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市場調查報告書

下一代儲能技術 (EST) 市場展望 2016年

Next Generation Energy Storage Technologies (EST) Market Prospects 2016

出版商 Visiongain Ltd 商品編碼 357185
出版日期 內容資訊 英文 209 Pages
商品交期: 最快1-2個工作天內
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下一代儲能技術 (EST) 市場展望 2016年 Next Generation Energy Storage Technologies (EST) Market Prospects 2016
出版日期: 2016年04月18日 內容資訊: 英文 209 Pages
簡介

本報告提供下一代儲能技術 (EST) 市場相關調查,新興EST市場促進要素、抑制因素分析,各技術的性能、優點與缺點、展望的詳細分析,現有技術和新興技術比較分析,各地區的市場分析,及今後的市場展望等。

第1章 摘要整理

第2章 確立的、新興儲能技術的簡介

  • 儲能技術的分類
  • 已設置儲能容量
  • 新興儲能技術的崛起
  • 確立的、新興儲能技術的主要應用

第3章 下一代儲能技術的促進要素、抑制因素

  • 市場動態的簡介
  • 促進、抑制市場的要素

第4章 下一代機械儲能技術

  • 創新的抽蓄水力發電儲存
  • 隔熱、等溫壓縮空氣能源儲存
  • 液體空氣儲能 (LAES)

第5章 下一代化學儲能技術

  • 大型氫燃料儲能系統、氫燃料電池

第6章 下一代電能儲存技術

  • 超導性磁儲能 (SMES)

第7章 下一代電化學儲能技術

  • 下一代電池技術的簡介
  • 市場上創新的主要成長因素
  • 市場上創新的主要模式
  • 鋰-空氣 (Li-Air)
  • 鋰-硫磺 (Li-S)
  • 鎂-離子 (Mg-Ion)
  • 鋅-空氣 (An-Air)
  • 彙整

第8章 專家的見解

第9章 下一代電能儲存市場PEST分析

第10章 確立的、新興儲能技術:比較分析

第11章 全球新興儲能技術市場情勢

  • 北美下一代儲能技術
  • 歐洲的下一代儲能技術
  • 亞洲的下一代儲能技術

第12章 結論、建議

  • 新興儲能技術市場促進要素、抑制因素
  • 創新的抽蓄水力發電儲存的展望
  • 先進壓縮空氣能源儲存的展望
  • 液體空氣儲能的展望
  • 大型氫存儲系統、氫燃料電池的展望
  • 超導磁儲能系統的展望
  • 下一代電池的展望

第13章 詞彙表

目錄
Product Code: ENE0057

Sub Title: Analysis of Technology Maturity, Performance & Commercialisation of Mechanical (Innovative PHS, AA-CAES, Isothermal CAES & LAES), Chemical (Hydrogen Storage & Fuel Cells), Electrical (SMES) & Electrochemical (Lithium-Air, Lithium-Sulphur, Magnesium-Ion & Zinc-Air Batteries).

Visiongain has established that three of the ten most promising emerging energy storage technologies will reach full commercialisation by 2020. In addition to analysing the drivers and restraints of the emerging EST market, the report provides a detailed analysis of performance, advantages and disadvantages and outlook for every technology considered: Innovative PHS, adiabatic compressed air energy storage, liquid air energy storage, large-scale hydrogen storage systems and hydrogen fuel cells, superconducting magnetic energy storage, lithium-air batteries, lithium-sulphur batteries, magnesium-ion batteries and zinc-air batteries. In addition to a detailed study of each key emerging EST, the report also offers insight into how the performance and outlook of emerging technologies compares to the main commercially mature technologies and what the conditions for the development of emerging technologies are like in the key regional market spaces.

The report is essential reading for stakeholders or anyone interested in the changing dynamics of power networks and the energy storage market. Do not miss an opportunity to get a one-stop review of all emerging EST technologies. Purchasing this report today will help you to recognise important market opportunities and understand the possibilities there.

The report will answer questions such as:

  • How is the EST market evolving?
  • What are the key next-generation energy storage technologies?
  • What are the main applications of energy storage technologies? How do the next generation ESTs fit into the market?
  • At what stage of development are the key next-generation technologies? Are there any planned, existing or successful demonstration and pilot projects?
  • What key challenges do next-generation energy storage technologies have to overcome to become fully commercially viable? Is their development and commercialisation dependant on cost reductions or technological breakthroughs?
  • What is the outlook for key emerging energy storage technologies?
  • How do the performance characteristics of next-generation ESTs differ from those of established technologies?
  • Which companies, organisations and actors are involved with next-generation energy storage technologies?
  • What is driving and restraining the development and commercialisation of next-generation energy storage technologies?
  • Which market spaces are the most active in the development of next-generation energy storage technologies? How do the conditions for the development and deployment of energy storage technologies differ in key regional markets?

