North America Wind Turbine Pitch and Yaw Drive Market By Drive Type (Electric, Hydraulic), By Power Capacity (Below 1 MW, 1 MW-5 MW, 5 MW-10 MW, Above 10 MW), By Application (Onshore, Offshore), By Component Type (Pitch Drive, Yaw Drive), By Country, By Competition, Forecast and Opportunities 2020-2030F

Market Overview

The North America Wind Turbine Pitch and Yaw Drive Market was valued at USD 3.36 Billion in 2024 and is expected to reach USD 4.96 Billion by 2030 with a CAGR of 6.71% during the forecast period. The North America wind turbine pitch and yaw drive market refers to the segment of the wind energy equipment industry focused on the systems responsible for controlling the orientation and blade angle of wind turbines.

Pitch drives adjust the angle of the blades to optimize wind capture and reduce stress during high wind speeds, while yaw drives rotate the entire nacelle to face the wind direction accurately. These systems are essential for enhancing the operational efficiency, safety, and longevity of wind turbines. The market is gaining momentum as North America intensifies its shift toward renewable energy sources to reduce dependence on fossil fuels and achieve carbon neutrality targets. Countries like the United States and Canada are expanding wind energy capacity, encouraged by favorable government incentives, power purchase agreements, and rising private sector investments. Wind accounted for over 10% of the total electricity generation in the United States as of 2023, with projections indicating substantial future growth.

The growing deployment of offshore wind farms is increasing the demand for robust and precise pitch and yaw systems that can withstand harsh marine environments. Technological innovations in drive systems, such as the adoption of smart sensors, predictive maintenance algorithms, and energy-efficient electric drives, are further improving system reliability and reducing maintenance costs. Retrofitting older turbines with advanced pitch and yaw systems is another avenue contributing to market expansion.

The rising scale of wind turbine installations—characterized by larger rotor diameters and taller towers—necessitates more powerful and accurate control systems, boosting demand for high-performance pitch and yaw drives. Supply chain advancements and increased collaboration between turbine manufacturers and component suppliers are also accelerating the adoption of advanced drive technologies. Overall, the North America wind turbine pitch and yaw drive market is poised for continued growth, driven by the region’s commitment to decarbonization, increased wind farm installations, and ongoing improvements in wind turbine technology and reliability.

Key Market Drivers

Expansion of Utility-Scale Wind Power Projects Across North America

The increasing number of utility-scale wind power projects across North America has emerged as a significant growth driver for the wind turbine pitch and yaw drive market. Governments in both the United States and Canada are committing to long-term decarbonization goals that require a rapid increase in renewable energy generation, particularly from wind power. Utility-scale wind farms—comprising large clusters of turbines designed to generate electricity for public grids—are being deployed at an unprecedented rate to meet these objectives. The growing size and complexity of these projects necessitate the installation of advanced wind turbine pitch and yaw drive systems to ensure precise control and maximize energy output. These systems allow operators to optimize blade angles and turbine orientation relative to wind direction and speed, significantly improving the efficiency and safety of the turbines. Utility-scale wind farms often include turbines with rotor diameters exceeding 120 meters and tower heights surpassing 100 meters, which require robust, high-torque pitch and yaw drives to maintain stability under varying wind loads.

As projects grow in size and scale, so does the demand for sophisticated pitch and yaw mechanisms that can operate efficiently over long lifespans with minimal maintenance. This requirement for high-performance components is especially relevant in remote or offshore utility-scale installations, where regular servicing is cost-prohibitive. Public utilities and independent power producers are increasingly issuing requests for proposals that specifically include technical performance criteria for pitch and yaw systems as part of their evaluation metrics, underlining the strategic importance of these subsystems in turbine procurement. The momentum in the development of utility-scale wind farms, supported by infrastructure investments and regulatory backing, is therefore expected to consistently fuel demand for advanced pitch and yaw drive systems in the North America region. In 2023, the United States added over 5,800 megawatts of utility-scale wind capacity, increasing the total operational wind fleet to more than 145,000 megawatts, underscoring the rising need for high-performance pitch and yaw systems.

