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EV充電用エネルギー貯蔵システムの世界市場:住宅、商業施設向けの先進的なバッテリー搭載EV充電器

Market Data - Energy Storage for EV Charging: Advanced Battery-Enabled EV Chargers for Residential and Commercial Markets - Global Market Analysis and Forecast

出版日: | 発行: Guidehouse Insights (formerly Navigant Research) | ページ情報: 英文 25 Pages; 41 Tables, Charts & Figures | 納期: 即納可能 即納可能とは

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EV充電用エネルギー貯蔵システムの世界市場:住宅、商業施設向けの先進的なバッテリー搭載EV充電器
出版日: 2020年07月20日
発行: Guidehouse Insights (formerly Navigant Research)
ページ情報: 英文 25 Pages; 41 Tables, Charts & Figures
納期: 即納可能 即納可能とは
  • 全表示
  • 概要
  • 図表
  • 目次
概要

世界規模で電気自動車(EV)の普及が拡大するなか、高速充電システムの需要も高まっています。エネルギー貯蔵システムと充電ステーションを統合したシステムもそうした需要に対応する技術の1つで、需要が低下する時間帯に送電網から充電を行い、ピーク需要時にEVに充電を行うことも可能です。エネルギー貯蔵システムは、ピークシェービングを行ってEV充電ソリューションの費用対効果を高めるだけではなく、再生可能エネルギーリソース(太陽光発電など)のEV充電ステーションへの統合を実現するうえでも不可欠です。

当レポートは、世界のEV充電用エネルギー貯蔵システムの市場を調査したもので、技術や市場の問題、市場予測などの情報を提供しています。

当レポートが対応している主な疑問点:

  • エネルギー貯蔵が可能なEV充電器の主な市場促進要因と課題
  • EV充電システムで使用されているエネルギー貯蔵技術
  • 現在進行中のプロジェクト
  • 最も有望な市場
  • エネルギー貯蔵に対応したEV充電器が商業、工業、住宅部門のユーザーに及ぼす影響
  • これらの技術の継続的な成功を確実にするため各国政府、メーカー、インテグレーターが取り組むべき課題

目次

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
  • 市場予測

第2章 技術の問題

  • 充電アーキテクチャ
  • EV充電電力レベル
  • EV充電システムの設置場所

第3章 市場の問題

  • 市場動向
    • 定常充電
    • モバイル充電
  • 市場成長要因
    • 大容量充電の需要
    • ピーク需要時の送電網の負荷軽減
    • 中古バッテリー
  • 市場の課題
    • 高コスト
    • 環境への悪影響

第4章 市場予測

  • 調査手法
  • 地域別の充電能力
  • 充電システム設置場所別の能力
  • 結論・提言

第5章 頭字語と略語のリスト

第6章 目次

第7章 図表

第8章 調査範囲、資料、 調査手法、注記

図表

LIST OF CHARTS AND FIGURES

  • Total ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Total Stationary ESEV Charging Energy Capacity and Revenue by Region, World Markets: 2020-2029
  • Total Stationary Chargers with ESEV Charging by Location Type, World Markets: 2020-2029
  • Total ESEV Charging Energy Capacity by Charging Location Type, World Markets: 2020-2029
  • Total Mobile and Stationary ESEV Charging Energy Capacity by Application, World Markets: 2020-2029
  • Total Number of Mobile and Stationary Chargers for ESEV Charging by Application, World Markets: 2020-2029
  • Total Mobile and Stationary Energy Storage Revenue for ESEV Charging by Application, World Markets: 2020-2029
  • Mobile ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Home Charger with Battery Storage
  • Mobile Charger

