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EUにおける洋上風力発電市場の分析

Analyzing the Offshore Wind Power Market in EU 2015

発行 Aruvian's R'search 商品コード 243518
出版日 ページ情報 英文 220 pages
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EUにおける洋上風力発電市場の分析 Analyzing the Offshore Wind Power Market in EU 2015
出版日: 2015年12月01日 ページ情報: 英文 220 pages
概要

当レポートでは、EUにおける洋上(オフショア)風力発電市場について調査分析し、市場全体/主要国の動向、EUに与える利益、直面している課題、京都議定書の目標達成に果たす役割などを検証し、主要発電所のプロファイルも含めてお届けいたします。

エグゼクティブサマリー

イントロダクション:風力発電

  • クリーンな自然エネルギー:風力発電
  • 風力発電の概要
  • 風力から電気
  • 風力タービンの働き
  • 風力発電技術
  • 風力発電市場
  • 風力発電の可変性に対応
  • 環境影響

風力エネルギーの成長促進要因

  • 供給保証
  • 環境潜在性
    • 気候変動と風力発電
    • クリーンな開発メカニズム(CDM)
  • 風力エネルギーを利用したCDMプロジェクト
  • 経済的実現可能性
  • 地方の雇用と開発
  • 再生可能エネルギーの割当
  • ポートフォリオの多様性
  • 技術

世界の風力発電市場

  • 市場プロファイル
  • 世界経済不況と風力発電市場の実績
  • 市場統計
  • 地域別市場分析
    • アフリカ・中東
    • アジア
    • 欧州
    • 北米
    • 南米(ラテンアメリカ)
    • 太平洋地域
  • 世界の風力資源
  • 将来のシナリオ

イントロダクション:洋上風力エネルギー

洋上風力発電所のコストと利益

EUにおけるエネルギー状況

EUにおける洋上風力発電市場の分析

EUの洋上風力発電市場に対する影響

京都議定書の目標と洋上風力発電の役割

EUにおける洋上風力発電のコスト

EUにおける洋上風力発電市場の国別分析

  • ベルギー
  • デンマーク
  • フランス
  • ドイツ
  • アイルランド
  • スペイン
  • スウェーデン
  • 英国

EUにおける洋上風力発電所の分析

EUにおける洋上風力発電産業のサプライチェーンの発展分析

将来の展望:EUの洋上風力エネルギー市場

洋上風力タービンのメーカーの分析

付録

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目次

In many parts of the world, wind energy has already grown to be a mainstream energy source. This growth has long been driven by concerns about global climate change, mainly in the developed world and especially in Europe.

The possibility of locating wind turbines in the sea bed has opened up a new frontier for wind power, especially in the countries of northern Europe, where the availability of relatively shallow coastal waters has combined with the need to find space for much larger projects than are possible on land.

The pioneer in offshore wind farming has been Denmark, which has installed the two largest wind parks in the sea - 160 MW at Horns Rev in the North Sea and 158 MW at Nysted in the Baltic. Two further large developments at the same sites are now progressing.

The UK has also taken on a leading role, with 214 MW already built in four locations, a further 1,000 MW+ with agreement to proceed across eight sites, and even larger individual projects (of up to 1,000 MW each) planned within three strategic offshore areas identified by the UK government.

Aruvian Research brings a research report on the Offshore Wind Power Market in the European Union - Analyzing the Offshore Wind Power Market in EU.

Aruvian's research report Analyzing the Offshore Wind Power Market in EU starts off with an analysis of the basics about wind power and then takes a look at the various factors driving the wind power industry worldwide, and especially in the European Union. The economic feasibility of wind power is also a factor that is touched upon during the analysis of factors driving growth in the wind power industry worldwide. An introduction to offshore wind power and how it is impacting the energy industry worldwide is also discussed.

We analyze the overall market for offshore wind power in the European Union, along with a country-wise analysis of the major regions involved in offshore wind power developments, the benefits of offshore wind power for the European Union, the challenges facing offshore wind power in the EU, the role of offshore wind power in meeting the targets of the Kyoto Protocol, and an analysis of the major offshore wind farms in the EU.

A case study takes a look at the fast-growing offshore wind energy in China. Economic value of an offshore grid in the European Union is also described here.

