Floating Offshore Wind Power - Market Share Analysis, Industry Trends & Statistics, Growth Forecasts (2024 - 2029)
The Floating Offshore Wind Power Market size in terms of installed base is expected to grow from 0.94 gigawatt in 2024 to 22.29 gigawatt by 2029, at a CAGR of 88.36% during the forecast period (2024-2029).
Key Highlights
Over the medium term, rising investments in offshore renewable wind energy projects, coupled with advanced and readily accessible offshore wind turbine technologies, are expected to be major drivers of the floating offshore wind market during the forecast period.
On the other hand, tough competition from alternate renewable energy markets will restrain the floating offshore wind market during the forecast period.
Nevertheless, floating offshore wind energy is becoming more popular in developing untapped deep-water prospects favorable for floating structures, providing ample opportunities for the market players.
Europe is expected to dominate the floating offshore wind market during the forecast period.
Floating Offshore Wind Power Market Trends
The Transitional Water (30 m to 60 m depth) Segment is Expected to Grow
Due to the greater water depth and favorable project economics, floating offshore wind turbine (FOWT) technology is more developed in transitional water depths (30-60 meters). The barge variant is the most commercially viable floating wind turbine design at shallow depths. This model is appropriate for activities higher than 30 meters (m) and has the shallowest draft of any floating foundation.
Barge-style floating wind turbines have a square footprint, while other designs incorporate a moonpool to lessen stresses brought on by wave-induced loads. According to GWEC, a typical 6-megawatt floating barge wind turbine weighs between 2,000 and 8,000 tons. However, BW Ideol, with its Damping Pool Barge Floating Substructure Technology, is the only company that has deployed barge-type FOWT at the MW scale.
Since the water depth is shallower, FOWT technology is less practical from a business point of view than fixed-base technology. During the forecast period, barge technology is expected to make up a small part of the FOWT market. According to the US EPA, only 5 MW of barge FOWT capacity operated globally as of 2021. Around 1,932 MW of FOWT capacity on barges, or 2.1% of all announced offshore wind substructure technologies for future projects worldwide, was announced.
Most companies attempt to market FOWT designs that can be used in deeper waters. However, some semi-submersible technologies can also be used at transitional water depths. They can function at transitional depths due to several commercial FOWT models that are built on the semi-submersible design. A few of these models were initially used in experimental projects, while others were modified for use in ventures for profit.
The US Department of Energy’s Wind Energy Technologies Office (WETO) announced on April 24, 2024, that it intended to issue a Notice of Intent involving a USD 48 million funding opportunity for regional and national research and development of offshore wind technologies, including floating offshore wind platform research and development. This promises future growth potential for the market.
According to the International Renewable Energy Agency RE Capacity 2024, the global installed offshore wind energy capacity increased by 17.26% in FY 2023-24, adding 10,696 MW in 2023 to the earlier installed capacity of 61,967 MW in 2022. Such developments show promising outlooks for the market players in the near future.
Most of the FOWT projects in transitional depths are likely to be in Europe, especially in the United Kingdom, Scandinavia, and France, where large projects are in the planning stages. During the forecast period, most of the deployments in this segment are likely to happen in these regions.
Thus, the transitional water (30 m to 60 m depth) segment is expected to grow significantly during the forecast period.
Europe is Expected to Dominate the Market
Europe holds the largest share of offshore wind energy installations globally. According to the European Union, Europe represents a quarter of global offshore wind installations. The country (primarily North Sea countries) is likely to be at the helm of the offshore wind market.
Around 85% of offshore wind installations are globally in European waters. The governments, particularly in the North Sea area, have set an ambitious target for installing offshore wind farms in their territorial waters.
The EolMed project is France's first floating pilot wind farm in the Mediterranean Sea. In May 2022, TotalEnergies announced the start of the project's construction, which is expected to be operational by 2024. The project consists of three 10 MW floating turbines on the bathymetry of the 62-meter depth and anchored to the seabed. The turbines will use a barge design with a damping pool.
