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EV充電用蓄電池 (ESEVC) の世界市場の分析・予測:先進電池対応個人用・商用EV充電器

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

発行 Navigant Research 商品コード 657568
出版日 ページ情報 英文 39 Pages; 24 Tables, Charts & Figures
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EV充電用蓄電池 (ESEVC) の世界市場の分析・予測:先進電池対応個人用・商用EV充電器 Energy Storage for EV Charging - Advanced Battery-Enabled EV Chargers for Residential and Commercial Markets: Global Market Analysis and Forecasts
出版日: 2018年06月27日 ページ情報: 英文 39 Pages; 24 Tables, Charts & Figures
概要

当レポートでは、電気自動車の充電用蓄電池 (ESEVC) 技術および市場を調査し、市場および技術の定義と概要、主要企業による製品・事業展開、ESEVCシステムの概要、蓄電池技術オプション、ESEVCの実現技術、各種区分別の蓄電容量および収益の推移と予測、将来の展望、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

第2章 市場分析

  • イントロダクション:EV充電と蓄電池
  • EV充電市場
    • 技術・出力レベル
      • AC充電
      • ワイヤレス充電
      • DC充電
  • EV充電用蓄電池
  • 市場展開
    • 米国:ChargePoint・Green Charge Networks
    • 英国:Renault・Connected Energyの二次利用電池
    • 欧州:Leclanche・Fastnedの急速充電スタンド
    • Teslaのスーパーチャージャーステーション

第3章 技術分析

  • ESEVCシステムの特徴
    • アーキテクチャ
    • プロファイル・スケジューリングに関する考察
    • 個人向けESEVC:成長推進因子
    • 商用ESEVC:成長推進因子
    • ユーティリティへの影響
  • 蓄電池技術オプション
    • リチウムイオン電池
    • フロー電池
    • フライホイール
  • ESEVC実現技術
    • 電力変換システム
    • ソフトウェア・制御系
    • システム統合サービス
  • その他の技術
    • PV対応EV充電器
    • 電池交換

第4章 市場予測

  • イントロダクション
  • 予測手法
  • 蓄電容量:地域別
  • 蓄電容量:ロケーション別
  • 蓄電容量:出力レベル別
  • 蓄電容量:技術別
  • 価格分析
  • 総論・提言

第5章 頭字語・略語

第6章 目次

第7章 図表

第8章 調査範囲・情報ソース・調査手法・注記

図表

List of Charts and Figures

  • Energy Storage for EV Charging Power Capacity and Revenue by Region, World Markets: 2018-2027
  • Energy Storage Power Capacity and Revenue by Charger Location, World Markets: 2018-2027
  • Energy Storage Power Capacity and Revenue by Charger Power Level, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity and Revenue by Technology, World Markets: 2018-2027
  • Energy Storage for EV Charging Installed Cost (CAPEX) by Technology, Global Averages: 2018-2027
  • ESEVC Demand Charge Savings
  • ESEVC Architecture Examples
  • ESEVC Architecture: Grid Integrated Battery
  • ESEVC Architecture: Charger Integrated Battery
  • ESEVC Architecture: Solar PV-Enabled Battery

List of Tables

  • Light Duty PEV Sales by Region, World Markets: 2018-2027
  • Medium and Heavy Duty PEV Sales by Region, World Markets: 2018-2027
  • Installed Charging Ports by Region, World Markets: 2018-2027
  • EV Charger Sales by Region, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity by Region, World Markets: 2018-2027
  • Energy Storage for EV Charging Revenue by Region, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity by Charger Location, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity by Charger Location, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity by Charger Power Level, World Markets: 2018-2027
  • Energy Storage for EV Charging Revenue by Charger Power Level, World Markets: 2018-2027
  • Energy Storage for EV Charging Power Capacity by Technology, World Markets: 2018-2027
  • Energy Storage for EV Charging by Technology, World Markets: 2018-2027
  • Energy Storage for EV Charging Installed Cost (CAPEX) by Technology, Global Averages: 2018-2027
  • EV Charging Summary
目次
Product Code: MF-ESEV-18

Energy storage has become a key enabling technology for front-of-the-meter and behind-the-meter applications. Grid operators, commercial business owners, and homeowners are increasingly looking to storage to help mitigate electricity reliability and cost issues. EVs and their charging systems represent one of the problems that many customers face. EV charging introduces power supply issues in the form of harmonic currents and poor power factors because of non-linear charging equipment. These issues affect the quality of power being supplied to the EV battery, thus reducing its useable life.