How will you benefit from this report?

  • This report you will keep your knowledge base up to speed. Don't get left behind.
  • This report will allow you to reinforce strategic decision-making based upon definitive and reliable market data.
  • You will learn how to exploit new technological trends.
  • You will be able to realise your company's full potential within the market.
  • You will better understand the competitive landscape and identify potential new business opportunities and partnerships.

Five reasons why you must order and read this report today:

1) The report provides a detailed analysis of ten of the most promising emerging energy storage technologies, including information on performance characteristics, key advantages and limitations, intended applications, potential competitors, current uptake and location of demonstration plants and technology developers:

  • Innovative pumped hydro storage (PHS)
  • Adiabatic and isothermal compressed air energy storage (AA-CAES)
  • Liquid air energy storage (LAES)
  • Large-scale hydrogen energy storage and hydrogen fuel cells
  • Superconducting magnetic energy storage (SMES)
  • Lithium-air batteries
  • Lithium-sulphur batteries
  • Magnesium-ion batteries
  • Zinc-air batteries

2) The report analyses the outlook for each of the emerging technologies, providing information on expected progression to commercialisation and expected deployment, by focusing on:

  • Stage of development and current uptake for early commercial technologies, or existing and planned pilot and demonstration plants
  • Performance characteristics
  • The ability of each technology to use existing supply chains
  • The maturity and safety of the components used by each technology
  • Technological limitations, and factors affecting commercial viability
  • Any potential associated requirements (e.g. infrastructure)
  • The availability of RD&D funding and government support
  • The intended applications of the technology and competition from other established and emerging ESTs

3) The report also includes a chapter dedicated to a detailed comparative assessment of emerging and established energy storage technologies, focusing on their:

  • Performance characteristics (capacity, round-trip efficiency, lifecycle)
  • The maturity and limitations to further development or commercialisation
  • Suitability for different types of applications

4) The analysis is underpinned by exclusive interviews with leading experts and technology developers, providing unique insight into the technology development process, planned demonstration plants and expected commercialisation dates:

  • Gareth Brett from Highview Power
  • Paul DiRenzo, Jr. from Peak Hour Power
  • Philippe Bouchard from EoS Energy Storage
  • Giw Zanganeh from Airlight Energy

5) The report concludes with an analysis of the leading regional market spaces involved in the development and deployment of emerging energy storage technologies

  • North America
  • Europe
  • Asia

This independent, 209 page report offers you a unique opportunity to receive a one-stop review of all key emerging energy storage technologies, their capacity, round-trip efficiency, lifecycle, maturity and prospects. With 131 tables and figures examining the emerging EST market space, the report gives you a comprehensive overview of the prospects for emerging technologies PLUS information on key demonstration and pilot projects and expected commercialisation dates. Do not miss an opportunity to gain a comprehensive understanding of all key emerging energy storage technologies, and their comparison to existing energy storage technologies.

Who should read this report?

  • Anyone within the energy storage technologies value chain
  • Energy storage technology developers
  • Venture capital firms and angel investors interested in energy storage
  • CEOs
  • COOs
  • CIOs
  • Business development managers
  • Marketing managers
  • Technologists
  • Suppliers
  • Investors
  • Banks
  • Government agencies
  • Contractors
  • Transmission and distribution system operators
  • Electricity sector utilities
  • Operators and owners of CSP plants

Don't miss out

This report is essential reading for you or anyone in the power or energy storage sectors with an interest in energy storage technologies. Purchasing this report today will help you to recognise important market opportunities and understand the possibilities there.

Order the Next Generation Energy Storage Technologies (EST) Market Prospects 2016 report now. We look forward to receiving your order.

visiongain is a trading partner with the US Federal Government.

