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市場調查報告書

儲能技術 (EST) 年鑑 2016年

Energy Storage Technologies (EST) Yearbook 2016

出版商 Visiongain Ltd 商品編碼 372572
出版日期 內容資訊 英文 500 Pages
商品交期: 最快1-2個工作天內
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儲能技術 (EST) 年鑑 2016年 Energy Storage Technologies (EST) Yearbook 2016
出版日期: 2016年09月14日 內容資訊: 英文 500 Pages
簡介

全球6個傳統儲能技術 (EST) - 抽蓄水力式水力發電 (PHS) 、電網規模電池、蓄熱、壓縮空氣能源貯存 (CAES) 、超級電容器及飛輪儲能的支出規模,預計2016年達72億3,500萬美元。

本報告以儲能技術 (EST) 市場為焦點,提供12主要技術市場的CAPEX的預測,主要國家市場CAPEX預測,應用、技術市場詳細分析,進入障礙分析,及主要企業分析等。

第1章 報告概要

第2章 傳統、新興儲能技術 (EST)的簡介

  • 儲能技術的分類
  • 已設置儲能容量
  • 新興儲能技術的崛起
  • 傳統、新興儲能技術的主要應用
  • 本調查研究的技術的簡介
    • 抽蓄水力式水力發電 (PHS)
    • 電網規模電池
    • 壓縮空氣能源貯存 (CAES)
    • 先進CAES
    • 超級電容器/超級電容器儲能
    • 飛輪儲能
    • 蓄熱(度)
    • 液體空氣利用儲能
    • 大型氫燃料儲能系統、氫燃料電池
    • 超導體電磁儲能系統 (SMES)

第3章 全球儲能市場

  • 各國市場概要
  • 技術次級市場概要
  • EST市場促進要素、抑制因素
  • 促進EST市場的要素
  • 抑制EST市場的要素
  • 技術開發、發展平台

第4章 抽蓄水力式水力發電 (PHS) 技術

  • 全球PHS展望
  • PHS市場區分
  • 現有容量分析
  • PHS次級市場上顯示最穩定成長的是?
  • PHS部門的創新的模式
  • 全球PHS市場形勢

第5章 電網規模的電池技術

  • 全球電網規模電池展望
  • 電網規模電池的次級市場分析
    • 鋰離子電池
    • 鈉系電池
    • 液流電池儲存
    • 先進鉛酸電池儲存
    • 其他電池儲存技術

第6章 其他傳統儲能技術

  • 熱能源儲存
  • 壓縮空氣能源儲存
  • 超級電容器儲能
  • 飛輪儲能

第7章 新興儲能技術

  • 隔熱、等溫壓縮空氣能源儲存
  • 液體空氣儲能 (LAES)

第8章 下一代化學儲能技術

  • 大型氫燃料儲能系統、氫燃料電池
  • 超導性磁儲能 (SMES)
  • 下一代電池技術
  • 全球新興、下一代儲能技術市場情勢

第9章 各國市場

  • 中國
    • 儲能市場預測
    • PHS市場的焦點
    • 電網規模電池市場的焦點
    • 熱EST、CAES、超級電容器,及飛輪儲能市場的焦點
  • 美國
  • 日本
  • 義大利
  • 德國
  • 韓國
  • 英國
  • 法國
  • 西班牙
  • 印度
  • 其他 (RoW)

第10章 PEST分析

  • 政治
  • 經濟
  • 社會
  • 技術性

第11章 專家的見解

第12章 EST市場主要企業

  • PHS市場上主要企業
    • Voith Hydro
    • 東芝
    • Dongfang Electric
    • Alstom Energy
    • 其他
  • 網格儲存電池市場上的主要企業
    • NGK Insulators Ltd
    • BYD Co. Ltd
    • 住友電氣工業
    • Samsung SDI Co. Ltd
    • GE Energy Storage
    • Tesla Motors Inc.
    • 其他
  • 空氣儲能市場上主要企業
    • SustainX
    • General Compression
    • Airlight Energy
    • LightSail Energy
    • Dresser-Rand Group Inc
  • 飛輪儲能市場上主要企業
    • Amber Kinetics Inc.
    • Beacon Power
  • 熱儲能市場上主要企業
    • Highview Power Storage
    • Isentropic Ltd
  • 超級電容器儲能市場上主要企業
    • Maxwell technologies Inc.
  • EST市場上的其他企業

第13章 結論

第14章 用語

圖表清單

目錄
Product Code: ENE0067

This brand new yearbook from business intelligence provider visiongain offers the ultimate analysis of the energy storage market. Visiongain estimates that global spending on the six established energy storage technologies (EST), namely pumped hydro storage (PHS), grid-scale batteries, thermal storage, compressed air energy storage (CAES), ultracapacitors and flywheels will amount to $7,235m in 2016.

The grid-scale batteries market is set to increase substantially over the next ten years, overcoming PHS as the largest global energy storage submarkets from the early 2020s onwards. This is an example of the business-critical news that you need to know about. You need to read visiongain's objective analysis of how this will impact your company and the industry more broadly. How are you and your company reacting to this news? Are you sufficiently informed?

How this report will benefit you

In this brand-new 500 page yearbook you will find 403 in-depth tables, charts and graphs PLUS seven EXCLUSIVE interviews - all unavailable elsewhere.

This 500 page yearbook provides detailed CAPEX forecasts for the six established ESTs (PHS, grid-scale batteries, thermal storage, CAES, ultracapacitors and flywheels) over the period 2016-2026 and in-depth performance assessments for eight emerging and next-generation ESTs (adiabatic and isothermal CAES, liquid air energy storage, large-scale hydrogen storage and hydrogen fuel cells, superconducting magnetic energy storage and four innovative battery chemistries: lithium sulphur, lithium air, magnesium ion and zinc air).

By ordering and reading our brand new report today you will stay better informed and ready to act.

Report Scope

Expert opinion from seven leaders within the market:

  • Mr Petr Maralik from CEZ Group, one of Europe's biggest operators of PHS projects
  • Alexander Goldin from RusHydro, a Russian utility company active in the PHS sector
  • Mr. Paul DiRenzo, from Peak Hour Power, a US-based company developing innovative PHS facilities
  • Mr. Giw Zanganeh from Airlight Energy, a leader in thermal and air compressed energy storage
  • Mr. Gareth Brett from Highview Power, a former spin-off from the University of Leeds (UK) which is working on liquid air energy storage (LAES) technologies
  • Mr. Philippe Bouchard from EoS Energy Storage, a provider of batteries for the electric utility and transportation sectors
  • Mr. Bill Radvak and Brian Beck from American Vanadium, a leading producer of flow batteries

Forecasts for the CAPEX ($m) in the global EST market from 2016 to 2026, broken down into 12 leading technology submarkets:

  • Closed-loop / Open-loop / Innovative pumped hydro storage (PHS)
  • Lithium-ion / Sodium-based / Flow / Advanced lead acid / other batteries
  • Thermal storage
  • Compressed air energy storage (CAES)
  • Flywheels
  • Supercapacitors

CAPEX ($m) forecasts for the ten leading national markets (US, China, Japan, South Korea, India, UK, France, Germany, Spain and Italy) and the rest of the world market from 2016 to 2026, broken down into the six leading technology submarkets:

  • PHS
  • Grid-scale batteries
  • Thermal storage
  • CAES
  • Flywheels
  • Supercapacitors

Forecasts of the installed PHS capacity (MW) in the ten leading national markets and the rest of the world market from 2016 to 2026.

Details (project name, location, MW capacity, type, status and date of commissioning) of every operational, under construction and planned PHS project around the world from 2016 to 2026.

An overview and analysis of the range of applications of ESTs in the electricity sector, and their requirements.

Detailed analysis of each technology submarket with an overview of current performance characteristics, capital cost, existing capacity and subcategories of the technology, the technology's market share, outlook and applications in the electricity sector.

A barriers to entry analysis by:

  • Geographical market space in which ESTs will be utilised
  • Application
  • EST type

An analysis of the two emerging ESTs most likely to reach commercialisation over the forecast period:

  • Adiabatic and isothermal CAES
  • Liquid air energy storage (LAES)

A detailed analysis of the following next-generation ESTs:

  • Large-scale hydrogen storage and hydrogen fuel cells
  • Superconducting magnetic energy storage
  • Innovative battery chemistries: lithium-sulphur, lithium-air, magnesium-ion, zinc-air

PEST analysis of the EST market.

Analysis of leading companies operating in each technology submarket.

Leading Companies in the PHS Market

  • Voith Hydro
  • Toshiba
  • Dongfang Electric
  • Alstom Energy
  • Other Companies in the PHS Market

Leading Companies in the Grid Storage Battery Market

  • NGK Insulators Ltd
  • BYD Co. Ltd
  • Sumitomo Electric Industries Ltd.
  • Samsung SDI Co. Ltd
  • GE Energy Storage
  • Tesla Motors Inc.
  • Other Leading Companies in the Grid-Scale Battery Storage Market

Leading Companies in the Air Energy Storage Market

  • SustainX
  • General Compression
  • Airlight Energy
  • LightSail Energy
  • Dresser-Rand Group Inc.

Leading Companies in the Flywheel Market

  • Amber Kinetics Inc.
  • Beacon Power

Leading Companies in the Thermal Energy Storage Market

  • Highview Power Storage
  • Isentropic Ltd

Leading Companies in the SuperCapacitor Market

  • Maxwell technologies Inc.
  • Other Companies in the EST Market

Who should read this report?

  • Energy storage companies involved in the pumped hydro storage, compressed air energy storage (CAES), thermal storage, flywheels, batteries (Lithium-ion, sodium sulphur, flow batteries, etc.) and ultracapacitors submarkets
  • Utility companies and companies owning, operating or developing power transmission and distribution grids
  • Smart grid technology manufacturers and suppliers
  • Grid-scale energy efficiency analyst and engineering companies
  • Technology developers
  • Heads of strategic development
  • Marketing staff
  • Markets analysts
  • Procurement staff & suppliers
  • Investors & financial institutions
  • Banks
  • Governmental departments & agencies

Visiongain's study is intended for anyone requiring commercial analyses for the established, emerging and next-generation energy storage technologies market segments. You will find data, trends and predictions.

Buy our report the Energy Storage Technologies (EST) Yearbook 2016 today. Avoid missing out - get our report now.

visiongain is a trading partner with the US Federal Government.

