洋上風力タービンの世界市場 - 2022年～2027年の予測

世界の洋上風力タービンの市場規模は、2020年の123億3,500万米ドルから2027年に358億6,800万米ドルに達し、予測期間中にCAGRで16.47％の成長が予測されています。再生可能エネルギーへの依存が高まるにつれ、洋上風力タービンインフラも成長しています。

当レポートでは、世界の洋上風力タービン市場について調査分析し、市場力学、セグメント分析、地域分析、企業プロファイルなどを提供しています。

目次

第1章 イントロダクション

第2章 調査手法

第3章 エグゼクティブサマリー

第4章 市場力学

• 市場促進要因
• 市場抑制要因
• 市場機会
• ポーターのファイブフォース分析
• 業界バリューチェーン分析

第5章 洋上風力タービン市場：タイプ別

• イントロダクション
• モノパイル式
• トライポッド式
• ジャケット式
• 浮体式

第6章 洋上風力タービン市場：生産能力別

• 5MW未満
• 5MW超

第7章 洋上風力タービン市場：地域別

• イントロダクション
• 北米
  • 北米の洋上風力タービン市場：タイプ別（2020年～2027年）
  • 北米の洋上風力タービン市場：生産能力別（2020年～2027年）
  • 国別
• 南米
  • 南米の洋上風力タービン市場：タイプ別（2020年～2027年）
  • 南米の洋上風力タービン市場：生産能力別（2020年～2027年）
  • 国別
• 欧州
  • 欧州の洋上風力タービン市場：タイプ別（2020年～2027年）
  • 欧州の洋上風力タービン市場：生産能力別（2020年～2027年）
  • 国別
• 中東・アフリカ
  • 中東・アフリカの洋上風力タービン市場：タイプ別（2020年～2027年）
  • 中東・アフリカの洋上風力タービン市場：生産能力別（2020年～2027年）
  • 国別
• アジア太平洋
  • アジア太平洋の洋上風力タービン市場：タイプ別（2020年～2027年）
  • アジア太平洋の洋上風力タービン市場：生産能力別（2020年～2027年）
  • 国別

第8章 競合環境と分析

• 主要企業と戦略分析
• 新興企業と市場の収益性
• 合併・買収・合意・提携
• ベンダーの競争力マトリックス

第9章 企業プロファイル

• Siemens Gamesa Renewable Energy
• MHI Vestas
• Sewind
• Goldwind
• Envision
• GE Renewable Energy
• XEMC
• Nordex SE
• Enercon GmbH
• Hitachi Ltd

The offshore wind turbine market is expected to grow at a compound annual growth rate of 16.47% over the forecast period to reach a market size of US$35.868 billion in 2027, from US$12.335 billion in 2020. Offshore wind turbines are the pivotal infrastructure in the wind energy market. The turbines harness the wind energy and transform it into electricity. As per the offering, the offshore wind turbine market provides a plethora of services such as material expertise, welding solutions, coatings and resurfacing, design modeling of the wind turbine facility, installation sensors for regular monitoring, and conducting inspections of the sites.

As the dependence on renewables grows, the offshore wind turbine infrastructure also grows. According to International Finance Corporation (IFC) reports, while off-wind energy contributes only 0.3% of global power generation, it remains a critical resource for harnessing energy for areas around the coastline that are not connected to conventional power grids. Even there are initiatives from the government side to upscale the utility of wind energy. The demand for offshore wind turbines grows in tandem with initiatives to reduce the carbon footprints of energy systems, reduce air pollution, and contribute to the pool of renewable electricity.

As per the data by the IEA, the capacity additions of offshore wind turbines have declined by 25%. With the inception being China, considering it the epicenter of the outbreak. With the enforcement of restrictions in China, the new offshore wind farms declined by half. Gradually, as the pandemic rolled out and restrictions were eased, the market gained growth again. Similarly, since Mid-May, the offshore wind turbine market has adapted itself to the pandemic situation given that the offshore wind energy has been holding importance for the coastal nations, the market has witnessed investments in the first half of 2020 at the inception of the unlock down event, Vattenfall Hollandse invested $3.9 billion in the 1.5GW offshore wind energy facility around the Netherlands, SSE Seagreen invested $3.8 billion in an offshore wind facility in the UK, 600 MW, $3.6 billion in Taiwan by CIP Changfang Xidao and many others. The normalization of the market has been triggered by the European nations situated in the North Seas, where the high winds and shallow water provide suitable conditions to harness offshore wind energy. The launching of new policies by the European Union toward this renewable source of energy will create multiple offshore wind facilities, increasing the demand for offshore wind turbines by quadrupling.