Table of Contents

1. Executive Summary

  • 1.1. Next-Generation Energy Storage Technologies Market Overview
  • 1.2. Market Definition
  • 1.3. Methodology
  • 1.4. Why You Should Read This Report?
  • 1.5. Benefits of This Report
  • 1.6. Structure of this Report
  • 1.7. Key Questions Answered by This Analytical Report
  • 1.8. Who is this Report for?
  • 1.9. Frequently Asked Questions (FAQ)
  • 1.10. Associated Visiongain Reports
  • 1.11. 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

3. The Drivers and Restraints of Next-Generation Energy Storage Technologies

  • 3.1. An Introduction to the Dynamics of the Market
  • 3.2. The Factors that Will Drive and Restraint the Market
    • 3.2.1. Rising Energy Prices Indirectly Incentivise EST
    • 3.2.2. Investments in Research, Development and Demonstration
    • 3.2.3. The Importance of Renewable Energy Integration
    • 3.2.4. Smart Grids and Distributed Power Generation Systems
    • 3.2.5. Growing Electricity Demand
    • 3.2.6. The Developing Alternative Vehicle Market as a Growth Factor
    • 3.2.7. The High Capital Costs of Emerging Energy Storage Technologies
    • 3.2.8. Limited Cost Recovery Opportunities
    • 3.2.9. The Policy and Regulatory Challenges Ahead
    • 3.2.10. The Impact of a Weak Market Demand for EST
    • 3.2.11. Geographical and Spatial Constraints of Mature Energy Storage Technologies
    • 3.2.12. Conservatism in the Utility Industry
    • 3.2.13. The Need for Large-Scale Demonstration Projects
    • 3.2.14. Raw Material Availability
    • 3.2.15. Technology Development and Deployment Patterns
    • 3.2.16. The Limitations of Established Energy Storage Technologies
    • 3.2.17. Long Investment Cycles
    • 3.2.18. Opportunities for Home Energy Storage and Arbitrage

4. Next-Generation Mechanical Energy Storage Technologies

  • 4.1. Innovative Pumped Hydro Storage
    • 4.1.1. An Introduction to Innovative Pumped Hydro Storage
    • 4.1.2. The Nature of the Innovation
    • 4.1.3. The Performance Characteristics Of Innovative PHS Installations
    • 4.1.4. The Applications and Key Competitors of Innovative PHS
    • 4.1.5. Current Deployment of Innovative PHS
    • 4.1.6. Drivers and Restraints of Innovative PHS
    • 4.1.7. The Outlook for Innovative PHS
    • 4.1.8. Companies and Stakeholders Involved in the Innovative PHS Market
  • 4.2. Adiabatic and Isothermal Compressed Air Energy Storage
    • 4.2.1. An Introduction to Adiabatic and Isothermal Compressed Air Energy Storage
    • 4.2.2. The Nature of the Innovation
    • 4.2.3. The Performance Characteristics of Adiabatic and Isothermal CAES
    • 4.2.4. The Applications and Key Competitors of Advanced CAES
    • 4.2.5. Current Deployment of Compressed Air Energy Storage
    • 4.2.6. Drivers and Restraints of Advanced Compressed Air Energy Storage
    • 4.2.7. The Outlook for Advanced Compressed Air Energy Storage
    • 4.2.8. Companies and Stakeholders Involved in the Advanced CAES Market
  • 4.3. Liquid Aid Energy Storage (LAES)
    • 4.3.1. An Introduction to Liquid Air Energy Storage
    • 4.3.2. The Nature of the Innovation
    • 4.3.3. The Performance Characteristics of Liquid Air Energy Storage
    • 4.3.4. The Applications and Key Competitors of Liquid Air Energy Storage
    • 4.3.5. Current Deployment of Liquid Air Energy Storage
    • 4.3.6. Drivers and Restraints of the Liquid Air Energy Storage Market
    • 4.3.7. The Outlook for Liquid Air Energy Storage
    • 4.3.8. Companies and Stakeholders Involved in the Liquid Air Energy Storage Market

5. Next-Generation Chemical Energy Storage Technologies

  • 5.1. Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 5.1.1. An Introduction to Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 5.1.2. The Nature of the Innovation
    • 5.1.3. The Performance Characteristics of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 5.1.4. The Applications and Key Competitors of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
    • 5.1.5. Current Deployment of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 5.1.6. Drivers and Restraints of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
    • 5.1.7. The Outlook for Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells
    • 5.1.8. Companies and Stakeholders Involved in the Hydrogen and Fuel Cells Energy Storage Market

6. Next-Generation Electrical Energy Storage Technologies

  • 6.1. Superconducting Magnetic Energy Storage (SMES)
    • 6.1.1. An Introduction to Superconducting Magnetic Energy Storage (SMES)
    • 6.1.2. The Nature of the Innovation
    • 6.1.3. The Performance Characteristics of Superconducting Magnetic Energy Storage
    • 6.1.4. The Applications and Key Competitors of Superconducting Magnetic Energy Storage
    • 6.1.5. Current Deployment of Superconducting Magnetic Energy Storage
    • 6.1.6. Drivers and Restraints of Superconducting Magnetic Energy Storage
    • 6.1.7. The Outlook for Superconducting Magnetic Energy Storage
    • 6.1.8. Companies and Stakeholders Involved in the Superconducting Magnetic Energy Storage Market