Government-Led Clean Energy Incentives and Regulatory Mandates

Governmental policies aimed at reducing carbon emissions and fostering clean energy adoption are playing a pivotal role in driving demand for wind turbine pitch and yaw drive systems in North America. Federal and state-level agencies have introduced a wide array of financial and policy incentives such as tax credits, feed-in tariffs, renewable portfolio standards, and clean electricity performance programs that directly or indirectly enhance the viability and profitability of wind energy projects. These measures are designed to attract investments in wind infrastructure and ensure long-term operational sustainability, thereby escalating the installation rate of new wind turbines across various geographic regions. For instance, the United States Inflation Reduction Act includes provisions for extended tax credits for wind energy developers, making large-scale turbine procurement more economically feasible. As these installations increase, there is a corresponding surge in demand for essential turbine components such as pitch and yaw drives.

Specific regulatory requirements around grid stability and energy efficiency are prompting wind farm developers to invest in more sophisticated turbine technologies. Pitch and yaw systems play a critical role in ensuring that turbines operate at peak efficiency, respond accurately to real-time wind conditions, and integrate smoothly with regional power grids. Compliance with performance-based standards increasingly necessitates the use of advanced control systems, thereby encouraging the integration of intelligent pitch and yaw drives equipped with feedback loops and sensor-based monitoring. The strong policy-driven momentum for wind energy development has created a stable and predictable demand outlook for the wind turbine pitch and yaw drive market across North America. The United States federal government allocated over 370 billion United States dollars in clean energy incentives through the Inflation Reduction Act, including production tax credits for wind energy projects, leading to an estimated 40 percent increase in proposed wind installations by 2024 compared to the previous year.

Rise in Offshore Wind Energy Investments in Coastal States

The growing investment in offshore wind energy, particularly in coastal states such as New York, Massachusetts, and California, is significantly boosting the demand for high-durability wind turbine pitch and yaw drive systems. Offshore turbines are subject to more extreme environmental conditions, including higher wind speeds, saltwater corrosion, and turbulent airflow, necessitating advanced pitch and yaw systems that offer enhanced resistance to mechanical wear and superior control capabilities. Offshore wind turbines are typically larger in size and rated for higher capacities—often exceeding 10 megawatts per unit—thereby placing additional performance demands on drive components. Pitch systems must efficiently regulate blade angles to prevent structural overload, while yaw drives must reliably orient the nacelle into optimal wind directions despite dynamic sea-state conditions. Given the difficulty and expense of servicing offshore turbines, developers are prioritizing components with long operational lifespans and minimal maintenance requirements. This is leading to greater adoption of electrically driven pitch and yaw systems, which offer higher precision, remote diagnostic capabilities, and smoother integration with turbine control units.

New offshore projects are being planned with built-in digital twin capabilities and predictive maintenance technologies, placing further emphasis on pitch and yaw drives that can support continuous data monitoring and real-time performance analytics. The substantial increase in offshore wind leasing agreements and power purchase contracts by state utilities indicates a long-term commitment to this segment, ensuring steady growth for associated subsystems including pitch and yaw drives. As of 2024, the United States Department of the Interior has approved offshore wind energy leases with a cumulative potential exceeding 40 gigawatts, with planned installations requiring more than 3,000 large-scale offshore wind turbines equipped with high-performance pitch and yaw drive systems.

Lifecycle Optimization and Retrofitting of Aging Turbine Fleets

The aging fleet of wind turbines installed over the past two decades across North America is creating a robust demand for retrofitting and lifecycle optimization services, especially for critical subsystems such as pitch and yaw drives. Many wind farms commissioned in the early 2000s are now approaching or exceeding their 20-year design life, and operators are increasingly opting for upgrades rather than complete turbine replacements to extend operational viability. One of the most common upgrades involves replacing outdated or degraded pitch and yaw systems with newer, more efficient counterparts that provide improved control accuracy, lower maintenance requirements, and enhanced integration with modern turbine management systems. Retrofitting enables older turbines to achieve higher capacity factors and comply with updated grid performance standards, all while avoiding the capital expense of full turbine replacement.

Lifecycle cost analyses increasingly show that upgrading pitch and yaw systems can deliver substantial returns on investment through improved energy yield and reduced downtime. Retrofitting also supports sustainability objectives by reducing the environmental impact associated with decommissioning and material disposal. The retrofitting market is further expanding due to insurance and warranty requirements that stipulate periodic upgrading of mechanical and control systems to maintain coverage. Manufacturers and service providers are responding to this need by offering modular pitch and yaw systems specifically designed for backward compatibility with legacy turbine models. This retrofit wave represents a lucrative secondary market that complements new turbine installations and supports sustained growth in the wind turbine pitch and yaw drive sector. As of 2024, more than 25,000 wind turbines operating in the United States are over 15 years old, with at least 30 percent of them scheduled for subsystem retrofitting, including pitch and yaw drive replacements, within the next five years.

