부유식 해상 풍력발전 시장 : 예측(2026-2031년)

Floating Offshore Wind Energy Market, growing at a 5.26% CAGR, is projected to achieve USD 4.934 billion in 2031 from USD 3.628 billion in 2025.

The floating offshore wind energy market represents a transformative and rapidly advancing frontier within the global renewable energy sector, dedicated to deploying wind turbines on floating structures anchored in deep-water sites beyond the reach of fixed-bottom foundations. This technology unlocks vast, previously inaccessible wind resources located in deep continental shelf waters and open ocean areas. The market is transitioning from demonstration and pilot projects toward early commercialization, driven by the imperative to access superior wind resources, meet ambitious decarbonization goals, and leverage continuous technological and industrial advancements.

The primary and most compelling driver for floating wind is the abundant, high-quality wind resource located in deep-water regions. A significant portion of the world's offshore wind potential exists in waters deeper than 60 meters, where traditional fixed-bottom structures are technically unfeasible or prohibitively expensive. Floating platforms enable access to these areas, which often feature stronger and more consistent winds than near-shore sites. This capability dramatically expands the geographic potential for offshore wind, particularly for countries with steeply shelving coastlines like those in the Pacific, the Atlantic coast of the United States, and parts of Europe and Asia. Tapping into this resource is essential for scaling offshore wind to a level that can materially contribute to national and global clean energy targets.

A powerful catalyst for market development is the alignment with ambitious national and international commitments to decarbonize the energy system and achieve net-zero emissions. As governments and corporations set stringent climate goals, the need for large-scale, reliable, clean power sources intensifies. Floating offshore wind offers a pathway to deploy gigawatt-scale renewable generation in coastal regions where land-based and shallow-water resources may be limited or already allocated. Its role is increasingly recognized in national energy and industrial strategies as a key technology for long-term energy security and climate mitigation.

Concurrent and critical to market progression is the establishment of supportive government policies and regulatory frameworks. Successful commercialization requires clear maritime spatial planning, streamlined permitting processes, designated development zones, and financial mechanisms that de-risk early projects. Many forward-looking governments are implementing targeted policies, such as innovation funds, dedicated leasing rounds for floating wind, and research consortia, to foster a domestic supply chain and accelerate cost reduction. This proactive policy environment is essential to attract the substantial capital investment required for project development and associated port infrastructure.

Technological innovation and industrialization are central to driving down costs and improving reliability. The market features several competing platform concepts-including semi-submersible, spar-buoy, and tension-leg platforms-each undergoing iterative refinement through pilot and pre-commercial projects. Advancements are focused on optimizing platform design for stability, manufacturability, and ease of assembly and maintenance. Simultaneously, the integration of ever-larger, next-generation wind turbines (exceeding 15 MW) onto floating platforms is a key trend, as it increases energy capture and improves project economics. The standardization of designs and industrialization of manufacturing and installation processes are critical steps on the path to cost parity with fixed-bottom offshore wind.

Geographically, Europe is currently the leading region in terms of installed capacity and project pipeline, serving as the primary testing ground for technology and business models. Countries like the UK, Norway, France, and Portugal are hosting pioneering projects and implementing supportive regulatory regimes. However, significant growth potential is identified globally, with active development emerging in markets across Asia-Pacific (notably Japan, South Korea, and Taiwan) and North America (the US West Coast and Atlantic deep-water sites), where deep-water resources are plentiful.

Despite the strong momentum, the market faces substantial challenges. The current levelized cost of energy (LCOE) for floating wind remains higher than that of fixed-bottom offshore wind, primarily due to the nascent supply chain, less standardized processes, and the complexity of mooring and dynamic cabling systems. Significant engineering challenges persist related to withstanding harsh deep-water environmental conditions, including hurricanes and rogue waves, which demand robust and resilient designs. Furthermore, the development of specialized port infrastructure with heavy-lift capabilities and large staging areas is a prerequisite for scaling the industry, requiring coordinated public and private investment.

The competitive landscape involves a confluence of traditional offshore wind developers, major energy companies diversifying into renewables, specialized floating technology designers, and engineering firms. Success depends on technological expertise, access to capital, the ability to form consortia that cover the full project value chain, and securing early positions in emerging markets with favorable regulatory conditions.

In conclusion, the floating offshore wind energy market is poised for exponential growth, moving from a niche technology to a mainstream renewable energy solution over the next decade. Its evolution is driven by the inexorable need to access untapped wind resources and meet climate ambitions that shallow-water wind alone cannot satisfy. Future market expansion will be determined by the industry's ability to execute on a steep cost-reduction curve through technological learning and supply chain scaling, navigate complex maritime regulatory environments, and demonstrate reliable long-term performance in challenging open-ocean conditions. As these hurdles are overcome, floating wind is set to become a cornerstone of the future clean energy portfolio for many coastal nations.