7. Next-Generation Electrochemical Energy Storage Technologies

  • 7.1. An Introduction to Next-Generation Battery Technologies
  • 7.2. The Key Drivers of Innovation in the Market
  • 7.3. Key Patterns of Innovation in the Market
  • 7.4. Lithium-air (Li-Air)
    • 7.4.1. Nature of the Innovation
    • 7.4.2. The Performance Characteristics of Lithium Air Batteries
    • 7.4.3. The Applications and Key Competitors of Lithium Air Batteries
    • 7.4.4. Current Deployment of Lithium Air Batteries
    • 7.4.5. The Drivers and Restraints of the Lithium Air Batteries Market
    • 7.4.6. The Outlook for Lithium Air Batteries
    • 7.4.7. Key Companies Involved in the Lithium Air Battery Market
  • 7.5. Lithium-Sulphur (Li-S)
    • 7.5.1. Nature of the Innovation
    • 7.5.2. The Performance Characteristics of Lithium Sulphur Batteries
    • 7.5.3. The Applications and Key Competitors of Lithium Sulphur Batteries
    • 7.5.4. Current Deployment of Lithium Sulphur Batteries
    • 7.5.5. The Drivers and Restraints of the Lithium Sulphur Battery Market
    • 7.5.6. The Outlook for Lithium Sulphur Batteries
    • 7.5.7. Key Companies and Stakeholders Involved in the Lithium Sulphur Battery Market
  • 7.6. Magnesium-Ion (Mg-Ion)
    • 7.6.1. Nature of the Innovation
    • 7.6.2. The Performance Characteristics of Magnesium Ion Batteries
    • 7.6.3. The Applications and Key Competitors of Magnesium Ion Batteries
    • 7.6.4. Current Deployment of Magnesium Ion Batteries
    • 7.6.5. The Drivers and Restraints of Magnesium Ion Batteries
    • 7.6.6. The Outlook for Magnesium Ion Batteries
    • 7.6.7. Key Companies and Stakeholders Involved in the Magnesium Ion Battery Market
  • 7.7. Zinc-Air (Zn-air)
    • 7.7.1. Nature of the Innovation
    • 7.7.2. The Performance Characteristics of Zinc Air Batteries
    • 7.7.3. The Main Applications and Key Competitors of Zinc Air Batteries
    • 7.7.4. Current Deployment of Zinc Air Batteries
    • 7.7.5. The Drivers and Restraints of the Zinc Air Battery Market
    • 7.7.6. The Outlook for Zinc Air Batteries
    • 7.7.7. Key Companies and Stakeholders in the Zinc Air Battery Market
  • 7.8. Concluding Remarks on Emerging Battery Storage Technologies

8. Expert Opinions

  • 8.1. Expert Interview with Paul DiRenzo, Jr from Peak Hour Power
    • 8.1.1. The Growing Interest in Innovative Pumped Hydro Storage Installations?
    • 8.1.2. The Opportunities and Challenges of Seawater PHS
    • 8.1.3. The Competition of Other Next-Generation Bulk Storage Technologies
  • 8.2. Expert Interview with Giw Zanganeh, Airlight Energy
    • 8.2.1. Latest Developments at Airlight Energy
    • 8.2.2. CAES and Thermal Energy Storage in the Context of Other ESTs
    • 8.2.3. The Market Space and Applications of Thermal Energy Storage
    • 8.2.4. The Maturity and Key Markets of the AA-CAES Technology
  • 8.3. Expert Interview with Gareth Brett and Emma Gibson, Highview Power
    • 8.3.1. Latest Developments at Highview Power
    • 8.3.2. Liquid Air Energy Storage Technology
    • 8.3.3. The Maturity and Commercial Viability of the Technology
    • 8.3.4. The Key Challenges and Competitors
    • 8.3.5. Media Attention and the Hype Surrounding Emerging Technologies
    • 8.3.6. The Technical Specifications and Performance of the Technology
    • 8.3.7. Key Markets and Main Regulatory Drivers/Restraints
    • 8.3.8. The Status of Energy Storage Assets
    • 8.3.9. The Outlook of Next-Generation ESTs
  • 8.4. Expert Interview with Philippe Bouchard, EoS Energy Storage
    • 8.4.1. Latest Developments at EoS Energy Storage
    • 8.4.2. EoS Energy Storage and Next-Generation Battery Chemistries
    • 8.4.3. The Performance Characteristics of Eos Battery Chemistries
    • 8.4.4. The Key Competitors in the Market
    • 8.4.5. The Maturity of the Hybrid Cathode Battery Technology
    • 8.4.6. The Main Patterns of Innovation in the Energy Storage Sector
    • 8.4.7. Key National Markets