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Key Market Challenges

High Capital and Maintenance Costs Associated with Advanced Pitch and Yaw Drive Systems

One of the most prominent challenges facing the North America wind turbine pitch and yaw drive market is the high capital expenditure required for the procurement, installation, and maintenance of advanced drive systems. As the wind energy sector shifts toward larger turbines and offshore installations, the demand for high-performance pitch and yaw drives capable of handling greater mechanical loads and extreme environmental conditions is increasing. These advanced systems, particularly those that utilize electric drives integrated with intelligent control units, come with significant cost premiums. Manufacturers must invest heavily in specialized materials, precision manufacturing technologies, and advanced electronics to ensure performance and durability, all of which contribute to the high initial cost of the product.

The complexity of these systems adds to the overall installation and commissioning expenses, requiring skilled labor and customized configuration processes to align with specific turbine models and site conditions. Beyond the initial investment, ongoing maintenance presents an additional financial burden. Pitch and yaw drives are subject to substantial mechanical stress during continuous operation and must be regularly serviced to prevent system failures that could lead to turbine downtime. For offshore installations, maintenance operations are even more costly due to logistical challenges, such as the need for vessels, cranes, and weather-dependent service windows. Asset owners must weigh the benefits of installing high-performance drive systems against the increased operational costs associated with inspections, part replacements, and system recalibration. In many cases, operators of older wind farms face difficulty justifying the retrofitting of newer drive systems due to constrained project budgets or limited return on investment.

These cost-related constraints are particularly significant for independent power producers and smaller utilities with tighter financial margins, limiting widespread adoption of state-of-the-art pitch and yaw drives. The economic challenge is further exacerbated by supply chain pressures, as the cost of raw materials such as rare earth magnets, precision gear alloys, and specialized lubricants continues to rise. These factors collectively act as a deterrent to rapid market expansion, especially in cost-sensitive projects or regions with limited government subsidies. Unless innovative financing mechanisms, cost-reduction strategies, or new manufacturing techniques are widely adopted, the economic barrier presented by capital and maintenance costs is expected to remain a substantial obstacle to broader penetration of advanced pitch and yaw drive systems in North America.

Supply Chain Volatility and Component Availability Constraints

Supply chain volatility remains a critical operational challenge for the wind turbine pitch and yaw drive market in North America, particularly as demand accelerates amid growing renewable energy adoption. The production of pitch and yaw drive systems requires a coordinated supply of multiple specialized components, including electric motors, precision bearings, gearboxes, torque sensors, and advanced electronics for control systems. Disruptions in the availability of any one of these critical components can delay manufacturing schedules, increase lead times, and ultimately postpone turbine deployment timelines. Over the past few years, geopolitical tensions, trade policy shifts, and pandemic-related interruptions have exposed the fragility of global supply chains, especially those dependent on imports from international manufacturing hubs such as China, Germany, and Japan.

Many North American wind turbine component manufacturers lack domestic alternatives for highly specialized inputs like neodymium magnets, sealed actuators, and hardened steel components, leaving them vulnerable to price fluctuations and export restrictions. Logistics constraints, including port congestion, container shortages, and inland transportation bottlenecks, have further contributed to delays and increased costs for turbine developers and component integrators. Additionally, fluctuations in foreign exchange rates and the imposition of import tariffs have complicated procurement strategies and raised the landed cost of components. For companies operating on fixed-cost power purchase agreements, these cost increases directly affect project margins and investment decisions. There is limited scalability within the domestic supplier ecosystem for pitch and yaw systems, resulting in a dependency on a small number of established vendors.

This concentration risk limits competition and innovation, while increasing vulnerability to production stoppages and labor strikes. In response, some manufacturers have started localizing production, but such transitions require significant investment, time, and regulatory coordination. Meanwhile, the growing demand for pitch and yaw systems exacerbates the strain on existing supply networks, particularly as larger wind turbines require more complex and robust components. Without a resilient and diversified supply chain capable of supporting sustained demand growth, the market risks project slowdowns and a potential loss of investor confidence. As such, managing supply chain complexity and ensuring component availability remain key challenges that must be addressed to ensure long-term stability and scalability of the wind turbine pitch and yaw drive market in North America.

