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データセンター向け持続可能発電技術・再生可能発電技術の世界市場の分析・予測:グリーンデータセンターの発電技術とビジネスモデル

Sustainable and Renewable Power Generation for Global Data Centers - Generation Technologies and Business Models for Green Data Centers: Global Market Analysis and Forecasts

発行 Navigant Research 商品コード 742406
出版日 ページ情報 英文 35 Pages; 19 Tables, Charts & Figures
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データセンター向け持続可能発電技術・再生可能発電技術の世界市場の分析・予測:グリーンデータセンターの発電技術とビジネスモデル Sustainable and Renewable Power Generation for Global Data Centers - Generation Technologies and Business Models for Green Data Centers: Global Market Analysis and Forecasts
出版日: 2018年11月07日 ページ情報: 英文 35 Pages; 19 Tables, Charts & Figures
概要

データセンターは通常、年中無休で稼動するエネルギー集約型の施設であり、欧州委員会の推計によれば、その出力密度は538 W/mから2,153 W/mであり、10 KW/mに達するケースもあるとされています。配電・冷却・照明・IT需要が主な用途ですが、1時間の停電で平均35万ドルのコストが発生します。ビッグデータ、デジタルコンテンツ、eコマースなどへの投資の拡大により、データセンターの電力需要は今後も大幅に増大する見通しです。したがって、データセンターに供給される電力の信頼性および持続可能性を十分に理解することが非常に重要と考えられています。

当レポートでは、データセンター向け持続可能発電技術・再生可能発電技術の市場を調査し、市場の定義と概要、市場成長推進因子と障壁、持続可能発電の各種モデルとケーススタディ、分散型発電の技術・用途別の発電容量および収益の予測、各種提言などをまとめています。

第1章 エグゼクティブサマリー

  • イントロダクション
  • 調査範囲
  • 主要市場動向
  • 世界市場の展望

第2章 市場分析

  • イントロダクション
  • データセンター向け持続可能発電技術
    • 市場成長推進因子
    • 市場の障壁
  • データセンター向け持続可能発電モデル
    • グリッド接続
      • ケーススタディ:RagingWire
    • 分散型発電
      • ケーススタディ (再生可能):Microsoft
      • ケーススタディ (従来型):Wartsila

第3章 市場予測

  • 調査手法
  • 世界市場の概要
  • データセンター向け分散型発電:技術別
    • ソーラーPV
    • 小型・中型風力タービン
    • マクロタービン
    • 燃料電池
    • 天然ガス発電セット
    • ディーゼル発電セット
  • データセンター向け分散型発電:用途別
    • 常用電源
    • 重要電源
  • 総論・提言

第4章 略語など

第5章 目次

第6章 図表

第7章 調査範囲・情報ソース・調査手法・注記

図表

List of Charts and Figures

  • Annual Installed Data Center Distributed Power Generation Revenue, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Region, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Capacity by Region, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Capacity by Technology, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Technology, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Capacity by Application, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Application, World Markets: 2018-2027
  • Voltage and Frequency Transient for 75% Step Change in Load
  • Capacity (MW) for IT Sector Renewable Contracts: 2010-2016
  • Data Center Power Generation Models
  • Data Center Power Generation Business Model Comparison
  • Distributed Power Generation Model for Data Center - Microsoft
  • Distributed Power Generation Model for Data Centers - Wärtsilä

List of Tables

  • Annual Installed Data Center Distributed Power Generation Capacity by Region, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Region, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Capacity by Technology, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Technology, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Capacity by Application, World Markets: 2018-2027
  • Annual Installed Data Center Distributed Power Generation Revenue by Application, World Markets: 2018-2027
目次
Product Code: MF-SRPG-18

Data centers are critical to a functional global digital economy and society. Investment in cloud storage, colocation, and hyperscale data centers has resulted in the construction of a large volume of new data centers globally, thus increasing energy consumption. Meanwhile, edge computing has led to a shift toward more off-grid, small-scale installations closer to the point of use. With increasing digitization across emerging markets, data centers are becoming more and more advanced. Extensive use of services such as big data, Internet of Things, cloud computing, and artificial intelligence is prompting data center operators to adopt high performance, mission-critical IT infrastructure.

Data centers are energy-intensive establishments that usually run 24/7 year round. The European Commission estimates data center power densities range from 538 W/m to 2,153 W/m and can reach up to 10 KW/m. Power distribution, cooling, lighting, and IT demand are the primary use of energy. While the industry estimates that a 1-hour outage at a data center can cost $350,000 on average, this figure is expected to increase over the next 10 years. Increasing investments in big data, digital content, and e-commerce will continue to drive explosive growth in power demand for data center markets. Therefore, it is critical to understand the reliability and sustainability of power supplied to these facilities.

This Navigant Research evaluates various reliable power generation models for data centers, with a focus on distributed power generation technologies. The latter include distributed energy resources (DER) such as gensets, solar, wind, microturbines, and fuel cells. The study explores the market issues, including drivers, barriers, and trends, associated with sustainable power generation for data centers. Global market forecasts for distributed power generation technologies for data centers, segmented by region, technology, and application, extend through 2027. The report also examines the key sustainable power generation models and provides case studies for grid-connected and distributed power generation for data centers.

Key Questions Addressed:

  • Why will distributed power generation become key to increasing sustainability and efficiency across global data centers?
  • What are the main drivers of distributed and sustainable power generation technologies?
  • Which markets will offer the most growth for power generation technologies for data centers?
  • How quickly will global revenue for distributed power generation for data centers grow through 2027?
  • Which power generation model will be crucial for the future integration of DER across data centers?

Who Needs This Report:

  • Solar developers, installers, and operators
  • Wind developers, installers, and operators
  • Genset manufacturers
  • Renewables integration hardware and software providers
  • Energy storage manufacturers
  • Demand response and DER management system providers
  • Resource assessment companies
  • Investor community

Table of Contents

1. Executive Summary

  • 1.1. Introduction
  • 1.2. Scope of Report
  • 1.3. Key Market Trends
  • 1.4. Global Outlook

2. Market Issues

  • 2.1. Introduction
  • 2.2. Market Drivers for Sustainable Data Center Power Generation
  • 2.3. Market Barriers for Sustainable Data Center Power Generation
  • 2.4. Sustainable Power Generation Models for Data Centers
    • 2.4.1. Grid-Connected Power
    • 2.4.2. Distributed Power Generation
    • 2.4.3. Grid-Connected Power Generation Case Study: RagingWire
    • 2.4.4. Distributed Power Generation Case Study: Renewables - Microsoft
    • 2.4.5. Distributed Power Generation Case Study: Conventional - Wärtsilä

3. Market Forecasts

  • 3.1. Methodology
    • 3.1.1. Segmentation by Technology
    • 3.1.2. Segmentation by Application
  • 3.2. Global Market Overview
  • 3.3. Distributed Power Generation for Data Centers by Technology
    • 3.3.1. Solar PV
    • 3.3.2. Small and Medium Wind Turbines
    • 3.3.3. Microturbines
    • 3.3.4. Fuel Cells
    • 3.3.5. Natural Gas Gensets
    • 3.3.6. Diesel Gensets
  • 3.4. Distributed Power Generation for Data Centers by Application
    • 3.4.1. Primary Power
    • 3.4.2. Critical Power
  • 3.5. Conclusions and Recommendations

4. Acronym and Abbreviation List

5. Table of Contents

6. Table of Charts and Figures

7. Scope of Study, Sources and Methodology, Notes

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