Table of Contents
Executive Summary
- E.1 Introduction: Smart grid storage and materials opportunities.
- E.1.1 Overview of the smart grid and the role of energy storage.
- E.1.2 Current energy storage options for a smart grid.
- E.2 Opportunities for smart grid storage; materials and manufacturing
companies.
- E.3 Key Firms to watch in smart grid energy storage landscape.
- E.4 Summary of Forecasts.
Chapter One: Introduction
- 1.1 Background to this report.
- 1.1.1 Materials opportunities in the emerging smart grid.
- 1.2 Objective and scope of this report.
- 1.3 Methodology of this report.
- 1.4 Plan of this report.
Chapter Two: Materials and Technology for Battery and Ultra-Capacitor Smart Grid Storage
- 2.1 Introduction: The crucial need for advanced storage solutions in a
smart grid.
- 2.1.1 Overview of the smart grid.
- 2.1.2 The need for storage in the smart grid and examples of its use
today.
- 2.1.3 Storage options on the smart grid
- 2.1.4 Materials opportunities in smart grid storage
- 2.2 Traditional grid storage solutions
- 2.2.1 Lead acid and advanced lead acid batteries
- 2.2.2 Metal hydride batteries
- 2.2.3 Lithium ion batteries
- 2.3 Advanced grid storage solutions.
- 2.3.1 Sodium Sulfur batteries.
- 2.3.2 Vanadium redox. and other redox flow battery systems.
- 2.3.3 Zinc bromine and other hybrid flow battery systems.
- 2.3.4 Liquid metal batteries.
- 2.3.5 Chemical storage materials roadmap.
- 2.4 Ultra-capacitors and their place in the smart grid
- 2.4.1 Current ultra-capacitors and their current applications.
- 2.4.2 Ultra-capacitor applications in a smart grid.
- 2.4.3 Advanced Ultra-capacitors and their smart grid applications
- 2.4.4 Ultra-capacitor materials roadmap.
Chapter Three: Company Profiles
- 3.1 Advanced Lead Acid Companies
- 3.1.1 Exide Technologies
- 3.1.2 Enersys
- 3.1.3 C&D Technologies
- 3.1.4 Ultralife Batteries
- 3.1.5 Axion Power International
- 3.1.6 Varta Bosch
- 3.2 Advanced lithium Ion
- 3.2.1 Altair Nanotechnologies
- 3.2.2 Ener1
- 3.2.3 Valence Technologies
- 3.2.4 SAFT Groupe/ABB JV
- 3.2.5 NGK Insulators Ltd
- 3.2.6 A123 systems
- 3.2.7 Boston Power
- 3.2.8 nexeon (silicon anode lithium ion batteries)
- 3.2.9 Imara
- 3.2.10 SAFT
- 3.2.11 Sanyo
- 3.2.12 Hitachi maxell
- 3.2.13 Cobasys
- 3.2.14 Johnson Controls/Saft Advanced Power Solutions
- 3.2.15 Kyushu Electric Power and Mitsubishi Heavy Industries
- 3.3 Sodium Sulfur
- 3.3.1 NGK insulators Ltd
- 3.3.2 Tokyo Electric Power (TEPCO)
- 3.4 Zinc Bromide Storage Batteries
- 3.5 Vanadium Redox based systems
- 3.5.1 Vfuel Pty Ltd
- 3.5.2 Sumitomo Electric Industries
- 3.5.3 Cellennium limited (Thailand)
- 3.5.4 RE-fuel Technology
- 3.6 Others battery systems
- 3.6.1 Metal Hydride
- 3.6.2Revolt (zinc air)
- 3.6.3Liquid metal batteries (MIT)
- 3.7 Ultra-capacitors
- 3.7.1 Maxwell
- 3.7.2 Siemens
- 3.7.3 EPCOS
- 3.7.4 NEC/Tokin
- 3.7.5 Panasonic/Matsushita
- 3.7.6 Elna/Asahi Glass
- 3.7.7 Ness Capacitor
- 3.7.8 Power Systems Co.
- 3.7.9 ESMA
- 3.7.10 EEStor
- 3.7.11 EnerG2
- 3.7.12 APowerCap
- 3.7.13 BatScap
Chapter Four: Eight-Year Forecasts for Smart Grid Storage Batteries and Ultra-Capacitors Materials Markets
- 4.1 Forecasting Methodology
- 4.1.1 Data Sources
- 4.1.2 Clean power mandates that drive demand for grid storage
- 4.1.3 Storage roadmap for a smart grid
- 4.2 Eight-year forecast of materials used in smart grid storage batteries
and ultra-capacitors
- 4.2.1 Traditional chemical storage technologies
- 4.2.2 Advanced chemical storage technologies
- 4.2.3 Ultra-capacitor storage technologies
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