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海底送電の世界市場予測 - HVDC・HVAC海底電源ケーブル:需要促進因子・技術課題・有望プロジェクト・主要企業

Submarine Electricity Transmission - HVDC and HVAC Submarine Power Cables: Demand Drivers, Technology Issues, Prominent Projects, Key Industry Players and Global Market Forecasts

発行 Navigant Research 商品コード 205764
出版日 ページ情報 英文 69 Pages; 38 Tables, Charts & Figures
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海底送電の世界市場予測 - HVDC・HVAC海底電源ケーブル:需要促進因子・技術課題・有望プロジェクト・主要企業 Submarine Electricity Transmission - HVDC and HVAC Submarine Power Cables: Demand Drivers, Technology Issues, Prominent Projects, Key Industry Players and Global Market Forecasts
出版日: 2015年06月23日 ページ情報: 英文 69 Pages; 38 Tables, Charts & Figures
概要

HVDC (高圧直流送電) および HVAC (高圧交流送電) 海底送電システムは規模が大きく専門性が高い市場です。欧州において、送電システムは、石炭・原子力発電所の引退およびその他の離れたオフショア地域と同様、ノルディック地域におけるオフショア・オンショア風力発電の急成長によって、大規模な再構築・拡大が求められています。欧州市場は今後10年間にわたり世界の海底ケーブルプロジェクトの半数以上を構成すると見込まれています。世界の海底送電市場は、2015年の168億米ドルから、2024年に248億米ドルへ拡大すると予測されています。

当レポートでは、世界の高電圧海底電力ケーブル市場を取り上げ、市場動向、市場における供給阻害要因および需要促進要因、規制および施策、ならびに市場の課題を概括するとともに、技術的な問題および市場予測をまとめ、主要企業のプロファイルを交えて、お届けいたします。

第1章 エグゼクティブサマリー

第2章 市場の課題

  • イントロダクション
  • 海底送電市場の促進因子
    • 風力発電所とオフショア発電所との接続
    • 国と地域の電気グリッドの接続
    • HVACおよびHVDC海底送電が制限される地域
    • 島々を国もしくは地域の送電網へ接続
    • 同期・安全性のための州、国、および地域グリッドの相互接続
    • 2次市場の促進因子
  • 海底送電の規制と政策
    • 公海規制
    • 国家および地域組織
    • 海底送電に関する規制の将来

第3章 技術問題

  • 海底ケーブルのイントロダクション
  • 海底ケーブル技術
    • HVAC vs. HVDC技術
    • 変換所
  • ケーススタディ
  • ケーススタディ1:HVDCハイブリッド海底送電システム - Nalcor Energy の Lower Churchill Project
  • ケーススタディ2:HVDC海底送電システム - Nordic/Baltic Connector
  • ケーススタディ3:HVDCハイブリッド海底/地下システム - Central Hudson Project
  • その他の海底送電の利用例
    • 双方向HVDCケーブルの展開
    • オフショア施設への電力供給
    • アンビリカルケーブル
  • 海底ケーブルの種類
    • MIケーブル
    • SCFFケーブル
    • 押出断熱ケーブル
  • ケーブルの設置と主要送電網との接続
    • ケーブル設置に用いられる装置と技術
    • ケーブルの陸揚げと送電網への接続
  • 近い将来における課題および発展
    • 現行プロジェクトにおける諸技術の普及度
    • 将来における発展

第4章 主要企業

  • 主なHVDCシステムサプライヤー
    • ABB
    • Alstom
    • American Superconductor Corp.
    • Schweitzer Engineering Laboratories
    • Siemens
  • ケーブルおよび設備メーカー
    • LS Cable & System
    • LS Industrial Systems
    • Nexans
    • nkt cables
    • Prysmian SPA
  • 主な送電オペレーターおよびISO/RTO
    • China Southern Power Grid Company, Ltd.
    • DONG Energy
    • EDP
    • E.ON
    • GDF SUEZ (now Engie)
    • Iberdrola
    • Korea Electric Power Corporation
    • Power Grid Corporation of India Ltd.
    • RWE Innogy
    • SGCC
    • Statnett
    • TenneT
    • Vattenfall

第5章 市場予測

  • イントロダクション・予測アプローチ
  • 世界の海底送電予測
    • 北米
    • 欧州
    • アジア太平洋地域
    • その他:ラテンアメリカ・中東・アフリカ
  • 結論・提言

第6章 企業ディレクトリー

第7章 頭字語および略語リスト

第8章 目次

第9章 図表

第10章 調査範囲、情報源および調査手法、注記

図表リスト

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目次
Product Code: SET-15

HVDC and HVAC Submarine Power Cables: Demand Drivers, Technology Issues, Prominent Projects, Key Industry Players, and Global Market Forecasts.