Technical Integration Challenges with Evolving Turbine Designs

Another major challenge confronting the North America wind turbine pitch and yaw drive market is the increasing difficulty of achieving seamless technical integration with evolving turbine architectures. As the wind energy industry advances toward more complex and higher-capacity turbine designs, the technical demands placed on subcomponents such as pitch and yaw drive systems have escalated substantially. Modern turbines now feature larger rotor diameters, taller tower structures, and enhanced power electronics, all of which require highly customized and adaptive drive systems. These systems must be precisely engineered to handle increased torque loads, ensure rapid response to wind variability, and maintain alignment with sophisticated turbine control algorithms. Achieving this level of integration is a complex engineering task that requires interdisciplinary collaboration between component manufacturers, system integrators, and turbine original equipment manufacturers. However, a lack of standardized protocols, component specifications, and software interoperability creates significant technical barriers to integration. Each turbine platform has unique structural, control, and safety requirements, which necessitate the development of customized drive solutions. This customization process increases design time, testing requirements, and the likelihood of engineering errors during commissioning.

Integration challenges often result in delayed turbine deployment schedules or post-installation performance issues such as suboptimal blade pitch control, excessive yaw backlash, or component overheating. These problems not only compromise turbine efficiency but also lead to higher maintenance costs and potential safety risks. The complexity of integrating modern pitch and yaw systems is further compounded by the inclusion of emerging technologies such as real-time monitoring systems, digital twin models, and artificial intelligence-based predictive maintenance tools. Ensuring compatibility and reliable data communication between these systems and the turbine’s supervisory control and data acquisition architecture requires sophisticated software engineering and extensive validation testing. In many cases, legacy turbines in existing wind farms do not support such integrations, limiting the market for drive system upgrades and retrofits. Rapid advancements in turbine design outpace the development cycles of pitch and yaw systems, resulting in a lag between new turbine specifications and available drive technologies. Unless industry-wide standardization efforts, open architecture initiatives, and collaborative design frameworks are adopted, these integration challenges will continue to hinder the efficient deployment and performance optimization of wind turbine pitch and yaw systems in North America.

Key Market Trends

Adoption of Predictive Maintenance Technologies in Drive Systems

A significant trend influencing the North America wind turbine pitch and yaw drive market is the accelerated adoption of predictive maintenance technologies within drive system architectures. Wind turbine operators are increasingly implementing advanced sensors, data analytics platforms, and machine learning algorithms to monitor the real-time condition of pitch and yaw components. This trend reflects a broader shift toward performance-based maintenance models that aim to reduce unplanned downtime, extend the service life of components, and optimize energy output. Predictive systems are capable of analyzing vibration data, temperature changes, torque irregularities, and gear wear patterns to detect early signs of mechanical failure. This allows operators to schedule maintenance interventions before costly breakdowns occur, thereby lowering the total cost of ownership. These systems also support dynamic load forecasting, which enables better control of blade angles and yaw positioning in response to shifting wind conditions.

Many wind farm owners are integrating cloud-based platforms to centralize data across multiple turbines and locations, enhancing the scalability and utility of predictive maintenance. The trend is gaining momentum due to the increasing number of offshore and remote wind installations, where traditional maintenance approaches are costlier and risk-prone. Component manufacturers are responding by embedding diagnostic capabilities directly into pitch motors, gearboxes, and control modules, creating smart drive systems with enhanced operational transparency. Regulatory support for digital transformation in the renewable energy sector is further reinforcing this shift. As digital technologies mature and costs decrease, the widespread deployment of predictive maintenance solutions is expected to become a standard feature in pitch and yaw drive systems across the North America wind energy landscape.

Transition Toward Electrically Driven Pitch and Yaw Systems

The North America wind turbine pitch and yaw drive market is undergoing a notable transition from hydraulically actuated systems to electrically driven alternatives, driven by the demand for higher efficiency, greater reliability, and reduced environmental impact. Electric drive systems offer several performance advantages, including faster response times, more precise control over blade and nacelle positioning, and lower energy consumption during operation. Unlike hydraulic systems, which are prone to leakage, pressure loss, and complex maintenance requirements, electric drives offer a cleaner, more streamlined solution with fewer moving parts and reduced maintenance needs. As wind turbines scale in size and complexity, particularly in offshore environments, the operational simplicity and reliability of electric systems are becoming increasingly attractive. The modularity of electric drive units also enables easier integration into new turbine designs and facilitates upgrades in existing installations.