Table of Contents

1. Report Overview

  • 1.1. Energy Storage Technology (EST) Market Overview
  • 1.2. Market Structure Overview and Market Definition
  • 1.3. Methodology
    • 1.3.1. Pumped Hydro Storage (PHS) Methodology
    • 1.3.2. Grid-Scale Battery, Thermal Storage, CAES, Ultracapacitors and Flywheels Methodology
    • 1.3.3. Next-Generation Energy Storage Technologies Methodology
  • 1.4. How This Report Delivers
  • 1.5. Key Questions Answered by this Analytical Report
  • 1.6. Why You Should Read This Report
  • 1.7. Frequently Asked Questions
  • 1.8. Associated Visiongain Reports
  • 1.9. About Visiongain

2. An Introduction to Established and Emerging Energy Storage Technologies

  • 2.1. Categorisation of Energy Storage Technologies
  • 2.2. Installed Energy Storage Capacity
  • 2.3. The Rise of Emerging Energy Storage Technologies
  • 2.4. The Key Applications of Established and Emerging Energy Storage Technologies
  • 2.5. An Introduction to the Technologies Considered In This Report
    • 2.5.1. Pumped Hydro Storage
      • 2.5.1.1. The History and Characteristics of Pumped Hydro Storage
      • 2.5.1.2. The Technology Variants in the PHS Sector
    • 2.5.2. Grid-Scale Batteries
      • 2.5.2.1. Brief Aside on Batteries
      • 2.5.2.2. Overview of the Leading Grid-Scale Battery Technologies
      • 2.5.2.3. Lithium-Ion Batteries
      • 2.5.2.4. Sodium-Based Batteries
      • 2.5.2.5. Flow Batteries
      • 2.5.2.6. Advanced Lead Acid Batteries
      • 2.5.2.7. Other Battery Designs
    • 2.5.3. Compressed Air Energy Storage (CAES)
    • 2.5.4. Advanced Compressed Air Energy Storage
    • 2.5.5. Ultracapacitors / Supercapacitors
    • 2.5.6. Flywheels
    • 2.5.7. Thermal Storage
    • 2.5.8. Liquid Air Energy Storage
    • 2.5.9. Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 2.5.10. Superconducting Magnetic Energy Storage (SMES)

3. The Global Energy Storage Market 2016-2026

  • 3.1. National Markets Overview
  • 3.2. Technology Submarkets Overview
  • 3.3. EST Market Drivers & Restraints
  • 3.4. The Factors that Will Drive the EST Market
    • 3.4.1. How Rising Energy Prices Indirectly Incentivise EST
    • 3.4.2. Investments in EST Research, Development and Demonstration
    • 3.4.3. The Importance of Renewable Energy Integration
    • 3.4.4. Smart Grids and Distributed Power Generation Systems
    • 3.4.5. How Expanding Electricity Demand Can Drive Demand for EST
    • 3.4.6. The Developing Electric and Alternative Vehicle Market as a Growth Factor
    • 3.4.7. The Potential of Deregulating the Electric Utility Markets
    • 3.4.8. Opportunities for Home Energy Storage and Arbitrage
    • 3.4.9. The Limitations of Established Energy Storage Technologies
  • 3.5. The Factors that Will Restrain the EST Market
    • 3.5.1. The High Capital Costs of Emerging Energy Storage Technologies
    • 3.5.2. Limited Cost Recovery Opportunities
    • 3.5.3. The Policy and Regulatory Challenges Ahead
    • 3.5.4. The Impact of a Weak Market Demand for EST
    • 3.5.5. Geographical and Spatial Constraints of Mature Energy Storage Technologies
    • 3.5.6. Conservatism in the Utility Industry
    • 3.5.7. The Need for Large-Scale Demonstration Projects
    • 3.5.8. Raw Material Availability
    • 3.5.9. Long Investment Cycles
  • 3.6. Technology Development and Deployment Patterns

4. Pumped Hydro Storage (PHS) Technologies

  • 4.1. PHS Global Outlook
  • 4.2. PHS Market Segmentation
  • 4.3. Analysis of Existing Capacity
  • 4.4. Which PHS Submarket Will Provide the Strongest Growth?
    • 4.4.1. Open-Loop PHS Submarket
      • 4.4.1.1. Background
      • 4.4.1. 2. CAPEX and Capacity Forecasts
      • 4.4.1.3. Drivers and Restraints
    • 4.4.2. Closed Loop PHS Submarket
      • 4.4.2.1. Background
      • 4.4.2.2. CAPEX and Capacity Forecast
      • 4.4.2.3. Drivers and Restraints
    • 4.4.3. Innovative PHS Submarket
      • 4.4.3.1. Background
      • 4.4.3.2. CAPEX and Capacity Forecast
      • 4.4.3.3. Drivers and Restraints
  • 4.5. Patterns of Innovation in the Pumped Hydro Storage Sector
    • 4.5.1. Seawater Pumped Hydro Storage
      • 4.5.1.1. History and Outlook
      • 4.5.1.2. Drivers and Restraints
    • 4.5.2. Underground PHS and Installations Using Abandoned Mines or Quarries
      • 4.5.2.1. History and Outlook
      • 4.5.2.2. Drivers and Restraints
    • 4.5.3. Small-Scale PHS and RES-PHS Hybrid Projects
      • 4.5.3.1. History and Outlook
      • 4.5.3.2. Drivers and Restraints
  • 4.6. The Global Landscape of the PHS Sector
    • 4.6.1. Market Maturity
      • 4.6.1.1. The Maturity of Different National Markets
      • 4.6.1.2. The Maturity of the Three PHS Submarkets
    • 4.6.2. Variations in Construction Characteristics between National Markets and Submarkets (Construction Times, Costs and Duration)
      • 4.6.2.1. The Variation in Construction Patterns in National Markets
      • 4.6.2.2. The Variation in Construction Costs, Times and Sizes Between PHS Submarkets
    • 4.6.3. The Top 20 Largest Installations Globally

5. Grid-Scale Battery Technologies

  • 5.1. Grid-Scale Battery Global Outlook
  • 5.2. Grid-Scale Battery Submarket Breakdown
    • 5.2.1. Lithium-Ion Battery Submarket
      • 5.2.1.1. Lithium-Ion Battery Submarket Forecast 2016-2026
      • 5.2.1.2. Lithium-Ion Battery Storage Market Analysis Drivers & Restraints
    • 5.2.2. Sodium-Based Battery Submarket
      • 5.2.2.1. Sodium-Based Battery Submarket Forecast 2016-2026
      • 5.2.2.2. Sodium-Based Battery Storage Market Analysis Drivers & Restraints
    • 5.2.3. Flow Battery Storage Submarket
      • 5.2.3.1. Flow Battery Storage Submarket Forecast 2016-2026
      • 5.2.3.2. Flow Battery Storage Market Analysis Drivers & Restraints
    • 5.2.4. Advanced Lead Acid Battery Storage Submarket
      • 5.2.4.1. Advanced Lead Acid Battery Storage Submarket Forecast 2016-2026
      • 5.2.4.2. Advanced Lead Acid Battery Storage Market Analysis Drivers & Restraints
    • 5.2.5. Other Battery Storage Technologies Submarket
      • 5.2.5.1. Other Battery Storage Technologies Submarket Forecast 2016-2026
      • 5.2.5.2. Other Battery Storage Technologies Market Analysis Drivers & Restraints

6. Other Established Energy Storage Technologies

  • 6.1. Thermal Energy Storage
    • 6.1.1. Thermal Energy Storage Global Forecast 2016-2026
    • 6.1.2. Thermal Energy Storage Background
    • 6.1.3. Main Characteristics and Applications
    • 6.1.4. The Thermal Energy Storage Market Drivers & Restraints
  • 6.2. Compressed Air Energy Storage
    • 6.2.1. Compressed Air Energy Global forecast 2016-2026
    • 6.2.2. Compressed Air Energy Background
    • 6.2.3. Main Characteristics and Applications
    • 6.2.4. The Compressed Air Energy Storage Market Drivers & Restraints
  • 6.3. Supercapacitors
    • 6.3.1. Supercapacitors Global Forecast 2016-2026
    • 6.3.2. Supercapacitors Background
    • 6.3.3. Main Characteristics and Applications
    • 6.3.4. The Supercapacitor Energy Storage Market Drivers & Restraints
  • 6.4. Flywheels
    • 6.4.1. Flywheels Global Forecast 2016-2026
    • 6.4.2. Flywheels Background
    • 6.4.3. Characteristics and Main Applications
    • 6.4.4. The Flywheels Energy Storage Market Drivers & Restraints

7. Emerging Energy Storage Technologies

  • 7.1. Adiabatic and Isothermal Compressed Air Energy Storage
    • 7.1.1. An Introduction to Adiabatic and Isothermal Compressed Air Energy Storage
    • 7.1.2. The Nature of the Innovation
    • 7.1.3. Performance and Main Characteristics
    • 7.1.4. Applications and Key Competitors of Advanced CAES
    • 7.1.5. Current Deployment of Compressed Air Energy Storage
    • 7.1.6. Drivers and Restraints of Advanced Compressed Air Energy Storage
    • 7.1.7. The Outlook for Advanced Compressed Air Energy Storage
    • 7.1.8. Companies and Stakeholders Involved in the Advanced CAES Market
  • 7.2. Liquid Air Energy Storage (LAES)
    • 7.2.1. An Introduction to Liquid Air Energy Storage
    • 7.2.2. The Nature of the Innovation
    • 7.2.3. The Performance Characteristics of Liquid Air Energy Storage
    • 7.2.4. Applications and Key Competitors of Liquid Air Energy Storage
    • 7.2.5. Current Deployment of Liquid Air Energy Storage
    • 7.2.6. Drivers and Restraints of the Liquid Air Energy Storage Market
    • 7.2.7. The Outlook for Liquid Air Energy Storage
    • 7.2.8. Companies and Stakeholders Involved in the Liquid Air Energy Storage Market