9. PEST Analysis of the Next-Generation Energy Storage Market

10. Established and Emerging Energy Storage Technologies, a Comparative Analysis

11. The Global Landscape of the Emerging Energy Storage Technologies Market

  • 11.1. Next-Generation Energy Storage Technologies in North America
    • 11.1.1. Drivers and Restraints of Next-Generation ESTs Development and Deployment in North America
  • 11.2. Next-Generation Energy Storage Technologies in Europe
    • 11.2.1. Drivers and Restraints of Next-Generation ESTs development and Deployment in Europe
  • 11.3. Next-Generation Energy Storage Technologies in Asia
    • 11.3.1. Drivers and Restraints of Next-Generation ESTs development and Deployment in Asia

12. Conclusions and Recommendations

  • 12.1. Drivers and Restraints of the Emerging Energy Storage Technologies Market
  • 12.2. The Outlook for Innovative Pumped Hydro Storage
  • 12.3. The Outlook for Advanced Compressed Air Energy Storage
  • 12.4. The Outlook for Liquid Air Energy Storage
  • 12.5. The Outlook for Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
  • 12.6. The Outlook for Superconducting Magnetic Energy Storage
  • 12.7. The Outlook for Next-Generation Batteries

13. 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 2.1: List and Description of Main EST Applications
  • Table 3.1: Recent Demonstration Projects Funded by ARRA (Name, EST, Size (MW) Cost ($m), Planned Application)
  • Table 3.3: Global EST Market Drivers & Restraints
  • Table 4.1: PHS main characteristics (Lifetime, Capacity MW, Efficiency %, Maturity)
  • Table 4.2: List of all Operating Innovative Pumped Hydro Installations (Name, Location, Capacity MW, Type, Commissioning)
  • Table 4.3: Pumped Hydro Storage (PHS) Market Drivers & Restraints
  • Table 4.4: Innovative PHS Submarket Forecast 2016-2026 ($mil, AGR %, CAGR %, Cumulative)
  • Table 4.5: Innovative PHS Installed Capacity Forecast 2016-2026 (MW, Cumulative)
  • Table 4.6: List of all Planned Innovative Pumped Hydro Installations (Name, Location, Capacity MW, Type, Commissioning)
  • Table 4.7: Performance Characteristics of Conventional and Advanced CAES (Lifetime, Capacity MW, Efficiency %, Maturity )
  • Table 4.8: Installed CAES Capacity by National Market (MW)
  • Table 4.9: Key Diabatic and Adiabatic Compressed Air Energy Projects (Name, Location, Capacity MW, Type, Commissioning)
  • Table 4.10: Advanced CAES Market Drivers & Restraints
  • Table 4.11: Project Details for the Poleggio-Loderio Pilot AA-CAES Plant (Name, Location, Companies and Organisations Involved, Capacity kW, Type, Commissioning Date)
  • Table 4.12: The Main Characteristics of Liquid Air Energy Storage (Lifetime, Capacity MW, Efficiency %, Maturity)
  • Table 4.13: Drivers/ Advantages and Restraints/ Disadvantages of the LAES
  • Table 5.1: Hydrogen Main Characteristics (Lifetime, Capacity, Efficiency, Maturity)
  • Table 5.2: Large-Scale Hydrogen Energy Storage and Hydrogen Fuel Cells Drivers & Restraints
  • Table 6.1: Performance characteristics SMES (Lifetime, Capacity MW, Efficiency %, Maturity)
  • Table 6.2: Drivers & Restraints of the SMES Market
  • Table 7.1: Main Performance Characteristics of Lithium-Air Batteries (Energy density, Cycle life, Efficiency, Maturity)
  • Table 7.2: Lithium Air Batteries Market Drivers & Restraints
  • Table 7.3: Main Performance Characteristics of Lithium Sulphur Batteries (Energy Density, Cycle life, Efficiency, Maturity)
  • Table 7.4: Lithium Sulphur Batteries Market Drivers and Restraints
  • Table 7.5: Main Performance Characteristics for Magnesium Ion Batteries (Energy Density, Cycle life, Efficiency, Maturity)
  • Table 7.6: Magnesium Ion Batteries Market Drivers & Restraints
  • Table 7.7: Main Performance Characteristics of Zinc Air Batteries (Energy Density, Cycle life, Efficiency, Maturity)
  • Table 7.8: Zinc Air Battery Market Drivers & Restraints
  • Table 9.1: PEST Analysis of the Emerging EST Market
  • Table 10.1: Comparison of Key Established and Emerging Energy Storage Technologies (Maturity, Capacity, Efficiency, Lifecycle)
  • Figure 10.2: The Development Stage and Challenges of Established and Emerging Energy Storage Technologies
  • Table 11.1: Overview of the Next-Generation EST Being Developed in Different Regional and National Markets
  • Table 11.2: North America Next-Generation EST Market Drivers & Restraints
  • Table 11.3: Examples of Emerging Energy Storage RD&D Funding
  • Table 11.4: European Next-Generation EST Market Drivers & Restraints
  • Table 11.5: Asian Next-Generation EST Market Drivers & Restraints
  • Table 12.1: Global EST Market Drivers & Restraints
  • Table 12.2: Innovative PHS Submarket Forecast 2016-2026 ($m, AGR %, CAGR %, Cumulative)
  • Table 12.3: Innovative PHS Installed Capacity Forecast 2016-2026 (MW, Cumulative)