In response to this trend, manufacturers are developing high-torque electric motors with compact footprints, advanced gear systems, and integrated control electronics that can withstand harsh environmental conditions and dynamic mechanical loads. Electric drive systems are more compatible with renewable energy digitalization efforts, allowing for real-time monitoring, predictive diagnostics, and remote-control capabilities. Energy companies aiming to improve turbine performance and reduce lifetime operational costs are prioritizing the adoption of electric pitch and yaw systems in both onshore and offshore wind projects. As this transition continues, it is reshaping the product development strategies of component suppliers and setting new benchmarks for system performance and sustainability in the North America wind turbine pitch and yaw drive market.

Integration of Modular and Scalable Drive System Designs

A prominent trend gaining traction in the North America wind turbine pitch and yaw drive market is the integration of modular and scalable system designs that enhance flexibility in turbine manufacturing and operation. Modular pitch and yaw drive systems are engineered to accommodate various turbine sizes, blade configurations, and tower designs through the use of interchangeable components and standardized interfaces. This design philosophy reduces the need for bespoke engineering for each new turbine model, thereby accelerating product development timelines and lowering manufacturing costs. Scalability is a key advantage, particularly as turbine capacities continue to increase, with multi-megawatt models becoming the new industry norm. Scalable systems allow manufacturers to adapt the same core drive platform to different power classes by modifying torque ratings, gear ratios, or control parameters without altering the fundamental system architecture.

This trend is particularly beneficial for original equipment manufacturers seeking to streamline their product portfolios and reduce inventory complexity. Modular systems simplify maintenance operations by enabling faster part replacements and reducing the time required for system disassembly and reassembly. Wind farm operators also benefit from reduced training requirements and improved supply chain efficiency, as the same maintenance protocols and spare parts can be used across different turbine types. The growing emphasis on mass customization and agile production processes in the wind energy industry is further driving the demand for modular, scalable drive systems. As more component manufacturers embrace this design approach, it is expected to enhance both economic efficiency and technological innovation across the wind turbine pitch and yaw drive market in North America.

Segmental Insights

Drive Type Insights

In 2024, Electric Drive segment emerged as the dominant category in the North America wind turbine pitch and yaw drive market, and it is expected to maintain its leading position throughout the forecast period. This dominance is primarily attributed to the widespread adoption of electric drive systems in modern wind turbine designs, particularly in large-scale onshore and offshore wind projects. Electric drives offer significant advantages over hydraulic systems, including improved energy efficiency, higher precision in blade and nacelle positioning, reduced maintenance requirements, and better integration with digital monitoring systems. The growing preference for environmentally sustainable and maintenance-friendly technologies in the renewable energy sector has further reinforced the shift toward electric drives. As wind turbine manufacturers aim to improve overall system reliability and reduce the risk of hydraulic fluid leaks, electric drives are increasingly being integrated into next-generation turbine platforms. Technological advancements in electric motors, power electronics, and control systems have also enhanced the performance of electric pitch and yaw drives under diverse operational conditions, including extreme temperatures and variable wind loads.

The transition to electric drive systems is aligned with the broader digitalization trend in the wind energy industry, allowing for remote monitoring, predictive maintenance, and seamless integration with smart grid infrastructure. The cost-effectiveness of electric systems in terms of lifecycle management and the growing scale of wind turbine installations across North America have solidified the segment’s competitive edge. With multiple utility-scale wind projects in the pipeline across the United States and Canada, and an increasing focus on offshore wind development, the demand for efficient, reliable, and digitally compatible drive systems is expected to rise steadily. As a result, the electric drive segment is poised not only to sustain its market leadership but also to expand its share during the forecast period, driven by technological innovation, policy support, and evolving industry standards.

Power Capacity Insights

In 2024, the 1 MW to 5 MW power capacity segment dominated the North America wind turbine pitch and yaw drive market and is expected to maintain its dominance during the forecast period. This segment holds a substantial share due to the widespread deployment of onshore wind turbines within this capacity range, which are widely used across the United States and Canada for utility-scale and community-scale power generation. Turbines within this capacity bracket offer an optimal balance between output efficiency, operational cost, and infrastructure requirements, making them a preferred choice for both new installations and repowering projects. As wind energy investments continue to rise and project developers prioritize proven, cost-effective solutions, the 1 MW to 5 MW segment is likely to retain its leadership position.