8. Next-Generation Chemical Energy Storage Technologies

  • 8.1. Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 8.1.1. An Introduction to Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 8.1.2. The Nature of the Innovation
    • 8.1.3. The Performance Characteristics of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 8.1.4. Applications and Key Competitors of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
    • 8.1.5. Current Deployment of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 8.1.6. Drivers and Restraints of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
    • 8.1.7. The Outlook of Large Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 8.1.8. Companies and Stakeholders Involved in the Hydrogen and Fuel Cells Energy Storage Market
  • 8.2. Superconducting Magnetic Energy Storage (SMES)
    • 8.2.1. An Introduction to Superconducting Magnetic Energy Storage (SMES)
    • 8.2.2. The Nature of the Innovation
    • 8.2.3. The Performance Characteristics of Superconducting Magnetic Energy Storage
    • 8.2.4. Applications and Key Competitors of Superconducting Magnetic Energy Storage
    • 8.2.5. Current Deployment of Superconducting Magnetic Energy Storage
    • 8.2.6. Drivers and Restraints of Superconducting Magnetic Energy Storage
    • 8.2.7. The Outlook for Superconducting Magnetic Energy Storage
    • 8.2.8. Companies and Stakeholders Involved in the Superconducting Magnetic Energy Storage Market
  • 8.3. Next-Generation Battery Technologies
    • 8.3.1. The Key Drivers of Innovation in the Market
    • 8.3.2. Key Patterns of Innovation in the Market
    • 8.3.3. Lithium-air (Li-Air)
      • 8.3.3.1. Nature of the Innovation
      • 8.3.3.2. The Performance Characteristics of Lithium Air Batteries
      • 8.3.3.3. The Applications and Key Competitors of Lithium Air Batteries
      • 8.3.3.4. Current Deployment of Lithium Air Batteries
      • 8.3.3.5. Drivers and Restraints of the Lithium Air Batteries Market
      • 8.3.3.6. The Outlook for Lithium Air Batteries
      • 8.3.3.7. Key Companies and Stakeholders Involved in the Lithium Air Battery Market
    • 8.3.4. Lithium-Sulphur (Li-S)
      • 8.3.4.1. Nature of The Innovation
      • 8.3.4.2. The Performance Characteristics of Lithium Sulphur Batteries
      • 8.3.4.3. Applications and Key Competitors of Lithium Sulphur Batteries
      • 8.3.4.4. Current Deployment of Lithium Sulphur Batteries
      • 8.3.4.5. Drivers and Restraints of the Lithium Sulphur Battery Market
      • 8.3.4.6. The Outlook of Lithium Sulphur Batteries
      • 8.3.4.7. Key Companies and Stakeholders Involved in the Lithium Sulphur Battery Market
    • 8.3.5. Magnesium-Ion (Mg-Ion)
      • 8.3.5.1. Nature of the Innovation
      • 8.3.5.2. Performance Characteristics of Magnesium-Ion Batteries
      • 8.3.5.3. The Applications and Key Competitors of Magnesium-Ion Batteries
      • 8.3.5.4. Current Deployment of Magnesium-Ion Batteries
      • 8.3.5.5. Drivers and Restraints of Magnesium-Ion Batteries
      • 8.3.5.6. The Outlook for Magnesium-Ion Batteries
      • 8.3.5.7. Key Companies and Stakeholders Involved in the Magnesium-Ion Battery Market
    • 8.3.6. Zinc-Air (Zn-air)
      • 8.3.6.1. Nature of the Innovation
      • 8.3.6.2. The Performance Characteristics of Zinc-Air Batteries
      • 8.3.6.3. Main Applications and Key Competitors of Zinc-Air Batteries
      • 8.3.6.4. Current Deployment of Zinc-Air Batteries
      • 8.3.6.5. The Drivers and Restraints of the Zinc Air Battery Market
      • 8.3.6.6. The Outlook for Zinc-Air Batteries
      • 8.3.6.7. Key Companies and Stakeholders in the Zinc-Air Battery Market
    • 8.3.7. General Remarks on Emerging Battery Storage Technologies
    • 8.3.8. Established and Emerging Energy Storage Technologies, a Comparative Analysis
  • 8.4. The Global Landscape of the Emerging and Next-Generation Energy Storage Technologies Market
    • 8.4.1. Next-Generation Energy Storage Technologies in North America
      • 8.4.1.1. North America General Outlook
      • 8.4.1.2. Drivers and Restraints of Next-Generation EST development and Deployment in North America
    • 8.4.2. Next-Generation Energy Storage Technologies in Europe
      • 8.4.2.1. Europe General Outlook
      • 8.4.2.2. Drivers and Restraints of Next-Generation EST Development and Deployment in Europe
    • 8.4.3. Next-Generation Energy Storage Technologies in Asia
      • 8.4.3.1. Asia General Outlook
      • 8.4.3.2. Drivers and Restraints of Next-Generation ESTs development and Deployment in Asia

9. National Markets

  • 9.1. China
    • 9.1.1. Chinese Energy Storage Market Forecast 2016-2026
    • 9.1.2. Focus on the Chinese PHS Market
      • 9.1.2.1. The Drivers and Restraints of the Chinese PHS Market
      • 9.1.2.2. Background and Evolution of Installed Capacity in the Chinese PHS Market
      • 9.1.2.3. How can the Chinese PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.1.3. Focus on the Chinese Grid-Scale Battery Market
    • 9.1.4. Focus on the Chinese Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.2. USA
    • 9.2.1. US Energy Storage Market Forecast 2016-2026
    • 9.2.2. Focus on the US PHS Market
      • 9.2.2.1. The Drivers and Restraints of the US PHS Market
      • 9.2.2.2. Background and Evolution of Installed Capacity in the US PHS Market
      • 9.2.2.3. How can the US PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.2.3. Focus on the US Grid-Scale Battery Market
      • 9.2.3.1. California: The Impact of the 1.3 GW Mandate
      • 9.2.3.2. New York
      • 9.2.3.3. Texas (ERCOT)
      • 9.2.3.4. Hawaii
      • 9.2.3.5. PJM
      • 9.2.3.6. Other Grids
    • 9.2.4. Focus on the US Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.3. Japan
    • 9.3.1. Japanese Energy Storage Market Forecast 2016-2026
    • 9.3.2. Focus on the Japanese PHS Market
      • 9.3.2.1. The Drivers and Restraints of the Japanese PHS Market
      • 9.3.2.2. Background and Evolution of Installed Capacity in the Japanese PHS Market
      • 9.3.2.3. How can the Japanese PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.3.3. Focus on the Japanese Grid-Scale Battery Market
    • 9.3.4. Focus on the Japanese Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.4. Italy
    • 9.4.1. Italian Energy Storage Market Forecast 2016-2026
    • 9.4.2. Focus on the Italian PHS Market
      • 9.4.2.1. The Drivers and Restraints of the Italian PHS Market
      • 9.4.2.2. Background and Evolution of Installed Capacity in the Italian PHS Market
      • 9.4.2.3. How can the Italian PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.4.3. Focus on the Italian Grid-Scale Battery Market
    • 9.4.4. Focus on the Italian Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.5. Germany
    • 9.5.1. German Energy Storage Market Forecast 2016-2026
    • 9.5.2. Focus on the German PHS Market
      • 9.5.2.1. The Drivers and Restraints of the German PHS Market
      • 9.5.2.2. Background and Evolution of Installed Capacity in the German PHS Market
      • 9.5.2.3. How can the German PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.5.3. Focus on the German Grid-Scale Battery Market
    • 9.5.4. Focus on the German Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.6. South Korea
    • 9.6.1. South Korean Energy Storage Market Forecast 2016-2026
    • 9.6.2. Focus on the South Korean PHS Market
      • 9.6.2.1. The Drivers and Restraints of the South Korean PHS Market
      • 9.6.2.2. Background and Evolution of Installed Capacity in the South Korean PHS Market
      • 9.6.2.3. How can the South Korean PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.6.3. Focus on the South Korean Grid-Scale Battery Market
    • 9.6.4. Focus on the South Korean Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.7. UK
    • 9.7.1. The UK Energy Storage Market Forecast 2016-2026
    • 9.7.2. Focus on the UK PHS Market
      • 9.7.2.1. The Drivers and Restraints of the UK PHS Market
      • 9.7.2.2. Background and Evolution of Installed Capacity in the UK PHS Market
      • 9.7.2.3. How can the UK PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.7.3. Focus on the UK Grid-Scale Battery Market
    • 9.7.4. Focus on the UK Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.8. France
    • 9.8.1. French Energy Storage Market Forecast 2016-2026
    • 9.8.2. Focus on the French PHS Market
      • 9.8.2.1. The Drivers and Restraints of the French PHS Market
      • 9.8.2.2. Background and Evolution of Installed Capacity in the French PHS Market
      • 9.8.2.3. How can the French PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.8.3. Focus on the French Grid-Scale Battery Market
    • 9.8.4. Focus on the French Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.9. Spain
    • 9.9.1. Spanish Energy Storage Market Forecast 2016-2026
    • 9.9.2. Focus on the Spanish PHS Market
      • 9.9.2.1. The Drivers and Restraints of the Spanish PHS Market
      • 9.9.2.2. Background and Evolution of Installed Capacity in the Spanish PHS Market
      • 9.9.2.3. How can the Spanish PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.9.3. Focus on the Spanish Grid-Scale Battery Market
    • 9.9.4. Focus on the Spanish Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.10. India
    • 9.10.1. Indian Energy Storage Market Forecast 2016-2026
    • 9.10.2. Focus on the Indian PHS Market
      • 9.10.2.1. The Drivers and Restraints of the Indian PHS Market
      • 9.10.2.2. Background and Evolution of Installed Capacity in the Indian PHS Market
      • 9.10.2.3. How can the Indian PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.10.3. Focus on the Indian Grid-Scale Battery, Thermal EST, CAES, Ultracapacitors and Flywheels Markets
  • 9.11. RoW
    • 9.11.1. The RoW Energy Storage Market Forecast 2016-2026
    • 9.11.2. Focus on the Rest of the World PHS Market
      • 9.11.2.1. The Drivers and Restraints of the Rest of the World PHS Market
      • 9.11.2.2. Background and Evolution of Installed Capacity in the Rest of the World PHS Market
      • 9.11.2.3. How can the Rest of the World PHS Market be Expected to Evolve in the Period 2016-2026?
    • 9.11.3. Focus on the Rest of the World Grid-Scale Battery, Thermal EST, CAES, Ultracapacitors and Flywheels Markets
      • 9.11.3.1. Drivers and Restraints in the Rest of the World Grid-Scale Battery, Thermal EST, CAES, Ultracapacitors and Flywheels Markets
      • 9.11.3.2. Key National Segments in the Rest of the World Grid-Scale Battery markets