Offshore wind energy turbine technological advancements The offshore wind energy turbines have undergone a massive shift from the models which were prone to exposure to seawater. The models in the advanced offshore wind farms are more withstanding, requiring less maintenance, replacement services, etc. The United States government also undertakes the funding of projects, industry collaborations, and national laboratory facilities to conduct research and work on innovative solutions. This aims to improve turbine performance and reduce the cost of offshore wind systems. For instance, as per the data by the United States government, firms are currently working on the project of developing an offshore wind turbine set up as around 58% of the US offshore wind turbines have a deep foundation base in the ocean where it is difficult to undertake repair and maintenance activities. Furthermore, the usage of drones, robots, and analytics modeling has reduced the cost of conducting maintenance and even brought remote assistance to the scattered offshore wind energy turbines.

Challenges in the offshore wind turbine market

Offshore wind turbines are very prone to environmental externalities. As the wind turbines are placed in increasing water depths, the task of undertaking maintenance becomes tedious and difficult. However, some of the challenges can be avoided by changing the structure to jacketed structures. But it also poses manufacturing challenges that drive up the cost of setting the turbine, which is expected to go beyond the benefits received from it. Furthermore, with the intent of cost reduction by introducing larger blades, they have introduced logistical barriers which make the process of installing the turbine difficult. Moreover, offshore wind farms have led to an effect on birds. For instance, Orsted, the Danish group's offshore wind turbine project, is at a halt as it is affecting the colony of kittiwakes. There is also resistance from the coastal dwellers who might have to vacate their communities to place the project.

Regional Analysis

The offshore wind turbine is in high demand in Western European countries such as the United Kingdom, Germany, Denmark, the Netherlands, and Belgium because the European countries have offshore lines with potential sites for placing turbines and harnessing energy, which appears to be gaining popularity in European markets. Considering the Asian nations, there would be emerging demand for turbines in Taiwan, South Korea, Japan, and Vietnam. As per the Global Offshore Wind Report, India has a 7,600 km coastline and has set a target of installing 5GW capacity by 2022 and 30GW by 2030, which seems to be appealing for offshore wind turbines. India is expected to be the emerging country to harness almost all forms of renewable energy given the diverse set of resources it has by earmarking approximately 70GW of offshore wind energy development.

Recent Development

In May 2021, Hecate Independent Power Limited (HIP), a US-based renewable energy project developer, unveiled the HIP Atlantic Project, which will deploy around 10 GW of floating & fixed wind power in the North Atlantic, United Kingdom. The project would connect offshore farmland to the national grid network and is projected to cost over USD 30 billion.

In May 2021, GE's renewable energy division revealed that it has received an order for the Dogger Bank offshore wind farm's third phase. The Haliade-X 14 MW offshore wind turbine will be delivered in 87 pieces including a five-year absolute agreement for the project, which will begin installation in 2025 and end in 2026.

Vestas introduced the V236 offshore wind turbine in February 2021, with a total energy rating output of 15 MW. The new units have a swept area of 43,743 m2 to collect most winds, a rotor diameter of 236 meters, and a high nominal power rating, allowing the system to generate up to 80 GWh of energy each year.

COVID-19 Impact

The impact of COVID-19 on the offshore wind market was positive overall. The Bureau of Ocean Energy Management established five new Wind Energy Zones in the New York Bight with an installed output of 9,800 MW, according to the Offshore Wind Market Report: 2021 Edition, accounting for a substantial share of the 2020-2021 pipeline increase. The overall installed offshore wind output in 2020 was 5,519 MW. Turbines grew in size, with typical rotor diameters exceeding 150 meters and turbine capabilities topping 7.5 megawatts. In 2020, new trends arose, such as a surge in interest in exploiting offshore wind to generate clean hydrogen. In 2020, the global pipeline for floating offshore wind energy will have increased by more than threefold to 26,529 MW.