LIST OF TABLES

  • EV Charging Breakdown of Power Ratings by Power Level, World Markets: 2020
  • Installed Cost per Kilowatt-Hour of Li-Ion Battery System Pricing by Technology, US Market: 2020-2029
  • Residential Installed ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Fleet Installed ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Private Installed ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Public Installed ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Mobile Installed ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Total Installed Stationary ESEV Charging Power Capacity by Region, World Markets: 2020-2029
  • Residential Installed ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Residential ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Fleet ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Fleet ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Private ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Private ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Public ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Public ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Mobile ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Mobile ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Total Stationary ESEV Charging Energy Capacity by Region, World Markets: 2020-2029
  • Total Stationary ESEV Charging Revenue by Region, World Markets: 2020-2029
  • Home Charging Ports by Region, World Markets: 2012-2030
  • Apartment Charging Ports by Region, World Markets: 2012-2030
  • Workplace Charging Ports by Region, World Markets: 2012-2030
  • Fleet Charging Ports by Region, World Markets: 2012-2030
  • Public Charging Ports by Region, World Markets: 2012-2030
  • Residential Chargers with ESEV Charging by Region, World Markets: 2020-2029
  • Fleet Chargers with ESEV Charging by Region, World Markets: 2020-2029
  • Private Chargers with ESEV Charging by Region, World Markets: 2020-2029
  • Public Chargers with ESEV Charging by Region, World Markets: 2020-2029
  • Mobile Chargers with ESEV Charging by Region, World Markets: 2020-2029
  • Total Stationary Chargers with ESEV Charging by Region, World Markets: 2020-2029
目次
Product Code: MD-ESEV-20

As the rate of EV adoption increases across global markets, so does the demand for accessible and faster charging. To accelerate growth in this sector, charging networks must provide faster charging without incurring high demand charges or heavy costs for new infrastructure upgrades. One solution is the integration of energy storage systems into charging stations. A battery storage system can feed from the grid during low demand and release power to charge an EV during peak demand time. Energy storage not only aids in peak shaving to make EV charging solutions more cost effective but also is needed to support integration of renewable energy resources (e.g., solar PV) into EV charging stations.

Energy storage for EV (ESEV) is providing increasing opportunities across multiple markets. Many companies have cited issues with high demand charges at their stations that can be addressed with the integration of battery storage to alleviate strain on the grid. Although peak shaving and higher charging capabilities remain the two leading drivers for the ESEV market, the current high costs of battery storage and some negative environmental impacts still pose challenges to wider market adoption. Solutions such as second-life battery applications can bridge the gap to provide more sustainable options in the ESEV market.

This ‘Guidehouse Insights report’ looks closely at existing and emerging ESEV technology to create a comprehensive analysis of the global market. The report outlines the EV charging market, how energy storage can play a vital role in the market, and key technology considerations driving the EV charging industry. Charging location types covered include residential, fleet, private, public, and mobile. The charging levels discussed include alternating current (AC) Level 1-Level 3 (L1-L3), and direct current (DC). The report explores five global regions and provides forecasts through 2029.

KEY QUESTIONS ADDRESSED:

  • What are the key market drivers and challenges for energy storage-enabled EV chargers?
  • What types of energy storage technologies are being used in EV chargers?
  • What projects and trends are being observed in the ESEV market?
  • Where are energy storage for EV charging systems gaining the most traction?
  • How will energy storage-enabled EV chargers affect commercial and industrial and residential customers?
  • What should government, manufacturers, and integrators do to ensure the continued success of these technologies?

WHO NEEDS THIS REPORT:

  • Advanced battery manufacturers and vendors
  • Stationary energy storage customers
  • Energy storage technology vendors
  • EV charging companies
  • EV OEMs
  • Energy storage software providers
  • Investor community

Table of Contents

1. Executive Summary

  • 1.1. Introduction
  • 1.2. Report Scope
  • 1.3. Market Forecasts

2. Technology Issues

  • 2.1. Charging Architecture
  • 2.2. EV Charging Power Levels
  • 2.3. EV Charging Location Types

3. Market Issues

  • 3.1. Market Trends
    • 3.1.1. Stationary Charging
      • 3.1.1.1. North America
      • 3.1.1.2. Europe
      • 3.1.1.3. Asia Pacific
      • 3.1.1.4. Middle East & Africa
    • 3.1.2. Mobile Charging
  • 3.2. Market Drivers
    • 3.2.1. Demand for High Capacity Charging
    • 3.2.2. Grid Alleviation During Peak Demand
    • 3.2.3. Second-Life Batteries
  • 3.3. Market Challenges
    • 3.3.1. High Costs
    • 3.3.2. Adverse Environmental Impacts

4. Market Forecasts

  • 4.1. Methodology
  • 4.2. Capacity by Region
  • 4.3. Capacity by Charging Location Type
  • 4.4. Conclusions and Recommendations

5. Acronym and Abbreviation List

6. Table of Contents

7. Table of Charts and Figures

8. Scope of Study, Sources and Methodology, Notes

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