10. PEST Analysis of the Energy Storage Market

  • 10.1. Political
  • 10.2. Economic
  • 10.3. Social
  • 10.4. Technological

11. Expert Opinion

  • 11.1. Expert Interview with Petr Maralík, CEZ Group
    • 11.1.1. Latest Developments at CEZ
    • 11.1.2. The Main Applications of PHS
    • 11.1.3. Pumped Hydro Storage in a Regulatory Context
    • 11.1.4. The Outlook of the Sector in Europe
    • 11.1.5. Pumped Hydro Storage in the Context of Other Energy Storage Technologies
    • 11.1.6. Innovations in the PHS Sector
  • 11.2. Expert Interview with Alexander Goldin, RusHydro
    • 11.2.1. RusHydro's Involvement in the PHS Market
    • 11.2.2. PHS Applications
    • 11.2.3. The Current Regulatory Environment
    • 11.2.4. Regional Outlook
    • 11.2.5. Topographical Restraints on the Development of New PHS Installations
    • 11.2.6. The Key Innovations and Developments in the Sector
    • 11.2.7. The Outlook for the PHS Sector
  • 11.3. Expert Interview with Paul DiRenzo, Jr from Peak Hour Power
    • 11.3.1. Peak Hour Power and its Involvement in the PHS Market
    • 11.3.2. The Growing Interest in Innovative Pumped Hydro Storage Installations
    • 11.3.3. The Opportunities and Challenges of Seawater PHS
    • 11.3.4. Competition from Other Next-Generation Bulk Storage Technologies
  • 11.4. Expert Interview with Giw Zanganeh, Airlight Energy
    • 11.4.1. Latest Developments at Airlight Energy
    • 11.4.2. CAES and Thermal Energy Storage in the Context of Other ESTs
    • 11.4.3. The Market Space and Applications of Thermal Energy Storage
    • 11.4.4. The Maturity and Key Markets of the AA-CAES Technology
  • 11.5. Expert Interview with Gareth Brett, Highview Power
    • 11.5.1. Latest Developments at Highview Power
    • 11.5.2. Liquid Air Energy Storage Technology
    • 11.5.3. The Maturity and Commercial Viability of the Technology
    • 11.5.4. The Key Challenges and Competitors
    • 11.5.5. Media Attention and the Hype Surrounding Emerging Technologies
    • 11.5.6. The Technical Specifications and Performance of the Technology
    • 11.5.7. Key Markets and Main Regulatory Drivers / Restraints
    • 11.5.8. The Status of Energy Storage Assets
    • 11.5.9. The Outlook for Next-Generation ESTs
  • 11.6. Expert Interview with Philippe Bouchard, EoS Energy Storage
    • 11.6.1. Latest Developments at EoS Energy Storage
    • 11.6.2. EoS Energy Storage and Next-Generation Battery Chemistries
    • 11.6.3. The Performance Characteristics of Eos Battery Chemistries
    • 11.6.4. The Key Competitors in the Market
    • 11.6.5. The Maturity of the Hybrid Cathode Battery Technology
    • 11.6.6. The Main Patterns of Innovation in the Energy Storage Sector
    • 11.6.7. Key National Markets
  • 11.7. Expert Interview with Bill Radvak & Brian Beck, American Vanadium
    • 11.7.1. Latest Developments at American Vanadium
    • 11.7.2. Key Markets and Recent Developments in the Grid-Scale Battery Industry
    • 11.7.3. Commercial Viability of Different Grid-Scale Battery Technologies
    • 11.7.4. Areas of Greatest Cost Reduction
    • 11.7.5. Impact of Electric Vehicle Development on the Grid-Scale Battery Industry
    • 11.7.6. Future of Government Support for Grid-Scale Batteries
    • 11.7.7. Drivers, Restraints, and Regulatory Issues Facing the Grid-Scale Battery Industry
    • 11.7.8. Perception of Grid-Scale Batteries by Utility Companies
    • 11.7.9. Key National Markets and Technological Developments
    • 11.7.10. Issues and Opportunities of Flow Batteries

12. Leading Companies in the EST Market

  • 12.1. Leading Companies in the PHS Market
    • 12.1.1. Voith Hydro
    • 12.1.2. Toshiba
    • 12.1.3. Dongfang Electric
    • 12.1.4. Alstom Energy
    • 12.1.5. Other Companies in the PHS Market
  • 12.2. Leading Companies in the Grid Storage Battery Market
    • 12.2.1. NGK Insulators Ltd
    • 12.2.2. BYD Co. Ltd
    • 12.2.3. Sumitomo Electric Industries Ltd.
    • 12.2.4. Samsung SDI Co. Ltd
    • 12.2.5. GE Energy Storage
    • 12.2.6. Tesla Motors Inc.
    • 12.2.7. Other Leading Companies in the Grid-Scale Battery Storage Market
  • 12.3. Leading Companies in the Air Energy Storage Market
    • 12.3.1. SustainX
    • 12.3.2. General Compression
    • 12.3.3. Airlight Energy
    • 12.3.4. LightSail Energy
    • 12.3.5. Dresser-Rand Group Inc.
  • 12.4. Leading Companies in the Flywheel Market
    • 12.4.1. Amber Kinetics Inc.
    • 12.4.2. Beacon Power
  • 12.5. Leading Companies in the Thermal Energy Storage Market
    • 12.5.1. Highview Power Storage
    • 12.5.2. Isentropic Ltd
  • 12.6. Leading Companies in the SuperCapacitor Market
    • 12.6.1. Maxwell technologies Inc.
  • 12.7. Other Companies in the EST Market

13. Conclusions

  • 13.1. Global EST Market
  • 13.2. Drivers and Restraints of the Global EST Market
  • 13.3. Leading National EST Markets
  • 13.4. Technology Submarkets