Market Segmentation:

• By Type

Monopile

Tripod

Jacketed

Floating

• By Capacity

Less than 5 MW

Above 5 MW

• By Geography

North America

• United States
• Canada
• Mexico

South America

• Brazil
• Argentina
• Others

Europe

• Germany
• Italy
• Spain
• France
• United Kingdom
• Others

Middle East and Africa

• Egypt
• Saudi Arabia
• Others

Asia Pacific

• Australia
• China
• Japan
• India
• Indonesia
• Thailand
• Others

TABLE OF CONTENTS

1. INTRODUCTION

• 1.1. Market Overview
• 1.2. Covid-19 Scenario
• 1.3. Market Definition
• 1.4. Market Segmentation

2. RESEARCH METHODOLOGY

• 2.1. Research Data
• 2.2. Assumptions

3. EXECUTIVE SUMMARY

• 3.1. Research Highlights

4. MARKET DYNAMICS

• 4.1. Market Drivers
• 4.2. Market Restraints
• 4.3. Market Opportunities
• 4.4. Porter's Five Force Analysis
  • 4.4.1. Bargaining Power of Suppliers
  • 4.4.2. Bargaining Power of Buyers
  • 4.4.3. Threat of New Entrants
  • 4.4.4. Threat of Substitutes
  • 4.4.5. Competitive Rivalry in the Industry
• 4.5. Industry Value Chain Analysis

5. Offshore Wind Turbine Market, By Type

• 5.1. Introduction
• 5.2. Monopile
• 5.3. Tripod
• 5.4. Jacketed
• 5.5. Floating

6. Offshore Wind Turbine Market, By Capacity 

• 6.1. Less than 5 MW
• 6.2. Above 5 MW

7. Offshore Wind Turbine Market, By Geography

• 7.1. Introduction
• 7.2. North America
  • 7.2.1. North America Offshore Wind Turbine Market, By Type, 2020 to 2027
  • 7.2.2. North America Offshore Wind Turbine Market, By Capacity, 2020 to 2027
  • 7.2.3. By Country
    • 7.2.3.1. United States
    • 7.2.3.2. Canada
    • 7.2.3.3. Mexico
• 7.3. South America
  • 7.3.1. South America Offshore Wind Turbine Market, By Type, 2020 to 2027
  • 7.3.2. South America Offshore Wind Turbine Market, By Capacity, 2020 to 2027
  • 7.3.3. By Country
    • 7.3.3.1. Brazil
    • 7.3.3.2. Argentina
    • 7.3.3.3. Others
• 7.4. Europe
  • 7.4.1. Europe Offshore Wind Turbine Market, By Type, 2020 to 2027
  • 7.4.2. Europe Offshore Wind Turbine Market, By Capacity, 2020 to 2027
  • 7.4.3. By Country
    • 7.4.3.1. Germany
    • 7.4.3.2. France
    • 7.4.3.3. United Kingdom
    • 7.4.3.4. Italy
    • 7.4.3.5. Spain
    • 7.4.3.6. Others
• 7.5. Middle East and Africa
  • 7.5.1. Middle East and Africa Offshore Wind Turbine Market, By Type, 2020 to 2027
  • 7.5.2. Middle East and Africa Offshore Wind Turbine Market, By Capacity, 2020 to 2027
  • 7.5.3. By Country
    • 7.5.3.1. Egypt
    • 7.5.3.2. Saudi Arabia
    • 7.5.3.3. Others
• 7.6. Asia Pacific
  • 7.6.1. Asia Pacific Offshore Wind Turbine Market, By Type, 2020 to 2027
  • 7.6.2. Asia Pacific Offshore Wind Turbine Market, By Capacity, 2020 to 2027
  • 7.6.3. By Country
    • 7.6.3.1. Australia
    • 7.6.3.2. China
    • 7.6.3.3. Japan
    • 7.6.3.4. India
    • 7.6.3.5. Indonesia
    • 7.6.3.6. Thailand
    • 7.6.3.7. Others

8. COMPETITIVE ENVIRONMENT AND ANALYSIS

• 8.1. Major Players and Strategy Analysis
• 8.2. Emerging Players and Market Lucrativeness
• 8.3. Mergers, Acquisitions, Agreements, and Collaborations
• 8.4. Vendor Competitiveness Matrix

9. COMPANY PROFILES

• 9.1. Siemens Gamesa Renewable Energy
• 9.2. MHI Vestas
• 9.3. Sewind
• 9.4. Goldwind
• 9.5. Envision
• 9.6. GE Renewable Energy
• 9.7. XEMC
• 9.8. Nordex SE
• 9.9. Enercon GmbH
• 9.10. Hitachi Ltd