Key Benefits of this Report:

• Insightful Analysis: Gain detailed market insights covering major as well as emerging geographical regions, focusing on customer segments, government policies and socio-economic factors, consumer preferences, industry verticals, and other sub-segments.
• Competitive Landscape: Understand the strategic maneuvers employed by key players globally to understand possible market penetration with the correct strategy.
• Market Drivers & Future Trends: Explore the dynamic factors and pivotal market trends and how they will shape future market developments.
• Actionable Recommendations: Utilize the insights to exercise strategic decisions to uncover new business streams and revenues in a dynamic environment.
• Caters to a Wide Audience: Beneficial and cost-effective for startups, research institutions, consultants, SMEs, and large enterprises.

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Industry and Market Insights, Opportunity Assessment, Product Demand Forecasting, Market Entry Strategy, Geographical Expansion, Capital Investment Decisions, Regulatory Framework & Implications, New Product Development, Competitive Intelligence

Report Coverage:

• Historical data from 2021 to 2025 & forecast data from 2026 to 2031
• Growth Opportunities, Challenges, Supply Chain Outlook, Regulatory Framework, and Trend Analysis
• Competitive Positioning, Strategies, and Market Share Analysis
• Revenue Growth and Forecast Assessment of segments and regions including countries
• Company Profiling (Strategies, Products, Financial Information), and Key Developments among others.

Floating Offshore Wind Energy Market Segmentation

• By Water Depth
• Shallow Water (less than 30 m depth)
• Transitional Water (30 m to 60 m depth)
• Deep Water (Higher than 60 m depth)
• By Turbine Capacity
• Up to 3MW
• 3MW-5MW
• Above 5MW
• By Application
• Pre-Commercial Pilot
• Commercial Utility-Scale
• Hybrid Wind-To-X
• By Geography
• North America
• USA
• Canada
• Mexico
• South America
• Brazil
• Argentina
• Others
• Europe
• Germany
• France
• United Kingdom
• Spain
• Others
• Middle East and Africa
• Saudi Arabia
• UAE
• Others
• Asia Pacific
• China
• India
• Japan
• South Korea
• Indonesia
• Thailand
• Others

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

2. MARKET SNAPSHOT

• 2.1. Market Overview
• 2.2. Market Definition
• 2.3. Scope of the Study
• 2.4. Market Segmentation

3. BUSINESS LANDSCAPE

• 3.1. Market Drivers
• 3.2. Market Restraints
• 3.3. Market Opportunities
• 3.4. Porter's Five Forces Analysis
• 3.5. Industry Value Chain Analysis
• 3.6. Policies and Regulations
• 3.7. Strategic Recommendations

4. TECHNOLOGICAL OUTLOOK

5. FLOATING OFFSHORE WIND ENERGY MARKET BY WATER DEPTH

• 5.1. Introduction
• 5.2. Shallow Water (less than 30 m depth)
• 5.3. Transitional Water (30 m to 60 m depth)
• 5.4. Deep Water (Higher than 60 m depth)

6. FLOATING OFFSHORE WIND ENERGY MARKET BY TURBINE CAPACITY

• 6.1. Introduction
• 6.2. Up to 3MW
• 6.3. 3MW-5MW
• 6.4. Above 5MW

7. FLOATING OFFSHORE WIND ENERGY MARKET BY APPLICATION

• 7.1. Introduction
• 7.2. Pre-Commercial Pilot
• 7.3. Commercial Utility-Scale
• 7.4. Hybrid Wind-To-X

8. FLOATING OFFSHORE WIND ENERGY MARKET BY GEOGRAPHY

• 8.1. Introduction
• 8.2. North America
  • 8.2.1. USA
  • 8.2.2. Canada
  • 8.2.3. Mexico
• 8.3. South America
  • 8.3.1. Brazil
  • 8.3.2. Argentina
  • 8.3.3. Others
• 8.4. Europe
  • 8.4.1. Germany
  • 8.4.2. France
  • 8.4.3. United Kingdom
  • 8.4.4. Spain
  • 8.4.5. Others
• 8.5. Middle East and Africa
  • 8.5.1. Saudi Arabia
  • 8.5.2. UAE
  • 8.5.3. Others
• 8.6. Asia Pacific
  • 8.6.1. China
  • 8.6.2. India
  • 8.6.3. Japan
  • 8.6.4. South Korea
  • 8.6.5. Indonesia
  • 8.6.6. Thailand
  • 8.6.7. Others

9. COMPETITIVE ENVIRONMENT AND ANALYSIS

• 9.1. Major Players and Strategy Analysis
• 9.2. Market Share Analysis
• 9.3. Mergers, Acquisitions, Agreements, and Collaborations
• 9.4. Competitive Dashboard

10. COMPANY PROFILES

• 10.1. Vestas Wind Systems AS
• 10.2. General Electric Company
• 10.3. Siemens Gamesa Renewable Energy SA
• 10.4. BW Ideol AS
• 10.5. Equinor ASA
• 10.6. Marubeni Corporation
• 10.7. Macquarie Group Limited
• 10.8. Doosan Enerbility Co. Ltd.

11. APPENDIX

• 11.1. Currency
• 11.2. Assumptions
• 11.3. Base and Forecast Years Timeline
• 11.4. Key Benefits for the Stakeholders
• 11.5. Research Methodology
• 11.6. Abbreviations