List of Figures

  • Figure 1.1: Next-Generation Energy Storage Technologies Market Overview
  • Figure 1.2: Development Stage of Different Energy Storage Technologies
  • Figure 1.3: The Performance Characteristics of Advanced and Conventional CAES (Lifecycle-years, Efficiency %, Capacity, Maturity) 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 (GW) 1996-2015
  • Figure 2.5: Global Energy Storage Capacity by EST Type, Excluding PHS (GW),1996-2015
  • Figure 2.6: Key Next-Generation EST Market Structure Overview
  • Figure 2.7: EST Overview of Types of Applications
  • Figure 3.1: Industrial Electricity Price History in France, Germany, Italy, UK, Japan and USA 1979-2014 (Pence/kWh)
  • Figure 3.2: Industrial Electricity Prices for Medium Sized Industries in European Countries 2004-2014 (EUR/kWh)
  • Figure 3.3: Industrial Electricity Prices for Medium Sized Industries in Germany, Spain, France and the United Kingdom 2004-2014 (EUR/kWh)
  • Figure 3.4: Total Public Energy RD&D Spending of IEA Members 2015 (% of Total RD&D Spending on Energy-Related Projects)
  • Figure 3.5: Evolution of Total Public Energy RD&D Spending by Selected IEA members 1985-2013 ($m)
  • Figure 3.6: The Scale and Composition of Installed RES capacity in Selected Countries and Regions (GW)
  • Figure 3.7: Electricity Generated from Renewable Sources, EU 28, 2003-2013 (TWh, % of Consumption)
  • Figure 3.8: Number of FCEVs expected to operate in the US, South Korea, Japan and Europe 2020
  • Figure 3.9: Technology and Innovation Adoption Lifecycle
  • Figure 4.1: Main Types of PHS Installations
  • Figure 4.2: Evolution of Installed Capacity in the Open-Loop, Closed-Loop and Innovative PHS Submarkets (1926 - 2015 , MW)
  • Figure 4.3: Main Patterns of Innovation in the Global PHS Sector
  • Figure 4.4: Average Capacity of Existing and Planned PHS Installations (Submarket, MW)
  • Figure 4.5: The Performance Characteristics of Innovative PHS (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 4.6: Main Applications of Innovative PHS
  • Figure 4.7: Main Competitors of Innovative PHS
  • Figure 4.8: Key Market Spaces for Innovative PHS
  • Figure 4.9: Evolution of Installed Capacity in the Innovative PHS Submarket 1966 - 2015 (MW)
  • Figure 4.10: Total CAPEX on Innovative PHS by National Market (Cumulative 2016-2026 $mil)
  • Figure 4.11: Innovative PHS Installed Capacity Forecast 2016-2026 (MW)
  • Figure 4.12: Structure of the CAES Market
  • Figure 4.13: Roundtrip Efficiency of Conventional Diabatic CAES and Advanced CAES (%)
  • Figure 4.14: The Performance Characteristics of Advanced and Conventional CAES (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 4.15: Main Applications of Advanced Compressed Air Energy Storage
  • Figure 4.16: Main Competitors of Advanced Compressed Air Energy Storage
  • Figure 4.17: Key Market Spaces for Advanced CAES
  • Figure 4.18: Installed CAES Capacity by Category: Diabatic and Isothermal (MW, % of total)
  • Figure 4.19: Anticipated progress of AA-CAES through the pilot stage onto commercialisation (2014-2020)
  • Figure 4.20: Selection of Stakeholders and Companies Involved in the Advanced Compressed Air Energy Storage Market
  • Figure 4.21: The Stages Involved in Liquid Air Energy Storage
  • Figure 4.22: Roundtrip Efficiency of Liquid Air Energy Storage Variants (Standalone, Integrating Waste Heat and Integrating Waste Cold, %)
  • Figure 4.23: The Performance Characteristics of Liquid Air Energy Storage (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 4.24: Main Applications of Liquid Air Energy Storage
  • Figure 4.25: Main Competitors of Liquid Air Energy Storage
  • Figure 4.26: Key Market Spaces for Liquid Air Energy Storage
  • Figure 4.27: The Historic and Expected Development of Liquid Air Energy Storage (Conceptualisation to Commercialisation, 2005-2018)
  • Figure 4.28: Selection of Stakeholders and Companies Involved in the Liquid Air Energy Storage Market
  • Figure 5.1: The Fundamentals of Hydrogen Storage and Hydrogen Fuel Cells