14. Glossary

List of Tables

  • Table 1.1: Example of Standardised Metric Used for the Comparison of Energy Storage Technologies in Radial Graphs Presented Throughout This Report
  • Table 1.2: EXAMPLE Leading National EST Markets Forecast 2016-2026 ($m, AGR %, Cumulative)
  • Table 2.1: List and Description of Main EST Applications
  • Table 2.2: PHS Main Characteristics (Lifetime, Capacity MW, Energy Rating, Cost/kW & kWh, Efficiency %, Response Time)
  • Table 2.3: Comparison of Grid-Scale Battery Storage Technologies (Maturity, Capacity MW, Output MWh, Discharge, Efficiency %, Cycles)
  • Table 3.1: Leading National EST Markets Forecast 2016-2026 ($m, AGR %, Cumulative)
  • Table 3.2: Technology Submarkets Forecast 2016-2026 ($m, AGR %, Cumulative)
  • Table 3.3: Global EST Market Drivers & Restraints
  • Table 3.4: Recent Demonstration Project Funded by ARRA ($m)
  • Table 4.1: Global PHS Market Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 4.2: Global PHS Installed Capacity Forecast 2016-2026 (GW, Cumulative)
  • Table 4.3: PHS Submarket Forecasts 2016-2026 ($m, AGR %)
  • Table 4.4: Open-Loop PHS Submarket Forecast 2016-2026 ($m, AGR%, CAGR%, Cumulative)
  • Table 4.5: Open-Loop PHS Installed Capacity Forecast 2016-2026 (GW, Cumulative)
  • Table 4.6: List of all Planned Open-loop Pumped Hydro Installations (Name, Location, MW Capacity, Commissioning)
  • Table 4.7: Drivers and Restraints in the Open Loop PHS Submarket
  • Table 4.8: List of all Operating Closed-Loop Pumped Hydro Installations (Name, Location, MW Capacity, Commissioning)
  • Table 4.9: Closed-Loop PHS Submarket Forecast 2016-2026 ($mil, AGR%, CAGR%, Cumulative)
  • Table 4.10: Closed-Loop PHS Installed Capacity Forecast 2016-2026 (MW, Cumulative)
  • Table 4.11: List of all Planned Closed-Loop Pumped Hydro Installations (Name, Location, Capacity MW, Type, Commissioning)
  • Table 4.12: Drivers and Restraints in the Closed-Loop PHS Submarket
  • Table 4.13: List of all Operating Innovative Pumped Hydro Installations (Name, Location, Capacity MW, Type, Commissioning)
  • Table 4.14: Innovative PHS Submarket Forecast 2016-2026 ($mil, AGR %, CAGR %, Cumulative)
  • Table 4.15: Innovative PHS Installed Capacity Forecast 2016-2026 (MW, Cumulative)
  • Table 4.16: List of all Planned Innovative Pumped Hydro Installations (Name, Location, MW Capacity, Type, Commissioning)
  • Table 4.17: Drivers and Restraints in the Innovative PHS Submarket
  • Table 4.18: Existing Seawater PHS projects (Name, Location, MW Capacity, Status and Commissioning Date)
  • Table 4.19: Drivers & Restraints of Seawater PHS
  • Table 4.20: Existing Underground PHS Projects (Project Name, Location, MW Capacity, Type, Status and Commissioning Date)
  • Table 4.21: Planned Underground PHS Projects (Project Name, Location, MW Capacity, Type, Status and Commissioning Date)
  • Table 4.22: Drivers & Restraints of Underground PHS and Installations Using Mines and Quarries
  • Table 4.23: Drivers & Restraints of Small-Scale PHS and Renewable-PHS Hybrid Projects
  • Table 4.24: The 20 Oldest Still-Operational PHS Installations in the World (Project Name, Location, MW Capacity, Type, Status, Commissioning Date)
  • Table 4.25: The Oldest Still-Operational Installations in Each PHS Submarket (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 4.26: Overview of the 20 Largest PHS Installations in the World (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 5.1: Global Grid-Scale Battery Storage Market Forecast 2016-2026 ($m, AGR %, CAGR%, Cumulative)
  • Table 5.2: Grid-Scale Battery Storage Submarket Forecasts 2016-2026 ($m, AGR %)
  • Table 5.3: Lithium-Ion Battery Storage Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 5.4: Lithium-Ion Battery Storage Submarket Drivers & Restraints
  • Table 5.5: Sodium-Based Battery Storage Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 5.6: Sodium-Based Battery Storage Submarket Drivers & Restraints
  • Table 5.7: Flow Battery Storage Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 5.8: Flow Battery Storage Submarket Drivers & Restraints
  • Table 5.9: Advanced Lead Acid Battery Storage Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 5.10: Advanced Lead Acid Battery Storage Submarket Drivers & Restraints
  • Table 5.11: Other Battery Storage Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 5.12: Other Battery Storage Submarket Drivers & Restraints
  • Table 6.1: Global Thermal Energy Storage Market Forecast 2016-2026 ($m, AGR %, CAGR%, Cumulative)
  • Table 6.2: Thermal Performance Characteristics (Maturity, MW Capacity, MWh Output, Discharge Duration, Efficiency %, Cycles, Cost per kW & kWh)
  • Table 6.3: Thermal Energy Storage Market Drivers & Restraints
  • Table 6.4: Global CAES Market Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 6.5: Installed CAES Capacity by National Market (MW)
  • Table 6.6: CAES Performance Characteristics (Lifetime, MW Capacity, Energy Rating, Cost per kW & kWh, Efficiency %, Response Time)
  • Table 6.7: CAES Market Drivers & Restraints
  • Table 6.8: Global Supercapacitors Market Forecast 2016-2026 ($m, AGR %, CAGR%, Cumulative)
  • Table 6.9: Supercapacitors Performance Characteristics (Lifetime, MW Capacity, Energy Rating, Cost per kW & kWh, Efficiency %, Response Time)
  • Table 6.10: Ultracapacitor Storage Market Drivers & Restraints
  • Table 6.11: Global Flywheels Market Forecast 2016-2026 ($m, AGR %, CAGR%, Cumulative)
  • Table 6.12: Performance Characteristics Flywheels ((Lifetime, MW Capacity, Energy Rating, Cost per kW & kWh, Efficiency %, Response Time)
  • Table 6.13: Flywheels Market Drivers & Restraints
  • Table 7.1: Performance Characteristics of Conventional and Advanced CAES (Lifetime, MW Capacity, Efficiency %, Maturity)
  • Table 7.2: Key Diabatic and Adiabatic Compressed Air Energy Projects (Name, Location, MW Capacity, Type, Commissioning)
  • Table 7.3: Advanced CAES Market Drivers & Restraints
  • Table 7.4: Project Details for the Poleggio-Loderio Pilot AA-CAES Plant (Name, Location, Companies and Organisations Involved, Capacity kW, Type, Commissioning Date)
  • Table 7.5: The Main Characteristics of Liquid Air Energy Storage (Lifetime, Capacity MW, Efficiency %, Maturity)
  • Table 7.6: Drivers and Restraints of Liquid Air Energy Storage
  • Table 8.1: Hydrogen Main Characteristics (Lifetime, Capacity, Efficiency, Maturity)
  • Table 8.2: Large Scale Hydrogen Energy Storage and Hydrogen Fuel Cell Drivers & Restraints
  • Table 8.3: SMES Performance characteristics (Lifetime, Capacity MW, Efficiency %, Maturity)
  • Table 8.4: Drivers & Restraints of the SMES Market
  • Table 8.5: Main Performance Characteristics of Lithium-Air Batteries (Energy density, Cycle life, Efficiency, Maturity)
  • Table 8.6: Lithium Air Batteries Market Drivers & Restraints
  • Table 8.7: Main Performance Characteristics of Lithium Sulphur Batteries (Energy Density, Cycle life, Efficiency, Maturity)
  • Table 8.8: Lithium Sulphur Batteries Market Drivers and Restraints
  • Table 8.9: Main Performance Characteristics for Magnesium Ion Batteries (Energy Density, Cycle Life, Efficiency, Maturity)
  • Table 8.10: Magnesium Ion Batteries Market Drivers & Restraints
  • Table 8.11: Main Performance Characteristics of Zinc Air Batteries (Energy Density, Cycle Life, Efficiency and Maturity)
  • Table 8.12: Zinc Air Battery Market Drivers & Restraints
  • Table 8.13: Comparison of Key Established and Emerging Energy Storage Technologies (Maturity, Capacity / Density, Efficiency, Lifecycle)
  • Table 8.14: Overview of the Next-Generation ESTs Being Developed in Different Regional and National Markets
  • Table 8.15: North America Next-Generation EST Market Drivers & Restraints
  • Table 8.16: Examples of Emerging Energy Storage RD&D Funding
  • Table 8.17: European Next-Generation EST Market Drivers & Restraints
  • Table 8.18: Asian Next-Generation EST Market Drivers & Restraints
  • Table 9.1: Chinese Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.2: Chinese PHS Market Drivers and Restraints
  • Table 9.3: Existing PHS projects in China (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.4: Installed Capacity Forecast for the Chinese PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.5: Planned PHS Projects in China (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.6: Chinese Grid-Scale Battery Market Drivers & Restraints
  • Table 9.7: Chinese Other EST Market Drivers & Restraints
  • Table 9.8: US Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.9: US PHS Market Drivers and Restraints
  • Table 9.10: Existing PHS projects in the United States (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.11: Installed Capacity Forecast for the US PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.12: Planned PHS Projects in the US (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.13: US Grid-Scale Battery Market Drivers & Restraints
  • Table 9.14: US Other EST Market Drivers & Restraints
  • Table 9.15: Japanese Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.16: Japanese PHS Market Drivers and Restraints
  • Table 9.17: Existing PHS projects in Japan (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.18: Installed Capacity Forecast for the Japanese PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.19: Planned PHS Projects in Japan (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.20: Japanese Grid-Scale Battery Market Drivers & Restraints
  • Table 9.21: Japanese Other EST Market Drivers & Restraints
  • Table 9.22: Italian Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.23: Italian EST Market Drivers and Restraints
  • Table 9.24: Existing PHS projects in Italy (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.25: Installed Capacity Forecast for the Italian PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.26: Planned PHS Projects in Italy (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.27: Italian Grid-Scale Battery Market Drivers & Restraints
  • Table 9.28: Italian Other EST Market Drivers & Restraints
  • Table 9.29: German Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.30: German EST Market Drivers and Restraints
  • Table 9.31: Existing PHS Projects in Germany (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.32: Installed Capacity Forecast for the German Market 2016-2026 (MW, Cumulative)
  • Table 9.33: Planned PHS Projects in Germany (Project Name, MW Capacity, Type, Status , Expected Commissioning)
  • Table 9.34: German Grid-Scale Battery Market Drivers & Restraints
  • Table 9.35: German Other EST Market Drivers & Restraints
  • Table 9.36: South Korean Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.37: South Korean PHS Market Drivers and Restraints
  • Table 9.38: Existing PHS Projects in South Korea (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.39: South Korean Grid-Scale Battery Market Drivers & Restraints
  • Table 9.40: South Korean Other EST Market Drivers & Restraints
  • Table 9.41: UK Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.42: UK PHS Market Drivers and Restraints
  • Table 9.43: Existing PHS Projects in the UK (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.44: Installed Capacity Forecast for the UK PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.45: Planned PHS Projects in the UK (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.46: UK Grid-Scale Battery Market Drivers & Restraints
  • Table 9.47: UK Other EST Market Drivers & Restraints
  • Table 9.48: French Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.49: French EST Market Drivers and Restraints
  • Table 9.50: Existing PHS projects in France (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.51: French Other EST Market Drivers & Restraints
  • Table 9.52: Spanish Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.53: Spanish PHS Market Drivers and Restraints
  • Table 9.54: Existing PHS projects in Spain (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.55: Installed Capacity Forecast for the Spanish Market 2016-2026 (MW, Cumulative)
  • Table 9.56: Planned PHS Projects in Spain (Project Name, Location, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.57: Spanish Other EST Market Drivers & Restraints
  • Table 9.58: Indian Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.59: Indian EST Market Drivers and Restraints
  • Table 9.60: Existing PHS Projects in India (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.61: Installed Capacity Forecast for the Indian Market 2016 - 2026 (MW, Cumulative)
  • Table 9.62: Planned PHS Projects in India (Project Name, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.63: Indian Other EST Market Drivers & Restraints
  • Table 9.64: RoW Energy Storage Market CAPEX 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 9.65: The Rest of the World PHS Market Drivers & Restraints
  • Table 9.66: Existing PHS projects in the Rest of the World (Project Name, Location, MW Capacity, Type, Commissioning Date)
  • Table 9.67: Installed Capacity Forecast for the Rest of the World PHS Market 2016-2026 (MW, Cumulative)
  • Table 9.68: Planned PHS Projects in the Rest of the World (Project Name, Location, MW Capacity, Type, Status, Expected Commissioning)
  • Table 9.69: RoW Other EST Market Drivers & Restraints
  • Table 13.1: Global EST Market Forecast 2016-2026 ($m, AGR %, CAGR%, Cumulative)
  • Table 13.2: Global EST Market Drivers & Restraints
  • Table 13.3: Leading National EST Markets Forecast 2016-2026 ($m, AGR %, Cumulative)
  • Table 13.4: Global EST Submarkets Forecast 2016-2026 ($m, AGR %, Cumulative)