Since EV chargers are an electric load that can potentially create large spikes in demand, EV charging station hosts are pressured to do something about their impact on the grid. Several different solutions will address the peak demand of EVs and the associated charging issues. One solution is to implement EV charging strategies that contain the impact on the grid, thereby guaranteeing the quality of the service. The implementation of a charging strategy is related to the deployment of smart grid technologies-especially energy storage. Energy storage plays a fundamental role in the integration of the new power systems related to EV charging stations. Energy storage for EV charging (ESEVC) provides many benefits to the greater EV charging market, including reduced demand charges and improved grid stability.

This Navigant Research report examines the EV charging market, how energy storage can play a vital role, and key technology considerations that will drive this industry forward. The study analyzes the market issues, including market segmentation and the supply chain, associated with energy storage-enabled EV chargers. Global market forecasts, segmented by charger location, charger power level, technology, and region, extend through 2027. The report also examines the architectures related to ESEVC, as well as how EV charging companies are teaming up with energy storage developers to learn how to integrate and monetize energy storage systems.

Key Questions Addressed:

  • What are the key market drivers and challenges for energy storage-enabled EV chargers?
  • How will the integration of advanced batteries and energy storage affect the operational characteristics of an EV charger?
  • What types of energy storage technologies are currently being utilized in EV chargers?
  • Where are energy storage for EV charging (ESEVC) systems gaining the most traction?
  • How will energy storage-enabled EV chargers affect utilities, commercial and industrial (C&I) customers, 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
  • Electric utilities
  • Investor community

Table of Contents

1. Executive Summary

  • 1.1 Introduction
  • 1.2 Report Scope
  • 1.3 Market Forecasts

2. Market Issues

  • 2.1 Introduction: EV Charging and Energy Storage
  • 2.2 EV Charging Market
    • 2.2.1 Market Segmentation
    • 2.2.2 Technologies and Power Levels
      • 2.2.2.1 AC Charging
      • 2.2.2.2 Wireless Charging
      • 2.2.2.3 DC Charging
  • 2.3 Energy Storage for EV Charging
  • 2.4 Market Activity
    • 2.4.1 US: ChargePoint and Green Charge Networks
    • 2.4.2 UK: Renault and Connected Energy Second-Life EV Batterie
    • 2.4.3 Europe: Leclanché and Fastned Fast Charging Station
    • 2.4.4 Tesla Supercharger Stations

3. Technology Issues

  • 3.1 ESEVC System Features
    • 3.1.1 ESEVC System Architecture
    • 3.1.2 ESEVC Profile and Scheduling Considerations
    • 3.1.3 ESEVC Residential Drivers
    • 3.1.4 ESEVC Commercial Drivers
    • 3.1.5 ESEVC Utility Implications
  • 3.2 Energy Storage Technology Options
    • 3.2.1 Li-Ion Batteries
    • 3.2.2 Flow Batteries
    • 3.2.3 Flywheels
  • 3.3 ESEVC Enabling Technologies
    • 3.3.1 Power Conversion Systems
    • 3.3.2 Software and Controls
    • 3.3.3 Systems Integrator Services
  • 3.4 Other EV Charging Technologies
    • 3.4.1 Solar PV-Enabled EV Chargers
    • 3.4.2 Battery Swapping

4. Market Forecasts

  • 4.1 Introduction
  • 4.2 Methodology
  • 4.3 ESEVC Power Capacity by Region
  • 4.4 ESEVC Power Capacity by Charger Location
  • 4.5 ESEVC Power Capacity by Charger Power Level
  • 4.6 ESEVC Power Capacity by Technology
  • 4.7 Technology Pricing
  • 4.8 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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