  • Figure 5.2: The Roundtrip Efficiency of Hydrogen Storage by Pathway Variant ( Electricity > Gas > Electricity and Heat, Electricity > Gas > Electricity and Electricity > Gas) (%)
  • Figure 5.3: The Performance Characteristics of Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 5.4: Main Applications of Large-Scale Hydrogen Storage Systems and Hydrogen Fuel Cells
  • Figure 5.5: Main Competitors of Large-Scale Hydrogen Storage Systems
  • Figure 5.6: Main Competitors of Hydrogen Fuel Cells
  • Figure 5.7: Key Market Spaces for Hydrogen Storage and Hydrogen Fuel Cells
  • Figure 5.8: FCEV Fleet in Operation in Leading National and Regional Markets as of 2014
  • Figure 5.9: Hydrogen Fuelling Stations in Operation in Leading National and Regional Markets as of 2014
  • Figure 5.10: The Main Types of Hydrogen Storage
  • Figure 5.11: Existing and Planned Hydrogen Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 5.12: Existing and Planned Hydrogen Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 5.13: Existing and Planned Alternative Fuelling Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)
  • Figure 5.14: Selection of Stakeholders and Companies Involved in the Large-Scale Hydrogen Energy Storage Systems and Hydrogen Fuel Cells Market
  • Figure 6.1: Variants of SMES technology
  • Figure 6.2: The Performance Characteristics of Superconducting Magnetic Energy Storage (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 6.3: Main Applications of Superconducting Magnetic Energy Storage
  • Figure 6.4: Main Competitors of Superconducting Magnetic Energy Storage
  • Figure 6.5: Key Market Spaces for Superconducting Magnetic Energy Storage
  • Figure 6.6: Selection of Stakeholders and Companies Involved in the Superconducting Magnetic Energy Storage Market
  • Figure 7.1: Key Emerging Battery Chemistries
  • Figure 7.2: Li-air Categorisation by Electrolyte
  • Figure 7.3: The Performance Characteristics of Lithium Air Batteries (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 7.4: The Performance Characteristics of Lithium Sulphur Batteries (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 7.5: Main Applications of Lithium Sulphur Batteries
  • Figure 7.6: Key Market Spaces for Lithium Sulphur Batteries
  • Figure 7.7: Selection of Stakeholders and Companies Involved in the Lithium Sulphur battery Market
  • Figure 7.8: Selection of Stakeholders and Companies Involved in the Magnesium Ion Battery Market
  • Figure 7.9: The Performance Characteristics of Zinc Air (Lifecycle-years, Efficiency %, Capacity, Maturity) on a Metric Standardised for all Emerging Technologies
  • Figure 7.10: Main Applications of Zinc Air Batteries
  • Figure 7.11: Selection of Stakeholders and Companies Involved in the Zinc Air Battery Market
  • Figure 10.1: ESTs Characteristics and Requirements of Key Applications
  • Figure 10.2: Cost and Backup Time Comparison of Power Quality Energy Storage Technologies Except Pumped Storage (Euro/kWh & hours)
  • Figure 10.3: Comparison of the Roundtrip Efficiency of Key Established and Emerging Energy Storage Technologies (%)
  • Figure 11.1: Key National Markets Involved in the Development of Next-Generation Energy Storage Technologies
  • Figure 11.2: Overview of the Key Next-Generation ESTs Under Development in North America
  • Figure 11.3: Overview of the Key Next-Generation ESTs Under Development in Europe
  • Figure 11.4: Overview of the Key Next-Generation ESTs Under Development in Asia
  • Figure 12.1: Next-Generation Energy Storage Technologies Market Overview
  • Figure 12.2: Development Stage of Different Energy Storage Technologies
  • Figure 12.3: Anticipated Progress of AA-CAES through the pilot stage onto commercialisation (2014-2020)
  • Figure 12.4: The Historic and Expected Development of Liquid Air Energy Storage (Conceptualisation to Commercialisation, 2005-2018)
  • Figure 12.5: Existing and Planned Hydrogen Infrastructure in Leading Global Markets (Hydrogen Fuelling Stations)