List of Figures

  • Figure 1.1: The Performance Characteristics of Advanced and Conventional CAES (Lifecycle, Efficiency, Maturity, Capacity) on a Metric Standardised for all Emerging Technologies
  • Figure 2.1: Energy Storage Technologies Categorisation
  • Figure 2.2: Electricity Storage Matrix: EST Characteristics and Requirements of Key Applications
  • Figure 2.3: Global EST Market Structure Overview
  • Figure 2.4: Global Energy Storage Capacity by EST type 1996-2015 (GW)
  • Figure 2.5: Global Energy Storage Capacity by EST Type, Excluding PHS, 1996-2015 (GW)
  • Figure 2.6: Key Next-Generation EST Market Structure Overview
  • Figure 2.7: Overview of Types of EST Applications
  • Figure 2.8: Main Types of PHS Installations
  • Figure 2.9: Global Installed PHS Capacity by Installation Type - Open- Loop, Closed-Loop and Innovative (GW)
  • Figure 2.10: Global Grid-Scale Battery Storage Market Structure Overview
  • Figure 2.11: Structure of the CAES Market
  • Figure 2.12: The Fundamentals of Hydrogen Storage and Hydrogen Fuel Cells
  • Figure 2.13: Variants of SMES technology
  • Figure 3.1: Leading National EST Markets Forecast 2016-2026 ($m)
  • Figure 3.2: Leading National EST Markets Share Forecast, 2016 (%)
  • Figure 3.3: Leading National EST Markets Share Forecast, 2021 (%)
  • Figure 3.4: Leading National EST Markets Share Forecast, 2026 (%)
  • Figure 3.5: National EST Spending Forecast 2016-2026 ($m)
  • Figure 3.6: Leading National EST Markets Cumulative Total Spending 2016-2026 ($m)
  • Figure 3.7: Leading National EST Markets Share Change 2016-2026 (%)
  • Figure 3.8: Technology Submarkets Forecast 2016-2026 ($m)
  • Figure 3.9: Leading Technology EST Markets Share Forecast, 2016 (%)
  • Figure 3.10: Leading Technology EST Markets Share Forecast, 2021 (%)
  • Figure 3.11: Leading Technology EST Markets Share Forecast, 2026 (%)
  • Figure 3.12: Technology Submarkets Spending Forecast 2016-2026 ($m)
  • Figure 3.13: Technology Submarkets Cumulative Total Spending 2016-2026 ($m)
  • Figure 3.14: Technology Submarkets Share Change 2016-2026 (%)
  • Figure 3.15: Industrial Electricity Prices in France, Germany, Italy, UK and USA 1979-2014 (Pence/kWh)
  • Figure 3.16: Industrial Electricity Prices for Medium Sized Industries in European Countries 2004-2014 (EUR/kWh)
  • Figure 3.17: Industrial Electricity Prices for Medium Sized Industries in Germany, Spain, France and the United Kingdom 2004-2014 (EUR/kWh)
  • Figure 3.18: Total Public Energy R&D Spending of IEA Members by Sector, 2015 (%)
  • Figure 3.19: Evolution of Total Public Energy RD&D Spending by Selected IEA members 1985-2013 ($m)
  • Figure 3.20: The Scale and Composition of Installed Renewables Capacity in Selected Countries and Regions (TWh)
  • Figure 3.21: Global Electricity Production by Source 1971-2013 (TWh)
  • Figure 3.22: Electricity Generated from Renewable Sources, EU 28, 2003-2013 (TWh, % of Consumption)
  • Figure 3.23: Global EV and PHEV Growth Forecast 2010-2030 (Unit Sales)
  • Figure 3.24: Number of FCEVs expected to operate in the US, South Korea, Japan and Europe, 2020
  • Figure 3.25: Technology and Innovation Adoption Lifecycle
  • Figure 4.1: Global PHS Market Forecast 2016-2026 ($m, AGR %)
  • Figure 4.2: Global PHS Installed Capacity Forecast 2016-2026 (GW)
  • Figure 4.3: Share of the PHS Market in Global EST CAPEX 2016-2026 (%)
  • Figure 4.4: Main Types of PHS Installations
  • Figure 4.5: Evolution of Installed Capacity in the Open-Loop, Closed-Loop and Innovative PHS Submarkets (1926 - 2015 , MW)
  • Figure 4.6: Existing Global PHS Capacity by Submarket (number projects, GW)
  • Figure 4.7: Existing Global PHS Capacity by Submarket in the 15 Leading National Markets (MW)
  • Figure 4.8: PHS Submarket Forecasts 2016-2026 ($m, AGR %)
  • Figure 4.9: PHS Submarket CAPEX Share Forecast 2016 (%)
  • Figure 4.10: PHS Submarket CAPEX Share Forecast 2021 (%)
  • Figure 4.11: PHS Submarket CAPEX Share Forecast 2026 (%)
  • Figure 4.12: PHS Market Share Change 2016-2026 (%)
  • Figure 4.13: The Evolution of CAPEX in the Main PHS Submarkets 2016-2026 ($m)
  • Figure 4.14: Evolution of Installed Capacity in the Open Loop Submarket 1926 - 2015 (MW)
  • Figure 4.15: Open Loop PHS Submarket CAPEX Forecast 2016-2026 ($m)
  • Figure 4.16: Share of the Open-Loop PHS Submarket in Total CAPEX 2016-2026 (%)
  • Figure 4.17: CAPEX on Open-Loop PHS by National Market 2016-2026 ($m)
  • Figure 4.18: Total CAPEX on Open-Loop PHS by National Market (Cumulative 2016-2026 $m)
  • Figure 4.19: Open-loop PHS Installed Capacity Forecast 2016-2026 (GW)
  • Figure 4.20: Evolution of Installed Capacity in the Closed-Loop Submarket 1963 - 2015 (MW)
  • Figure 4.21: Closed-Loop PHS Submarket CAPEX Forecast 2016-2026 ($m)
  • Figure 4.22: Share of the Closed-Loop PHS Submarket in Total CAPEX 2016-2026 (%)
  • Figure 4.23: CAPEX on Closed-Loop PHS by National Market 2016-2026 ($m)
  • Figure 4.24: Cumulative CAPEX on Closed-Loop PHS by National Market 2016-2026 ($m)
  • Figure 4.25: Closed-Loop PHS Installed Capacity Forecast 2016-2026 (MW)
  • Figure 4.26: Main Types of Innovative PHS installations
  • Figure 4.27: Evolution of Installed Capacity in the Innovative PHS Submarket 1966 - 2015 (MW)
  • Figure 4.28: Innovative PHS Submarket Forecast 2016-2026 ($m, AGR %)
  • Figure 4.29: Share of the Innovative PHS Submarket in total CAPEX 2016-2026 (%)
  • Figure 4.30: CAPEX on Innovative PHS by National Market 2016-2026 ($m)
  • Figure 4.31: Total CAPEX on Innovative PHS by National Market (Cumulative 2016-2026 $m)
  • Figure 4.32: Innovative PHS Installed Capacity Forecast 2016-2026 (MW)
  • Figure 4.33: Main Patterns of Innovation in the Global PHS Sector
  • Figure 4.34: The Commissioning Date of the Earliest Still-Operating PHS Installation by National Market
  • Figure 4.35: The Commissioning Date of the First Still-Operational PHS Installation by Submarket
  • Figure 4.36: Size of Average Operational PHS Installation in Leading National Markets (MW)
  • Figure 4.37: Average Construction Period for PHS Installations in Leading National Markets (Years)
  • Figure 4.38: Average Size of PHS Installations Planned for the Period 2016-2026 in Leading National Markets (MW)
  • Figure 4.39: Average Size of Existing and Planned PHS Installations in Leading National Markets (MW)
  • Figure 4.40: Average Expected Construction Time of PHS Installations Planned for the Period 2016-2026 in Leading National Markets (Years)
  • Figure 4.41: Average Construction Time of Existing and Planned PHS Installations in Leading National Markets (Years)
  • Figure 4.42: Average Construction Cost of PHS Installations Planned for the Period 2016-2026 in Leading National Markets ($m)
  • Figure 4.43: Average Capacity of Existing PHS Installations by Submarket (MW)
  • Figure 4.44: Average Construction Period for Existing PHS Installations by Submarket (Years)
  • Figure 4.45: Average Capacity of PHS Installations Planned for the Period 2016-2026 by Submarket (MW)
  • Figure 4.46: Average Capacity of Existing and Planned PHS Installations by Submarket (MW)
  • Figure 4.47: Average Expected Construction Time of PHS Installations Planned for the Period 2016-2026 by Submarket (Years)
  • Figure 4.48: Average Construction Time of Existing and Planned PHS Installations (Submarkets, Years)
  • Figure 4.49: Average Expected Construction Cost of PHS Installations Planned for the Period 2016-2026 ($m/project)
  • Figure 4.50: Overview of the 20 Largest PHS Installations in the World (MW)
  • Figure 5.1: Global Grid-Scale Battery Storage Market Forecast 2016-2026 ($m, AGR %)
  • Figure 5.2: Share of the Grid-Scale Battery Storage Market in Global EST CAPEX 2016-2026 (%)
  • Figure 5.3: Grid-Scale Battery Storage Submarket Forecasts 2016-2026 ($m)
  • Figure 5.4: Grid-Scale Battery Storage Submarkets Share Forecast 2016 (%)
  • Figure 5.5: Grid-Scale Battery Storage Submarkets Share Forecast 2021 (%)
  • Figure 5.6: Grid-Scale Battery Storage Submarkets Share Forecast 2026 (%)
  • Figure 5.7: Grid-Scale Battery Storage Submarkets Aggregated CAPEX 2016-2026 ($m)
  • Figure 5.8: Lithium-Ion Battery Storage Submarket Forecast 2016-2026 ($m, AGR %)
  • Figure 5.9: Share of the Lithium-Ion Battery Storage Submarket in Total CAPEX 2016, 2021 and 2026 (%)
  • Figure 5.10: Sodium-Based Battery Storage Market Forecast by National Market 2016-2026 ($m, AGR %)
  • Figure 5.11: Share of the Sodium-Based Battery Storage Submarket in Global EST Market 2016, 2021 and 2026 (% Share)
  • Figure 5.12: Flow Battery Storage Market Forecast by National Market 2016-2026 ($m, AGR %)
  • Figure 5.13: Share of the Flow Battery Storage Submarket in Total CAPEX 2016, 2021 and 2026 (% Share)
  • Figure 5.14: Advanced Lead Acid Battery Storage Market Forecast by National Market 2016-2026 ($m, AGR %)
  • Figure 5.15: Share of the Advanced Lead Acid Battery Storage Submarket in Total CAPEX 2016, 2021 and 2026 (% Share)
  • Figure 5.16: Other Battery Storage Technologies Market Forecast by National Market 2016-2026 ($m, AGR %)
  • Figure 5.17: Share of the Other Battery Storage Submarket in Total CAPEX 2016, 2021 and 2026 (% Share)
  • Figure 6.1: Global Thermal Energy Storage Market Forecast 2016-2026 ($m, AGR %)
  • Figure 6.2: Share of the Thermal Energy Storage Market in Global EST CAPEX 2016-2026 (%)
  • Figure 6.3: Thermal Energy Storage Technologies
  • Figure 6.4: Share of the Main Energy Storage Technologies in Thermal Capacity as of December 2014 (%)
  • Figure 6.5: The Potential Applications of Thermal Energy Storage in the Power System
  • Figure 6.6: Global CAES Market Forecast 2016-2026 ($m, AGR %)
  • Figure 6.7: Share of the CAES Market in Global EST CAPEX 2016-2026 (%)
  • Figure 6.8: Structure of the CAES market
  • Figure 6.9: Installed CAES Capacity by Category: Diabatic and Isothermal (MW, % of total)
  • Figure 6.10: Global Supercapacitors Market Forecast 2016-2026 ($m, AGR %)
  • Figure 6.11: Share of the Supercapacitors Market in Global EST CAPEX 2016-2026 (%)
  • Figure 6.12: Global Flywheels Market Forecast 2016-2026 ($m, AGR %)
  • Figure 6.13: Share of the Flywheels Market in Global EST CAPEX 2016-2026 (%)
  • Figure 6.14: Flywheels: Regional Breakdown of Existing Installed Capacity (MW)
  • Figure 7.1: Structure of the CAES Market
  • Figure 7.2: Round-Trip Efficiency of Conventional Diabatic CAES and Advanced CAES (%)
  • Figure 7.3: The Performance Characteristics of Advanced and Conventional CAES (Lifecycle, Efficiency, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 7.4: Main Applications of Advanced Compressed Air Energy Storage