The developing supply chain in the EU offshore wind industry takes a look at two cost drivers that include the turbine supply chain in the industry and also the availability of substructures.

Leading offshore wind turbine manufacturers such as Siemens AG, Vestas, Nordex, Senvion SE, BARD Engineering, and Areva are analyzed keeping in mind their role in the offshore wind sector.

The future of the offshore wind power industry in the EU is also looked at in the report.

This research report from Aruvian Research on the offshore wind power market in the EU is a comprehensive study on this subject, and provides you with a complete picture of what is going on in the offshore wind power markets in the European Union.

Table of Contents

A. Executive Summary

B. Introduction to Wind Power

  • B.1. A Clean Green Energy - Wind Power
    • B.1.1. What is Wind Power?
    • B.1.2. How does it Work?
  • B.2. Brief History of Wind Power
  • B.3. Electricity from Wind
  • B.4. How do Wind Turbines Work?
  • B.5. Wind Power Technology
  • B.6. Wind Power Markets
  • B.7. Accommodating the Variable Nature of Wind Power
  • B.8. Environmental Impact

C. Growth Drivers & Challenges for Wind Energy

  • C.1. Supply Security
  • C.2. Environmental Potential
    • C.2.1. Climate Change & Wind Power
    • C.2.2. Clean Development Mechanism
  • C.3. Wind Energy CDM Projects
  • C.4. Economic Feasibility
  • C.5. Employment & Development of Rural Areas
  • C.6. Renewable Quotas
  • C.7. Diversification of Portfolio
  • C.8. Technology

D. Global Wind Market

  • D.1. Market Profile
  • D.2. Worldwide Economic Recession & Performance of the Wind Power Market
  • D.3. Market Statistics
  • D.4. Market Analysis by Region
    • D.4.1. Africa & the Middle East
    • D.4.2. Asia
    • D.4.3. Europe
    • D.4.4. North America
    • D.4.5. South & Latin America
    • D.4.6. Pacific Region
  • D.5. World Wind Resources
  • D.6. Future of Wind Energy

E. Introduction to Offshore Wind Energy

  • E.1. Background of Offshore Wind Power
  • E.2. Basic Offshore Wind Technology
  • E.3. Analyzing Offshore Wind Energy Economics
  • E.4. Role of the Oil & Gas Industry in the Implementation of Offshore Wind Energy
  • E.5. Global Offshore Wind Market
  • E.6. Future of Offshore Wind Power Policy
  • F. Costs & Benefits of Offshore Wind Installation
  • G. Energy Situation in the EU

H. Analyzing Offshore Wind Power in the EU

  • H.1. Overview
  • H.2. Market Statistics
  • H.3. Installed Capacity of Offshore Wind in Europe
  • H.4. Market for Offshore Wind Turbines
  • H.5. Investment in Offshore Wind Market
  • H.6. Economic Value of an Offshore Grid in the EU
  • H.7. Case Study: Offshore Wind Energy in China Gaining Momentum

I. Impacts on the EU Offshore Wind Power Market

  • I.1. Market Drivers
    • I.1.1. Ensuring Energy Supply Security
    • I.1.2. Establishment of a Functioning Internal Electricity Market
    • I.1.3. Battling Climate Change
    • I.1.4. Development of Maritime Products
  • I.2. Challenges Facing Offshore Wind Power in the EU
    • I.2.1. Lack of Grid Integration
    • I.2.2. Lack of Proper R&D Initiatives
    • I.2.3. Environmental Considerations
    • I.2.4. Financing Issues

J. Kyoto Protocol Targets & Role of Offshore Wind Power

K. Cost of Offshore Wind in the EU

L. Country-wise Analysis of the EU Offshore Wind Energy Market

  • L.1. Belgium
  • L.2. Denmark
  • L.3. France
  • L.4. Germany
  • L.5. Ireland
  • L.6. Spain
  • L.7. Sweden
  • L.8. United Kingdom