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Country Insights

Largest Country

In 2024, the United States maintained its position as the dominant player in the North America wind turbine pitch and yaw drive market, driven by its expansive wind energy infrastructure, favorable policy frameworks, and consistent investment in renewable energy technologies. The country’s vast geographic landscape offers ideal wind conditions across several key regions, including the Midwest, Great Plains, and coastal areas, enabling large-scale deployment of wind farms. Federal and state-level initiatives such as production tax credits, clean energy mandates, and streamlined permitting processes have created a supportive environment for wind energy development, further stimulating demand for pitch and yaw drive systems.

The rapid growth of offshore wind projects, particularly along the Eastern Seaboard, has contributed to increased adoption of advanced pitch and yaw technologies that offer durability and high performance in challenging marine environments. The United States is also home to major wind turbine original equipment manufacturers and component suppliers, ensuring strong domestic supply chain capabilities. The emphasis on repowering aging wind farms with newer, more efficient turbines has also boosted market activity. As the country continues to prioritize energy independence and carbon reduction, the United States is expected to remain the central hub for pitch and yaw drive demand within North America through the forecast period.

Emerging Country

Canada is rapidly emerging as a key player in the North America wind turbine pitch and yaw drive market due to its expanding wind energy capacity, favorable policy environment, and strategic regional initiatives. Provinces such as Alberta, Ontario, and Quebec are witnessing a surge in wind power projects driven by clean energy mandates and a national commitment to achieve net-zero emissions. This growth is creating strong demand for advanced pitch and yaw drive systems that ensure efficient wind turbine performance, particularly in regions with highly variable wind conditions.

Canada’s collaboration with global wind turbine manufacturers and component suppliers is strengthening its technological capabilities and local production ecosystem. With a growing emphasis on renewable energy infrastructure and consistent government backing, Canada is well-positioned to become a major force in this evolving market landscape.

Recent Developments

• In July 2024, Moog launched an advanced integrated slip ring and fiber optic rotary joint (FORJ) tailored for General Electric’s 2.5-megawatt and larger wind turbines. This system replaces conventional carbon-brush slip rings, significantly enhancing operational reliability by eliminating dust-related issues. Designed for up to 100 million maintenance-free revolutions, the innovation improves turbine efficiency and reduces downtime, thereby lowering overall maintenance costs for wind energy operators.
• In August 2024, ZF Wind Power reached a milestone of 50 gigawatts in gearbox production at its Coimbatore, India facility—the largest outside China. Serving as a key export hub for global markets, including North America, ZF announced plans to increase annual capacity from 9 gigawatts to 12 gigawatts and install a 13 megawatt test rig, further strengthening its leadership in wind turbine drivetrain technologies.
• In July 2024, Timken was honored as one of the World's Most Innovative Companies by Fast Company and named among America's Most Innovative Companies for 2024 and 2023 by Fortune. These prestigious recognitions underscore Timken’s commitment to product and process innovations that deliver tangible societal benefits, reinforcing its leadership in engineering solutions for advanced industries, including wind energy.
• At WindEnergy 2024, Bonfiglioli unveiled its latest pitch and yaw control systems engineered for wind turbines up to 17 megawatts. Emphasizing sustainability, the company highlighted innovations aimed at reducing energy consumption and enhancing system efficiency. Bonfiglioli’s ongoing investment in research and development reinforces its commitment to delivering high-performance solutions that meet the dynamic requirements of both onshore and offshore wind energy markets across North America and beyond.

Key Market Players

• Siemens AG
• General Electric Company
• Nordex SE
• Vestas Wind Systems A/S
• ABB Ltd.
• Moog Inc.
• Nabtesco Corporation
• Dana Incorporated

Report Scope:

In this report, the North America Wind Turbine Pitch and Yaw Drive Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

• North America Wind Turbine Pitch and Yaw Drive Market, By Drive Type:

o   Electric

o   Hydraulic               

• North America Wind Turbine Pitch and Yaw Drive Market, By Power Capacity:

o   Below 1 MW

o   1 MW-5 MW

o   5 MW-10 MW

o   Above 10 MW   

• North America Wind Turbine Pitch and Yaw Drive Market, By Application:

o   Onshore

o   Offshore

• North America Wind Turbine Pitch and Yaw Drive Market, By Component Type:

o   Pitch Drive

o   Yaw Drive

• North America Wind Turbine Pitch and Yaw Drive Market, By Country:

o   United States

o   Canada

o   Mexico

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the North America Wind Turbine Pitch and Yaw Drive Market.

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North America Wind Turbine Pitch and Yaw Drive Market report with the given market data, Tech Sci 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).

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