  • Figure 7.5: Main Competitors of Advanced Compressed Air Energy Storage
  • Figure 7.6: Key Market Spaces for Advanced CAES
  • Figure 7.7: Installed CAES Capacity by Category: Diabatic and Isothermal (MW, % of total)
  • Figure 7.8: Anticipated progress of AA-CAES through the pilot stage onto commercialisation (2014-2020)
  • Figure 7.9: Selection of Stakeholders and Companies Involved in the Advanced Compressed Air Energy Storage Market
  • Figure 7.10: The Stages Involved in Liquid Air Energy Storage
  • Figure 7.11: Round-Trip Efficiency of Liquid Air Energy Storage Technology Variants (%)
  • Figure 7.12: The Performance Characteristics of Liquid Air Energy Storage on a Metric Standardised for all Emerging Technologies (Lifecycle, Efficiency, Capacity, Maturity)
  • Figure 7.13: Main Applications of Liquid Air Energy Storage
  • Figure 7.14: Main Competitors of Liquid Air Energy Storage
  • Figure 7.15: Key Market Spaces for Liquid Air Energy Storage
  • Figure 7.16: The Historic and Expected Development of Liquid Air Energy Storage 2005-2018
  • Figure 7.17: Selection of Stakeholders and Companies Involved in the Liquid Air Energy Storage Market
  • Figure 8.1: The Fundamentals of Hydrogen Storage and Hydrogen Fuel Cells
  • Figure 8.2: The Round-Trip Efficiency of Hydrogen Storage by Pathway Variant (%)
  • Figure 8.3: The Performance Characteristics of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells on a Metric Standardised for all Emerging Technologies (Lifecycle, Efficiency, Capacity, Maturity)
  • Figure 8.4: Main Applications of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
  • Figure 8.5: Main Competitors of Large-Scale Hydrogen Storage Systems
  • Figure 8.6: Main Competitors of Hydrogen Fuel Cells
  • Figure 8.7: Key Market Spaces for Hydrogen Storage and Hydrogen Fuel Cells
  • Figure 8.8: FCEV Fleet in Operation in Leading National and Regional Markets as of 2014
  • Figure 8.9: Hydrogen Fuelling Stations in Operation in Leading National and Regional Markets as of 2014
  • Figure 8.10: The Main Types of Hydrogen Storage
  • Figure 8.11: Existing and Planned Hydrogen Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 8.12: Existing and Planned Hydrogen Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 8.13: Existing and Planned Alternative Fuelling Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 8.14: Selection of Stakeholders and Companies Involved in the Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells Market
  • Figure 8.15: Variants of SMES technology
  • Figure 8.16: The Performance Characteristics of Superconducting Magnetic Energy Storage on a Metric Standardised for all Emerging Technologies (Lifecycle, Efficiency, Capacity, Maturity)
  • Figure 8.17: Main Applications for Superconducting Magnetic Energy Storage
  • Figure 8.18: Main Competitors of Superconducting Magnetic Energy Storage
  • Figure 8.19: Key Market Spaces for Superconducting Magnetic Energy Storage
  • Figure 8.20: Selection of Stakeholders and Companies Involved in the Superconducting Magnetic Energy Storage Market
  • Figure 8.21: Key Emerging Battery Chemistries
  • Figure 8.22: Li-air Categorisation by Electrolyte
  • Figure 8.23: The Performance Characteristics of Lithium Air Batteries on a Metric Standardised for all Emerging Technologies (Lifecycle, Efficiency, Capacity, Maturity)
  • Figure 8.24: The Performance Characteristics of Lithium Sulphur Batteries on a Metric Standardised for all Emerging Technologies (Lifecycle-Years, Efficiency %, Capacity, Maturity)
  • Figure 8.25: Main Applications of Lithium Sulphur Batteries
  • Figure 8.26: Key Market Spaces for Lithium Sulphur Batteries
  • Figure 8.27: Selection of Stakeholders and Companies Involved in the Lithium Sulphur Battery Market
  • Figure 8.28: Selection of Stakeholders and Companies Involved in the Magnesium-Ion Battery Market
  • Figure 8.29: The Performance Characteristics of Zinc Air on a Metric Standardised for all Emerging Technologies (Lifecycle-Years, Efficiency, Capacity, Maturity)
  • Figure 8.30: Main Applications of Zinc Air Batteries
  • Figure 8.31: Selection of Stakeholders and Companies Involved in the Zinc-Air Battery Market
  • Figure 8.32: EST Characteristics and Requirements of Key Applications
  • Figure 8.33: Cost and Backup Time Comparison of Energy Storage Technologies except Pumped Storage (Euro/kWh, hours)
  • Figure 8.34: Comparison of the Round-Trip Efficiency of Key Established and Emerging Energy Storage Technologies (%)
  • Figure 8.35: The Development Stage and Challenges of Established and Emerging Energy Storage Technologies
  • Figure 8.36: Key Markets Involved in the Development of Next-Generation Energy Storage Technologies
  • Figure 8.37: Overview of the Key Next-Generation ESTs Under Development in North America
  • Figure 8.38: Overview of the Key Next-Generation ESTs Under Development in Europe
  • Figure 8.39: Overview of the Key Next-Generation ESTs Under Development in Asia
  • Figure 9.1: Chinese Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.2: Share of the Chinese EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.3: Key Factors Affecting the Chinese PHS Market
  • Figure 9.4: Evolution of Installed PHS Capacity in China 1968-2015 (MW)
  • Figure 9.5: The Share of Different Submarkets in the Chinese PHS market 2015 (MW)
  • Figure 9.6: Installed Capacity Forecast for the Chinese PHS Market 2016-2026 (MW)
  • Figure 9.7: New Wind Power Capacity Additions by Country, 2015 (%)
  • Figure 9.8: US Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.9: Share of the US EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.10: Key Factors Affecting the US PHS Market
  • Figure 9.11: Evolution of Installed PHS Capacity in the United States 1929-2015 (MW)
  • Figure 9.12: The Share of Different Submarkets in the US PHS Market 2015 (MW)
  • Figure 9.13: Installed Capacity Forecast for the US PHS Market 2016-2026 (MW)
  • Figure 9.14: Proposed Energy Storage Procurement Targets in Major Californian Utilities 2014, 2016, 2018, 2020 (MW)
  • Figure 9.15: Japanese Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.16: Share of the Japanese EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.17: Key Factors Affecting the Japanese PHS Market
  • Figure 9.18: Evolution of Installed PHS Capacity in Japan 1961-2015 (MW)
  • Figure 9.19: The Share of Different Submarkets in the Japanese PHS Market 2015 (MW)
  • Figure 9.20: Installed Capacity Forecast for the Japanese PHS Market 2016-2026 (MW)
  • Figure 9.21: Italian Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.22: Share of the Italian EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.23: Key Factors Affecting the Italian PHS Market
  • Figure 9.24: Evolution of Installed PHS Capacity in Italy 1905-2015 (MW)
  • Figure 9.25: The Share of Different Submarkets in the Italian PHS market 2015 (MW)
  • Figure 9.26: Installed Capacity Forecast for the Italian PHS Market 2016-2026 (MW)
  • Figure 9.27: Italian Renewables Production as a Share of Italian Electricity Consumption, 2010 and 2015 (% Share)
  • Figure 9.28: Italian Installed Hydropower, Wind, Solar, Geothermal and Biofuels Capacity, 2010-2015 (MW)
  • Figure 9.29: German Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.30: Share of the German EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.31: Evolution of Electricity Prices for Medium-Size Households in Germany and EU 28 (EUR/kWh)
  • Figure 9.32: Evolution of Electricity Prices for Medium-Size Industries in Germany and EU 28 (EUR/kWh)
  • Figure 9.33: Evolution of Installed PHS Capacity in Germany 1926 - 2015 (MW)
  • Figure 9.34: The Share of Different Submarkets in the German PHS Market 2015 (MW)
  • Figure 9.35: Installed Capacity Forecast for the German Market 2016-2026 (MW)
  • Figure 9.36: Renewable Capacity in Germany, 2010-2015 (MW)
  • Figure 9.37: South Korean Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.38: Share of the South Korean EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.39: Key Factors Affecting the South Korean PHS Market
  • Figure 9.40: Evolution of Installed PHS Capacity in South Korea 1979-2015 (MW)
  • Figure 9.41: The Share of Different Submarkets in the German PHS Market 2015 (MW)
  • Figure 9.42: UK Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.43: Share of the UK EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.44: Key Factors Affecting the UK PHS Market
  • Figure 9.45: Evolution of Installed PHS Capacity in the United Kingdom 1963-2015 (MW)
  • Figure 9.46: The Share of Different Submarkets in the UK PHS Market 2015 (MW)
  • Figure 9.47: Installed Capacity Forecast for the UK PHS Market 2016-2026 (MW)
  • Figure 9.48: French Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.49: Share of the French EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.50: Key Factors Affecting the French PHS Market
  • Figure 9.51: Evolution of Installed PHS Capacity in France 1950-2015 (MW)
  • Figure 9.52: The Share of Different Submarkets in the French PHS Market 2015 (MW)
  • Figure 9.53: Spanish Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.54: Share of the Spanish EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.55: Key Factors Affecting the Spanish PHS Market
  • Figure 9.56: Evolution of Installed PHS Capacity in Spain 1929-2015 (MW)
  • Figure 9.57: The Share of Different Submarkets in the Spanish PHS Market 2015 (MW)
  • Figure 9.58: Installed Capacity Forecast for the Spanish Market 2016-2026 (MW)
  • Figure 9.59: Indian Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.60: Share of the Indian EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.61: Evolution of Installed PHS Capacity in India 1926-2015 (MW)
  • Figure 9.62: The Share of Different Submarkets in the Indian PHS Market 2015 (MW)
  • Figure 9.63: Installed Capacity Forecast for the Indian Market 2016-2026 (MW)
  • Figure 9.64: RoW Energy Storage Market CAPEX 2016-2026 ($m, AGR %)
  • Figure 9.65: Share of the RoW EST Market in Global EST CAPEX 2016-2026 (%)
  • Figure 9.66: Key Factors Affecting the RoW PHS Market
  • Figure 9.67: Evolution of Installed PHS Capacity in the Rest of the World 1929-2015 (MW)
  • Figure 9.68: The Rest of the World National Breakdown of Existing Capacity 2015 (MW)
  • Figure 9.69: The Share of Different Submarkets in the Rest of the World PHS market 2015 (MW)
  • Figure 9.70: Installed Capacity Forecast for the Rest of the World PHS Market 2016-2026 (MW)