Submarine electricity transmission systems are increasingly used for long and short hauls in undersea, lake, and river interconnection applications, such as in the Hudson River in New York or for connecting offshore wind farms across Europe. As with overhead and underground systems, many high-voltage subsea systems are moving toward high-voltage direct current (HVDC) technology, away from the historically prevalent alternating current (AC) technology.

The market for HVDC and high-voltage alternating current (HVAC) submarine electricity transmission systems is large and highly specialized. Analysis of existing and planned systems indicates that the submarine transmission industry will continue to experience substantial growth for years to come. In Europe, the transmission system requires extensive reconfiguration and expansion to deal with coal and nuclear generation plant retirements and the rapid growth of offshore and onshore wind generation in the Nordic region, as well as in other remote offshore areas. The European market will likely account for more than half of the global submarine cable projects over the next decade. According to Navigant Research, the global submarine electricity transmission market is expected to grow from $16.8 billion in 2015 to $24.8 billion in 2024.

This Navigant Research report analyzes the global market for submarine electricity transmission systems. The study provides an analysis of the market issues, including market drivers and regulations and policies, associated with submarine electricity transmission projects. Global market forecasts for project value, segmented by technology and region, extend through 2024. The report also provides case studies and examines the key technologies related to submarine electricity transmission systems, as well as the competitive landscape.

Key Questions Addressed:

  • Which technologies represent the primary components of high-voltage direct current and alternating current (HVDC and HVAC) submarine electricity transmission systems?
  • What factors affect the implementation of the different submarine electricity transmission system technologies and which technologies are now obsolete?
  • How do the market trends and opportunities related to submarine electricity transmission systems vary by region?
  • What are the primary drivers for growth in the submarine electricity transmission system market?
  • How is the submarine electricity transmission system vendor landscape changing?

Table of Contents

1. Executive Summary

  • 1.1. Market Overview
  • 1.2. Key Trends and Market Drivers
  • 1.3. Market Forecast

2. Market Issues

  • 2.1. Introduction
  • 2.2. Submarine Transmission Market Drivers
    • 2.2.1. Connecting Wind Farms and Offshore Power Generation
    • 2.2.2. Connecting National and Regional Electric Grids
    • 2.2.3. Geographical Limitations to HVAC and HVDC Submarine Electricity Transmission
    • 2.2.4. Connecting Islands with National or Regional Electric Power Grids
    • 2.2.5. Interconnecting State, Country, and Regional Grids for Synchronization and Security
    • 2.2.6. Secondary Market Drivers
      • 2.2.6.1. Developing Regional Supergrids
      • 2.2.6.2. Industrial Applications for Offshore Facilities
  • 2.3. Submarine Electricity Transmission Regulations and Policies
    • 2.3.1. High Seas Regulation
    • 2.3.2. National and Regional Organizations
      • 2.3.2.1. North America
      • 2.3.2.2. Europe
    • 2.3.3. Cable Protection Committees
    • 2.3.4. The Future of Regulations for Submarine Electricity Transmission

3. Technology Issues

  • 3.1. Introduction to Submarine Cables
  • 3.2. Submarine Cable Technologies
    • 3.2.1. HVAC versus HVDC Technologies
    • 3.2.2. Converter Stations
  • 3.3. Case Studies
    • 3.3.1. Case Study 1: HVDC Hybrid Submarine Transmission System-Nalcor Energy's Lower Churchill Project
    • 3.3.2. Case Study 2: HVDC Submarine Transmission System-Nordic/Baltic Connector
    • 3.3.3. Case Study 3: HVDC Hybrid Submarine/Underground System-Central Hudson Project
  • 3.4. Other Submarine Electricity Transmission Use Cases
    • 3.4.1. Deploying Bidirectional HVDC Cables
    • 3.4.2. Power Supplies for Offshore Facilities
    • 3.4.3. Umbilical Cables
  • 3.5. Types of Submarine Cables
    • 3.5.1. Mass-Impregnated Cables
    • 3.5.2. Self-Contained Fluid-Filled Cables
    • 3.5.3. Extruded Insulation Cables
  • 3.6. Installation of Cables and Connection to Main Power Grids
    • 3.6.1. Equipment and Technologies Used to Install Cables
    • 3.6.2. Cable Landing and Connection to Power Grid
  • 3.7. Challenges and Developments on the Horizon
    • 3.7.1. Prevalence of Technologies in Current Projects
    • 3.7.2. Future Developments