Companies Listed

  • ABB Group
  • A123 Systems
  • Air Liquide
  • Air Products
  • Airbus Defense and Space
  • ALACAES
  • Alpiq
  • Axpo
  • Ballard Power Systems
  • Bruker
  • Chubu Electric
  • DLR
  • Dresser Rand
  • E.ON
  • Eagle Crest Energy
  • EDF
  • Electric Power Development Co.,
  • Ener1
  • Enercon
  • Energias de Portugal
  • EnZinc
  • Eos Energy Storage
  • Fluidic Energy
  • Fujikura
  • Furukawa Electric
  • Gartner
  • General Compression
  • General Electric
  • General Motors
  • Grid Logic
  • Gridflex Energy LLC Principals
  • Highview Power
  • Hitachi
  • Honda
  • Hydrogenics
  • IBM
  • Illwerge AG
  • ITM Power
  • J-Power
  • Linde
  • Magnum Energy Storage
  • Mercedes-Benz
  • Nissan
  • Norsk Hydro
  • Oxis Energy
  • Pacific Gas and Electric
  • Peak Hour Power LLC
  • Pellion Technologies
  • PG&E
  • Phinergy
  • PJM
  • Proinso
  • Proton Motor
  • Proton Motor
  • ReVolt Technology
  • RWE
  • Siemens Dailmer
  • Sion Power
  • Sony
  • Superconductor Technologies
  • SuperPower
  • SustainX
  • Tesla
  • Texas Center for Superconductivity
  • Thüga
  • Toyota
  • UTC Power
  • Valence Technology
  • Verbund
  • Volkswagen
  • ZAF Energy Systems
  • Züblin

Other Organisations Mentioned in This Report

  • Advanced Research Projects Agency - Energy (ARPA-E)
  • Brookhaven National Laboratory
  • California Public Utility Commission (CPUC)
  • Cambridge University
  • China Electrical Power Research Initiative (CEPRI)
  • Companies and organisations to look into
  • Electric Power Research Institute (EPRI)
  • Electric Vehicle Initiative (EVI)
  • Electricity Storage Association
  • European Commission
  • European Institute for Energy Research (EIFER)
  • European Parliament
  • European Photovoltaic Industry Association (EPIA)
  • European Union (EU)
  • Fraunhofer Center for Energy Storage
  • Fraunhofer Institute
  • 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)
  • Hessian Ministry for the Environment, Energy, Agriculture and Consumer Protection
  • High Energy Research Organisation
  • International Energy Agency (IEA)
  • Italian Ministry of Economy and Finances
  • Japan the Ministry of Economy, Trade and Industry (METI)
  • Korea Institute of Energy Research (KIER)
  • Lawrence Berkeley National Lab
  • National Energy Administration (NEA)
  • Ontario Ministry of Energy
  • Organisation for Economic Co-operation and Development (OECD)
  • REN21 (The Renewable Energy Network for the 21st Century)
  • Southern California Edison
  • Swiss Federal Office of Energy (SFOE)
  • Texas Centre for Superconductivity
  • Toyota Research Institute of North America (TRINA)
  • UK Department of Energy and Climate Change (DECC)
  • UK National Grid
  • United States Department of Energy (DOE).
  • Universität Magdeburg
  • United Nations Framework Convention on Climate Change (UNFCC)
  • US Energy Information Administration (EIA)
  • US Federal Energy Regulatory Commission (FERC)
  • Vehicle Technologies Office (VTO)
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