According to the International Renewable Energy Agency RE Capacity 2024, the installed offshore wind energy capacity in Europe increased by 9.58% in FY 2023-24, adding 2,830 MW in 2023 to the earlier installed capacity of 29,539 MW in 2022. Such developments show promising outlooks for the market players in the near future.
In August 2023, the world’s largest floating wind farm, the Hywind Tampen Project, started operating around 140 kilometers off the coast of Norway in depths ranging from 270 to 310 meters. Hywind Tampen uses 11 floating wind turbines and has a system capacity of 88 MW. It helps power operations at offshore oil and gas platforms.
During the forecast period, these trends should make Europe a great place to do business for players involved in floating offshore wind farms.
Floating Offshore Wind Power Industry Overview
The floating offshore wind power market is moderately fragmented. Some major players in the market include General Electric Company, Doosan Energy, Siemens Gamesa Renewable Energy, BW Ideaol SA, and Vestas Wind Systems AS.
Additional Benefits:
The market estimate (ME) sheet in Excel format
3 months of analyst support
Key Highlights
Over the medium term, rising investments in offshore renewable wind energy projects, coupled with advanced and readily accessible offshore wind turbine technologies, are expected to be major drivers of the floating offshore wind market during the forecast period.
On the other hand, tough competition from alternate renewable energy markets will restrain the floating offshore wind market during the forecast period.
Nevertheless, floating offshore wind energy is becoming more popular in developing untapped deep-water prospects favorable for floating structures, providing ample opportunities for the market players.
Europe is expected to dominate the floating offshore wind market during the forecast period.
Floating Offshore Wind Power Market Trends
The Transitional Water (30 m to 60 m depth) Segment is Expected to Grow
Due to the greater water depth and favorable project economics, floating offshore wind turbine (FOWT) technology is more developed in transitional water depths (30-60 meters). The barge variant is the most commercially viable floating wind turbine design at shallow depths. This model is appropriate for activities higher than 30 meters (m) and has the shallowest draft of any floating foundation.
Barge-style floating wind turbines have a square footprint, while other designs incorporate a moonpool to lessen stresses brought on by wave-induced loads. According to GWEC, a typical 6-megawatt floating barge wind turbine weighs between 2,000 and 8,000 tons. However, BW Ideol, with its Damping Pool Barge Floating Substructure Technology, is the only company that has deployed barge-type FOWT at the MW scale.
Since the water depth is shallower, FOWT technology is less practical from a business point of view than fixed-base technology. During the forecast period, barge technology is expected to make up a small part of the FOWT market. According to the US EPA, only 5 MW of barge FOWT capacity operated globally as of 2021. Around 1,932 MW of FOWT capacity on barges, or 2.1% of all announced offshore wind substructure technologies for future projects worldwide, was announced.
Most companies attempt to market FOWT designs that can be used in deeper waters. However, some semi-submersible technologies can also be used at transitional water depths. They can function at transitional depths due to several commercial FOWT models that are built on the semi-submersible design. A few of these models were initially used in experimental projects, while others were modified for use in ventures for profit.
The US Department of Energy’s Wind Energy Technologies Office (WETO) announced on April 24, 2024, that it intended to issue a Notice of Intent involving a USD 48 million funding opportunity for regional and national research and development of offshore wind technologies, including floating offshore wind platform research and development. This promises future growth potential for the market.
According to the International Renewable Energy Agency RE Capacity 2024, the global installed offshore wind energy capacity increased by 17.26% in FY 2023-24, adding 10,696 MW in 2023 to the earlier installed capacity of 61,967 MW in 2022. Such developments show promising outlooks for the market players in the near future.
Most of the FOWT projects in transitional depths are likely to be in Europe, especially in the United Kingdom, Scandinavia, and France, where large projects are in the planning stages. During the forecast period, most of the deployments in this segment are likely to happen in these regions.
Thus, the transitional water (30 m to 60 m depth) segment is expected to grow significantly during the forecast period.
Europe is Expected to Dominate the Market
Europe holds the largest share of offshore wind energy installations globally. According to the European Union, Europe represents a quarter of global offshore wind installations. The country (primarily North Sea countries) is likely to be at the helm of the offshore wind market.