4. Key Industry Players

  • 4.1. Major HVDC System Suppliers
    • 4.1.1. ABB
    • 4.1.2. Alstom
    • 4.1.3. American Superconductor Corp.
    • 4.1.4. Schweitzer Engineering Laboratories
    • 4.1.5. Siemens
  • 4.2. Cable and Equipment Vendors
    • 4.2.1. LS Cable & System
    • 4.2.2. LS Industrial Systems
    • 4.2.3. Nexans
    • 4.2.4. nkt cables
    • 4.2.5. Prysmian SPA
  • 4.3. Key Transmission Operators and ISOs/RTOs
    • 4.3.1. China Southern Power Grid Company, Ltd.
    • 4.3.2. DONG Energy
    • 4.3.3. EDP
    • 4.3.4. E.ON
    • 4.3.5. GDF SUEZ (now Engie)
    • 4.3.6. Iberdrola
    • 4.3.7. Korea Electric Power Corporation
    • 4.3.8. Power Grid Corporation of India Ltd.
    • 4.3.9. RWE Innogy
    • 4.3.10. SGCC
    • 4.3.11. Statnett
    • 4.3.12. TenneT
    • 4.3.13. Vattenfall

5. Market Forecasts

  • 5.1. Introduction and Forecast Approach
  • 5.2. Global Submarine Electricity Transmission Forecasts
    • 5.2.1. North America
    • 5.2.2. Europe
    • 5.2.3. Asia Pacific
    • 5.2.4. Rest of World: Latin America, Middle East, and Africa
  • 5.3. Conclusions and Recommendations

6. Company Directory

7. Acronym and Abbreviation List

8. Table of Contents

9. Table of Charts and Figures

10. Scope of Study, Sources and Methodology, Notes

List of Charts and Figures

  • Annual Submarine Electricity Transmission Project Value by Region, World Markets: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Region, World Markets: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, World Markets: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, North America: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, Europe: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, Asia Pacific: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, Rest of World: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, World Markets: 2015-2024
  • Horns Rev 1-3 Wind Turbine Cable Installation Schematic
  • European Submarine Supergrid
  • Ocean Jurisdictions by Distance from Shore
  • Current ENTSO-E Countries with TSOs in the European Market
  • Diagram of HVDC Submarine Cable System
  • Diagram of HVDC Light Converter Station
  • HVDC Submarine Electricity Transmission System-Labrador to Newfoundland Crossing
  • HVDC Submarine Electricity Transmission System-NordBalt Connector
  • Champlain Hudson Power Express Submarine HVDC System
  • Bidirectional Interconnection of Wind Turbines in the North Sea
  • Umbilical Cables Connected to Horns Rev 2 Wind Farm Transmission Station
  • Cross-Section of XLPE Submarine Power Cable
  • Prysmian's Giulio Verne Cable-Laying Ship
  • Cable-Laying Barge ATM Discoverer at Rhyl Flats Wind Farm
  • Submarine Power Cable Tow-Plough
  • Cable Jetting SmartJet Hydraulic Plough ROV
  • Submarine Cable Landing and Connection to Converter Stations

List of Tables

  • Annual Submarine Electricity Transmission Project Value by Region, World Markets: 2015-2024
  • Submarine Electricity Transmission Project Value Share by Region, World Markets: 2015 and 2024
  • Cumulative Submarine Electricity Transmission Project Value by Region, World Markets: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, World Markets: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, World Markets: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, North America: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, North America: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, Europe: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, Europe: 2014-2023
  • Annual Submarine Electricity Transmission Project Value by Technology, Asia Pacific: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, Asia Pacific: 2015-2024
  • Annual Submarine Electricity Transmission Project Value by Technology, Rest of World: 2015-2024
  • Cumulative Submarine Electricity Transmission Project Value by Technology, Rest of World: 2014-2023
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