical Recycling

o   Landfilling

• Wind Turbine Scrap Market, By Component:

o   Blades

o   Nacelle

o   Tower

o   Generator

o   Gearbox

o   Others

• Wind Turbine Scrap Market, By Application:

o   Construction

o   Commercial

o   Aerospace

o   Energy

o   Others

• Wind Turbine Scrap Market, By Region:

o   North America

§  United States

§  Canada

§  Mexico

o   Europe

§  Germany

§  France

§  United Kingdom

§  Italy

§  Spain

o   South America

§  Brazil

§  Argentina

§  Colombia

o   Asia-Pacific

§  China

§  India

§  Japan

§  South Korea

§  Australia

o   Middle East & Africa

§  Saudi Arabia

§  UAE

§  South Africa

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the Global Wind Turbine Scrap Market.

Available Customizations:

Global Wind Turbine Scrap Market report with the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report:

Company Information

• Detailed analysis and profiling of additional market players (up to five).

Global Wind Turbine Scrap Market is an upcoming report to be released soon. If you wish an early delivery of this report or want to confirm the date of release, please contact us at [email protected]