Around 85% of offshore wind installations are globally in European waters. The governments, particularly in the North Sea area, have set an ambitious target for installing offshore wind farms in their territorial waters.
The EolMed project is France's first floating pilot wind farm in the Mediterranean Sea. In May 2022, TotalEnergies announced the start of the project's construction, which is expected to be operational by 2024. The project consists of three 10 MW floating turbines on the bathymetry of the 62-meter depth and anchored to the seabed. The turbines will use a barge design with a damping pool.
According to the International Renewable Energy Agency RE Capacity 2024, the installed offshore wind energy capacity in Europe increased by 9.58% in FY 2023-24, adding 2,830 MW in 2023 to the earlier installed capacity of 29,539 MW in 2022. Such developments show promising outlooks for the market players in the near future.
In August 2023, the world’s largest floating wind farm, the Hywind Tampen Project, started operating around 140 kilometers off the coast of Norway in depths ranging from 270 to 310 meters. Hywind Tampen uses 11 floating wind turbines and has a system capacity of 88 MW. It helps power operations at offshore oil and gas platforms.
During the forecast period, these trends should make Europe a great place to do business for players involved in floating offshore wind farms.
Floating Offshore Wind Power Industry Overview
The floating offshore wind power market is moderately fragmented. Some major players in the market include General Electric Company, Doosan Energy, Siemens Gamesa Renewable Energy, BW Ideaol SA, and Vestas Wind Systems AS.
Additional Benefits:
The market estimate (ME) sheet in Excel format
3 months of analyst support
1 INTRODUCTION
1.1 Scope of the Study
1.2 Market Definition
1.3 Study Assumptions
2 EXECUTIVE SUMMARY
3 RESEARCH METHODOLOGY
4 MARKET OVERVIEW
4.1 Introduction
4.2 Floating Offshore Wind Power Potential Installed Capacity Forecast in GW, till 2029
4.3 Key Projects Information
4.3.1 Major Existing Projects
4.3.2 Upcoming Projects
4.4 Recent Trends and Developments
4.5 Government Policies and Regulations
4.6 Market Dynamics
4.6.1 Drivers
4.6.1.1 Rising investments in offshore renewable wind energy projects
4.6.1.2 Advanced and readily accessible offshore wind turbine technologies
4.6.2 Restraint
4.6.2.1 Tough competition from alternate renewable energy markets
4.7 Supply Chain Analysis
4.8 Porter's Five Forces Analysis
4.8.1 Bargaining Power of Suppliers
4.8.2 Bargaining Power of Consumers
4.8.3 Threat of New Entrants
4.8.4 Threat of Substitute Products and Services
4.8.5 Intensity of Competitive Rivalry
5 MARKET SEGMENTATION
5.1 By Water Depth (Qualitative Analysis Only)
5.1.1 Shallow Water (less than 30 m depth)
5.1.2 Transitional Water (30 m to 60 m depth)
5.1.3 Deep Water (higher than 60 m depth)
5.2 By Geography
5.2.1 North America
5.2.1.1 United States
5.2.1.2 Canada
5.2.1.3 Rest of North America
5.2.2 Europe
5.2.2.1 United Kingdom
5.2.2.2 Germany
5.2.2.3 France
5.2.2.4 Italy
5.2.2.5 Spain
5.2.2.6 Nordic Countries
5.2.2.7 Russia
5.2.2.8 Rest of Europe
5.2.3 Asia-Pacific
5.2.3.1 China
5.2.3.2 India