Companies Listed

  • A123 Energy Solutions
  • A123 Systems
  • Abatel
  • ABB Energy Storage
  • ABB Group
  • ABS Machining
  • Absaroka Energy
  • Active Power
  • AES Corporation
  • AES Energy Storage
  • Air Liquide
  • Air Products
  • Airbus Defense and Space
  • Airlight Energy/ ALACAES
  • ALACAES
  • Alpine Machine Co Inc
  • Alpiq
  • Alstom
  • Alstom Grid
  • Altair Nanotechnologies (Altairnano)
  • Amber Kinetics
  • American Electric Power (AEP)
  • American Vanadium
  • Andritz
  • Andritz Hydro
  • Angel Holdings
  • Applied Power
  • Aquion Energy
  • Arizona Public Service Company
  • Asahi Kasei
  • Ataur Nanotechnologies Inc. (Altairnano)
  • ATB Riva Calzoni
  • Austin Energy
  • Axeon
  • Axion Power International
  • Axpo
  • Ballard Power Systems
  • Bard
  • Basler Electric
  • Beacon Power
  • Beta R&D
  • Black & Veatch
  • Bloomberg New Energy Finance (BNEF)
  • BMW
  • Bosch
  • Boston Power Inc.
  • BrightSource Energy
  • Bruker
  • BYD Co Ltd.
  • C&D Technologies Inc.
  • Calisolar
  • Canadian Hydro Components Ltd
  • Canyon Hydro]
  • Cellstrom
  • CEZ Group
  • China Hydropower Engineering Consulting Group Corporation
  • China National Electric Equipment Corporation (CNEEC)
  • China Southern Power Grid (CSG)
  • China Water Conservancy Corporation
  • Chubu Electric
  • Coca-Cola
  • Con Edison
  • CSG Power Generation Company
  • Daewoo
  • Damwatch Engineering Ltd
  • DayStar Technologies
  • Deeya Energy
  • DEIF UK Ltd
  • DLR
  • DNV KEMA
  • Dongfang Electric
  • Douce Hydro SAS
  • Dow Chemical Company
  • Dow Kokam
  • Dresser Industries
  • Dresser-Rand Group
  • Duke Energy
  • E.On
  • Eagle Crest Energy
  • East Penn Manufacturing
  • Ecoult
  • EDF Energy
  • EDP: energia de Portugal
  • EDPR
  • Electrabel
  • Electric Power Development Co.,
  • Electricite de France
  • ÉlectricitÉ RÉseau Distribution France (ERDF)
  • Electrovaya
  • Ellergreen Hydro
  • Emerson Network Power Australia
  • Endesa
  • ENEL
  • Ener1
  • Enercon
  • Energias de Portugal
  • Energy Safe Victoria
  • Energy Storage & Power (ESP)
  • EnerSys
  • EnerVault
  • EnZinc
  • Eos Energy Storage
  • Epsilon Battery
  • Excell Battery
  • Exide Technologies
  • FIAMM
  • Firefly International Energy
  • First energy Corp
  • First Hydro Company
  • First Wind
  • Flextronics
  • Fluidic Energy
  • Forbes
  • Foundation Asset Management (FAM)
  • Fujikura
  • Furukawa Battery
  • Furukawa Electric
  • Gaia Akkumulatorenwerke
  • Gartner
  • GE Energy Storage
  • GE Power Systems
  • General Compression
  • General Electric
  • General Electric (GE)
  • General Motors
  • Gildemeister
  • Gildemeister Energy Solutions
  • Gilkes
  • Global Hydro Energy GmbH
  • GO Development
  • Google Inc.
  • GP Batteries
  • Green Charge Networks (GCN)
  • Grid Logic
  • GRIDFLEX
  • Gridflex Energy LLC Principals
  • Groupe Industriel Marcel Dassault
  • GruppoIren
  • GS Yuasa International
  • GS Yuasa Power Fielding
  • GSR Ventures
  • Harting Inc.
  • Hatch Associates Consultants Inc
  • Hellan Strainer Co
  • Highview Power Storage
  • Hitachi
  • Hitachi Battery Systems Company
  • Hokkaido Electric
  • Honda
  • Hudson Clean Energy Partners
  • Hydro Component Systems LLC
  • Hydro Consulting &Maintenance Services Inc
  • Hydro Expertise USA
  • Hydro Tech Inc
  • HydroChina Zhongnan Engineering Corp.
  • Hydrogenics
  • HydroPower Consult
  • IAI Hydro Inc
  • IBM
  • Illwerge AG
  • Imergy
  • INDAR
  • Ingersoll Rand
  • INSET Ltd
  • INVEN Capital
  • Isentropic Ltd.
  • ITM Power
  • JHP & Associates Inc
  • Johnson Controls Inc.
  • Johnson Matthey Group
  • J-Power
  • KC Hydro &Sackheim Consulting
  • KELAG
  • Keuka Energy
  • Kiser Hydro LLC
  • Kleinschmidt Associates
  • Korea Electric Power Corporation (KEPCO)
  • Kossler GmbH & Co KG
  • KT
  • Kuick Research
  • LG
  • LG Chem
  • LightSail Energy
  • Linde
  • Lithium Technology Corp. (LTC)
  • Litostroj Hydro Inc
  • M+W Group
  • Magnum Energy Storage
  • Max Hydro Power Equipment Ltd
  • Maxim Hydro International Services Inc
  • Maxwell Technologies
  • Mecan-Hydro
  • Mercedes-Benz
  • Mitsubishi Heavy Industries (MHI)
  • Mitsubishi Materials
  • MWH Global
  • National Grid
  • Nedap
  • Nesscap Energy
  • Nexeon
  • NGK Insulators
  • NHA: national hydropower association
  • Nichicon Corporation
  • Nippon Chemi-Con Corporation
  • Nissan
  • Norsk Hydro
  • Northland power
  • NRG Energy
  • Oak Investment Partners
  • Oiles Deutshcland GmbH
  • OKAE
  • Oncor
  • Ossberger Hydro Inc
  • Oxis Energy
  • Pacific Gas and Electric
  • Palladium Energy
  • Panasonic Corporation
  • Peak Hour Power LLC
  • Pellion Technologies
  • PG&E
  • Phillips Service Industries
  • Phinergy
  • Piedmont Hydro Technologies LLC
  • PJM
  • Plug Power
  • Power China
  • Power Grid Corporation of India
  • PowerMachines
  • Powerthru
  • Primus Power Corp.
  • Prineville nergy Storage LLC
  • Proinso
  • Proterra
  • Proton Motor
  • Prudent Energy Technology
  • PT Indonesia Hydro Consult
  • PXL Seals
  • Ray Power
  • Raytheon
  • Red Flow Ltd.
  • Regenesys
  • Rennasonic Inc
  • Repower
  • Repros GmbH
  • RES America
  • Research Institute for Energy Facilities
  • Restore Energy Systems
  • ReVolt Technology
  • Rockland Capital
  • Rusano
  • RusHydro
  • RWE Power
  • S&C Electric
  • Saft
  • Saint-Gobain
  • Samsung Corporation
  • Samsung SDI
  • Sanyo Electric
  • Schluchseewerk
  • Schmiedewerke Groditz GmbH
  • Seeo Inc.
  • Shimizu Corporation
  • Shimizu Institute of Technology
  • Siemens
  • Siemens Dailmer
  • Sinohydro (China Water Conservancy and Hydropower Construction Corporation)
  • Sion Power
  • SK Telecom
  • SolarCity
  • Solyndra
  • Sony
  • Sony Corporation
  • South Plains Electric Cooperative (SPEC)
  • Southern California Edison
  • SSE
  • Stadtwerke Mainz
  • State Grid Corporation of China (SGCC)
  • Statkraft
  • Stellba Hydro GmbH & Co KG
  • Stucky ltd
  • Sumitomo Corporation
  • Sumitomo Electric
  • Sun Edison
  • Superconductor Technologies
  • SuperPower
  • SustainX Inc.
  • TERNA
  • Terna Plus
  • Tesla
  • Tesla Energy
  • Tesla Motors
  • Texas Center for Superconductivity
  • The Brattle Group
  • Thüga
  • Tianjin Tianfa Heavy machinery & Hydro Power Equipment Manufacture Co Ltd
  • TK Advanced Battery
  • Tohoku Electric
  • Tokyo Electric Power Company (TEPCO)
  • Toshiba
  • Toyota
  • Trianel GmbH
  • Ultralife Corporation
  • US Hydro Inc
  • UTC Power
  • Valence Technology Inc.
  • Vattenfall
  • Verbund
  • Viridor
  • ViZn Energy
  • Voith Hydro
  • Volkswagen
  • Voralberger Illwerke
  • VRB Power Systems
  • Vycon Inc.
  • Wal-Mart
  • Wanxiang Group
  • Weir American Hydro
  • Wemag
  • Wenckus Engineering
  • Williams Hybrid Power
  • WZE
  • Xcel Energy
  • Xtreme Power Inc.
  • Yokohama Dockyard & Machinery Works
  • Younicos
  • ZAF Energy Systems
  • ZBB Energy Corporation
  • Zollern
  • Züblin

Other Organisations Mentioned in This Report

  • Advanced Lead Acid Battery Consortium (ALABC)
  • Advanced Research Projects Agency - Energy (ARPA-E)
  • American Energy Storage Association
  • Australian Labor Party
  • Australian Renewable Energy Agency (ARENA)
  • Brazilian Wind Energy Association
  • Brookhaven National Laboratory
  • California Energy Commission
  • California Public Utilities Commission (CPUC)
  • Cambridge University
  • Central Electricity Agency (CEA)
  • Centre for Renewable Energy Development (CRED)
  • Centre for the Commercialization of Electric Technologies (CCET)
  • China Electrical Power Research Initiative (CEPRI)
  • China Southern Power Grid
  • Commonwealth Scientific and Industrial Research Organisation (CSIRO)
  • Communist Party of China
  • Department of Energy (DOE)
  • Department of Energy and Climate Change (DECC)
  • Electric Power Research Institute (EPRI)
  • Electric Reliability Council of Texas (ERCOT grid)
  • Electric Vehicles Initiative (EVI)
  • Electricity Storage Association
  • Energy Technology Institute (ETI)
  • Engineering News
  • European Commission
  • European Commission Joint Research Centre
  • European Institute for Energy Research (EIFER)
  • European Parliament
  • European Photovoltaic Industry Association (EPIA)
  • European Union (EU)
  • Federal Association of Energy Storage (BVES)
  • Fraunhofer Center for Energy Storage
  • Fraunhofer Institute
  • Fraunhofer Society
  • French Environment and Energy Management Agency (ADEME)
  • French Europe Ecology-The Greens
  • German Christian Democratic Union (CDU)
  • German Christian Social Union (CSU)
  • German Federal Association of Energy and Water Industries (BDEW)
  • German Liberal Democratic Party (FDP)
  • German National Research Center for Aeronautics
  • Germany Federal Association of Energy and Water Industries (BDEW)
  • Germany Federal Association of Energy Storage (BVES)
  • Global Wind Energy Council (GWEC)
  • Harvard Business School
  • Hessian Ministry for the Environment, Energy, Agriculture and Consumer Protection
  • High Energy Research Organisation
  • Imperial College London
  • Indian Ministry of New and Renewable Energy
  • International Atomic Energy Agency (IAEA)
  • International Energy Agency (IEA)
  • Italian Ministry of Economy and Finances
  • Japanese Ministry of Economy, Trade and Industry (METI)
  • Kodiak Electric Association (KEA)
  • Korea Institute of Energy Research (KIER)
  • Kuick Research
  • Kyoto University
  • Lawrence Berkeley National Lab
  • Los Angeles Department of Water and Power (LADWP)
  • Massachusetts Institute of Technology (MIT)
  • Ministry of Economy, Trade and Industry (METI)
  • National Aeronautics and Space Administration (NASA)
  • National Energy Administration (NEA)
  • National Hydropower Association (NHA)
  • New York Battery and Energy Storage Technology Consortium (NY-BEST)
  • New York State Energy Research and Development Authority (NYSERDA)
  • Okinawa Institute of Science and Technology (OIST)
  • Ontario Ministry of Energy
  • Organisation for Economic Co-operation and Development (OECD)
  • Paris Stock Exchange (PAR)
  • Public Utilities Commission of Ohio (PUCO)
  • Regenesys
  • Renewable Energy Policy Network for the 21st Century (REN21)
  • Rutgers, The State University of New Jersey
  • Sandia National Laboratories
  • Seattle University
  • Shanghai Stock Exchange (SHH)
  • South Korean Ministry of Knowledge Economy
  • Southern California Edison
  • Spanish People's Party
  • Swiss Federal Office of Energy (SFOE)
  • Texas Centre for Superconductivity
  • Texas Public Utilities Commission
  • Tokyo Stock Exchange (TYO)
  • Toronto Stock Exchange (TSX)
  • Toyota Research Institute of North America (TRINA)
  • UK Conservative Party
  • UK Department of Energy and Climate Change (DECC)
  • UK Liberal Democratic Party
  • UK National Grid
  • UK Office of Gas and Electricity Markets (Ofgem)
  • UK Technology Strategy Board (TSB)
  • United Nations Framework Convention on Climate Change (UNFCCC)
  • Universität Magdeburg
  • University of St. Andrews
  • US Democratic Party
  • US Energy Information Administration (EIA)
  • US Federal Energy Regulatory Commission (FERC)
  • US Republican Party
  • Vehicle Technologies Office (VTO)
  • World Economic Forum
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