M. Analyzing the Offshore Wind Farms in EU

  • M.1. Alpha Ventus Offshore Wind Farm
  • M.2. Amrumbank West
  • M.3. Anholt Offshore Wind Farm
  • M.4. Arklow Bank Wind Park
  • M.5. BARD Offshore 1
  • M.6. Barrow Offshore Wind Farm
  • M.7. Beatrice Wind Farm
  • M.8. Bligh Bank Offshore Wind Farm
  • M.9. Blyth Offshore Wind Farm
  • M.10. Borkum Riffgat Offshore Wind Farm
  • M.11. Burbo Bank Offshore Wind Farm
  • M.12. Dantysk Offshore Wind Farm
  • M.13. Egmond aan Zee (OWEZ)
  • M.14. EnBW Baltic 1 Offshore Wind Farm
  • M.15. Gemini Wind Farm
  • M.16. Gode Wind Farm
  • M.17. Greater Gabbard Wind Farm
  • M.18. Gunfleet Sands Offshore Wind Farm
  • M.19. Gwynt y Môr Offshore Wind Farm
  • M.20. Horns Rev 1 & 2
  • M.21. Horns Rev 3 Offshore Wind Farm
  • M.22. Innogy Nordsee 1 Offshore Wind Farm
  • M.23. Kentish Flats Offshore Wind Farm
  • M.24. Lillgrund Wind Farm
  • M.25. Lincs Offshore Wind Farm
  • M.26. London Array Offshore Wind Farm
  • M.27. Lynn and Inner Dowsing Wind Farm
  • M.28. Middelgrunden Offshore Wind Farm
  • M.29. Neart Na Gaoithe
  • M.30. Nordsee-Ost Offshore Wind Farm
  • M.31. North Hoyle Offshore Wind Farm
  • M.32. Nysted Offshore Wind Farm
  • M.33. Ormonde Wind Farm
  • M.34. Princess Amalia Wind Farm
  • M.35. Robin Rigg Wind Farm
  • M.36. Rhyl Flats
  • M.37. Scroby Sands Offshore Wind Farm
  • M.38. Sheringham Shoal Offshore Wind Farm
  • M.39. Thanet Wind Farm
  • M.40. Thorntonbank Wind Farm
  • M.41. Walney Wind Farm
  • M.42. West of Duddon Sands Wind Farm
  • M.43. Westermost Rough Wind Farm

N. Analyzing the Developing Supply Chain in the EU Offshore Wind Industry

  • N.1. Overview
  • N.2. Cost Driver: Turbine Supply for the Industry
  • N.3. Cost Driver: Availability of Substructures

O. Future Perspective: EU Offshore Wind Energy Market

P. Analyzing Offshore Wind Turbine Manufacturers

  • P.1. Siemens AG
    • P.1.1. Corporate Profile
    • P.1.2. Siemens and the Offshore Wind Sector
  • P.2. Vestas
    • P.2.1. Corporate Profile
    • P.2.2. Vestas and the Offshore Wind Sector
  • P.3. Nordex
    • P.3.1. Corporate Profile
    • P.3.2. Nordex and the Offshore Wind Sector
  • P.4. Senvion SE
    • P.4.1. Corporate Profile
    • P.4.2. Senvion SE and the Offshore Wind Sector
  • P.5. BARD Engineering
    • P.5.1. Corporate Profile
    • P.5.2. BARD Engineering and the Offshore Wind Sector
  • P.6. Areva SA
    • P.6.1. Corporate Profile
    • P.6.2. AREVA and the Offshore Wind Sector