5.2.3.3 Japan
5.2.3.4 Indonesia
5.2.3.5 Malaysia
5.2.3.6 Vietnam
5.2.3.7 Rest of Asia-Pacific
5.2.4 South America
5.2.4.1 Brazil
5.2.4.2 Argentina
5.2.4.3 Colombia
5.2.4.4 Rest of South America
5.2.5 Middle East and Africa
5.2.5.1 Saudi Arabia
5.2.5.2 United Arab Emirates
5.2.5.3 Egypt
5.2.5.4 South Africa
5.2.5.5 Nigeria
5.2.5.6 Rest of the Middle East and Africa
6 COMPETITIVE LANDSCAPE
6.1 Mergers, Acquisitions, Collaboration and Joint Ventures
6.2 Strategies Adopted by Key Players
6.3 Company Profiles
6.3.1 Vestas Wind Systems AS
6.3.2 General Electric Company
6.3.3 Siemens Gamesa Renewable Energy SA
6.3.4 BW Ideol AS
6.3.5 Equinor ASA
6.3.6 Marubeni Corporation
6.3.7 Macquarie Group Limited
6.3.8 Doosan Enerbility Co. Ltd
6.4 Market Ranking Analysis
7 MARKET OPPORTUNITIES AND FUTURE TRENDS
7.1 Developing Floating Offshore Wind Projects in untapped offshore deep-water prospects
1.1 Scope of the Study
1.2 Market Definition
1.3 Study Assumptions
2 EXECUTIVE SUMMARY
3 RESEARCH METHODOLOGY
4 MARKET OVERVIEW
4.1 Introduction
4.2 Floating Offshore Wind Power Potential Installed Capacity Forecast in GW, till 2029
4.3 Key Projects Information
4.3.1 Major Existing Projects
4.3.2 Upcoming Projects
4.4 Recent Trends and Developments
4.5 Government Policies and Regulations
4.6 Market Dynamics
4.6.1 Drivers
4.6.1.1 Rising investments in offshore renewable wind energy projects
4.6.1.2 Advanced and readily accessible offshore wind turbine technologies
4.6.2 Restraint
4.6.2.1 Tough competition from alternate renewable energy markets
4.7 Supply Chain Analysis
4.8 Porter's Five Forces Analysis
4.8.1 Bargaining Power of Suppliers
4.8.2 Bargaining Power of Consumers
4.8.3 Threat of New Entrants
4.8.4 Threat of Substitute Products and Services
4.8.5 Intensity of Competitive Rivalry
5 MARKET SEGMENTATION
5.1 By Water Depth (Qualitative Analysis Only)
5.1.1 Shallow Water (less than 30 m depth)
5.1.2 Transitional Water (30 m to 60 m depth)
5.1.3 Deep Water (higher than 60 m depth)
5.2 By Geography
5.2.1 North America
5.2.1.1 United States
5.2.1.2 Canada
5.2.1.3 Rest of North America
5.2.2 Europe
5.2.2.1 United Kingdom
5.2.2.2 Germany
5.2.2.3 France
5.2.2.4 Italy
5.2.2.5 Spain
5.2.2.6 Nordic Countries
5.2.2.7 Russia
5.2.2.8 Rest of Europe
5.2.3 Asia-Pacific
5.2.3.1 China
5.2.3.2 India
5.2.3.3 Japan
5.2.3.4 Indonesia
5.2.3.5 Malaysia
5.2.3.6 Vietnam
5.2.3.7 Rest of Asia-Pacific
5.2.4 South America
5.2.4.1 Brazil
5.2.4.2 Argentina
5.2.4.3 Colombia
5.2.4.4 Rest of South America
5.2.5 Middle East and Africa
5.2.5.1 Saudi Arabia
5.2.5.2 United Arab Emirates
5.2.5.3 Egypt
5.2.5.4 South Africa
5.2.5.5 Nigeria
5.2.5.6 Rest of the Middle East and Africa
6 COMPETITIVE LANDSCAPE
6.1 Mergers, Acquisitions, Collaboration and Joint Ventures
6.2 Strategies Adopted by Key Players
6.3 Company Profiles
6.3.1 Vestas Wind Systems AS
6.3.2 General Electric Company
6.3.3 Siemens Gamesa Renewable Energy SA
6.3.4 BW Ideol AS
6.3.5 Equinor ASA
6.3.6 Marubeni Corporation
6.3.7 Macquarie Group Limited
6.3.8 Doosan Enerbility Co. Ltd
6.4 Market Ranking Analysis
7 MARKET OPPORTUNITIES AND FUTURE TRENDS
7.1 Developing Floating Offshore Wind Projects in untapped offshore deep-water prospects