Q. Appendix

R. Glossary of Terms

List of Figures

  • Figure 1: Top 10 Cumulative Capacity as of Dec 2014
  • Figure 2: Top 10 New Installed Capacity Jan-Dec 2014
  • Figure 3: Global Annual Installed Wind Capacity 1997-2014
  • Figure 4: Global Cumulative Installed Wind Capacity 1997-2014
  • Figure 5: Annual Installed Capacity by Region 2006-2014
  • Figure 6: Total Installed Wind Capacity 1997-2020 (MW)
  • Figure 7: Offshore Wind Farm Projects Developed up to 2000
  • Figure 8: Offshore Wind Farm Projects Developed up to 2011
  • Figure 9: Schematic of an Offshore Wind Facility
  • Figure 10: Primary Components and Dimensions of One of the 2-MW Turbines in Denmark's Horns Rev Offshore Wind Park
  • Figure 11: Typical Cost Breakdown for an Offshore Wind Plant in Shallow Water
  • Figure 12: Typical Offshore Wind Turbine
  • Figure 13: Available Offshore Area (km2) for Wind Farms
  • Figure 14: Technical Potential for Offshore Wind Energy in 2030 by Countries
  • Figure 15: Annual Offshore Wind Capacity Installations in Europe in 2014 (in MW)
  • Figure 16: Share of Wind Turbine Manufacturers' at end of 2014 (in MW)
  • Figure 17: European Offshore Wind Energy Market, Key Statistics, 2014
  • Figure 18: Offshore Locations with a Water Depth of less than 50 m and Mountainous Areas (above 600 m) in Europe
  • Figure 19: Installed Capacity of Offshore Wind in Europe (in MW), 2000-2015
  • Figure 20: Installation and Grid Connection of Offshore Wind Turbines in H1 2015
  • Figure 21: Share of Offshore Wind Developers in New Grid Connected Capacity in H1 2015 (in MW)
  • Figure 22: Share of Wind Turbine Manufacturers' of Grid Connected Capacity of Wind Power (in MW), in Europe, H1 2015
  • Figure 23: Share of Wind Turbine Manufacturers of Grid Connected Turbines in Europe (in Units & %), H1 2015
  • Figure 24: Offshore Wind Projects Reaching Final Investment Phase
  • Figure 25: Investments & Divestments in European Offshore Wind Power Industry (Capacity in MW), 2014-2015
  • Figure 26: Investment in Transmission Assets in the European Offshore Wind Market, 2011-H1 2015
  • Figure 27: Investments in Offshore Wind Farms, Million Euros/MW
  • Figure 28: Ireland's Offshore Wind Resource
  • Figure 29: Construction Work at Alpha Ventus Wind Farm
  • Figure 30: Anholt Offshore Wind Farm
  • Figure 31: Barrow Offshore Wind Turbines
  • Figure 32: Beatrice Wind Farm
  • Figure 33: Gunfleet Sands Offshore Wind Farm
  • Figure 34: Vestas V90 Wind Turbine at Kentish Flats
  • Figure 35: Lillgrund Wind Farm
  • Figure 36: Middelgrunden Wind Farm
  • Figure 37: Wind turbine at Ormonde Wind Farm
  • Figure 38: Robin Rigg Wind Farm
  • Figure 39: Domestic Production Capacity in Europe Compared to Demand (MW)
  • Figure 40: Hywind Concept
  • Figure 41: Blue H Concept
  • Figure 42: Outlook for Offshore Wind Development in the EU (Cumulative, GW)
  • Figure 43: General Layout for a Wind Turbine System
  • Figure 44: An Offshore Wind Farm
  • Figure 45: EWEA's Three Wind Power Scenarios to 2030
  • Figure 46: Development of the Offshore Wind Industry in Terms of Water Depth (m) and Distance to Shore (km)
  • Figure 47: Harbors Suitable for Future Offshore Wind Developments

List of Tables

  • Table 1: Environmental Footprint of Wind
  • Table 2: Wind CDM Projects
  • Table 3: Global Installed Wind Power Capacity (MW) by Regions, 2013-2014
  • Table 4: Wind Farms and Turbines Connected to the Grid at end of 2014 in Europe
  • Table 5: Ongoing Work on Offshore Wind Farms in H1 2015
  • Table 6: Investment in Offshore Wind Farms in Europe in H1 2015
  • Table 7: CO2 Emission Reduction Targets of Several EU Member States by Comparison to 1990 Levels
  • Table 8: Investment Statistics on Recent Offshore Wind Farms
  • Table 9: Average Investment Costs per MW Related to Offshore Wind Farms in Horns Rev and Nysted
  • Table 10: Operating and Planned Offshore Wind Farms in Denmark
  • Table 11: Operating and Planned Offshore Wind Farms in Sweden
  • Table 12: Production Capacity of Baltic 1 (in GWh), 2012-2014
  • Table 13: Different Types of Substructures
  • Table 14: Offshore Wind Projects in the Pipeline in Europe
  • Table 15: EU Forecast for Deployment of Wind Energy
  • Table 16: EWEA Wind Power Scenarios to 2030
  • Table 17: Vessel Availability for European Offshore Wind Installation
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