智慧電網用電池・超級電容器市場:市場機會分析(2009年至2016年) 是由出版商NanoMarkets在2009年08月所出版的。
這份英文市場調查報告書包含120 Pages 價格從美金995起跳。
本報告書內容包括:智慧電網用化學電池及超級電容器材料的市場機會調查分析、各種電池類型概要、現在的用途、今後的用途、R&D動向、2016年之前的8年市場成長預測、主要企業介紹。內容綱要摘記如下:
實施概要
第1章 介紹
第2章 利用電池及超級電容器的智慧電網儲存材料・技術
- 介紹:智慧電網最先端儲存解決方案需求
- 智慧電網概要
- 智慧電網儲存需求及利用實例
- 智慧電網儲存選擇
- 智慧電網儲存各種材料的市場機會
- 傳統的電網儲存解決方案
- 鉛蓄電池及最先進的鉛蓄電池
- 氫化物電池
- 鋰離子電池
- 最先進的電網儲存解決方案
- 鈉硫黃蓄電池
- 全釩氧化還原液流電池及其他液流電池系統
- 鋅溴・其他複合流程電池系統
- 液態金屬電池
- 化學儲存材料藍圖
- 超級電容器及智慧電網領域
- 現在的超級電容器及現在的應用
- 智慧電網超級電容器應用
- 最先端超級電容器及智慧電網應用
- 超級電容器材料藍圖
第3章 企業介紹
- 最先進的鉛酸
- 最先進的鋰離子
- 鈉‐硫黄
- 鋅溴儲存電池
- 全釩氧化還原液流系統
- 其他電池系統
- 超級電容器
第4章 8年預測
- 預測方法
- 資料來源
- 刺激電網儲存需求的潔淨能源的義務
- 智慧電網儲存藍圖
- 智慧電網儲存電池/超級電容器材料:8年預測
- 傳統型化學儲存技術
- 最先進的化學儲存技術
- 超級電容器儲存技術
Abstract
Summary
While the current electrical grid is a modern marvel, the smart grid of the
future will include significant electrical storage as part of the solution to
increase the grids efficiency, enhance reliability, and help reduce the
environmental impact of supplying the electrical power needs of modern
society. As a result, NanoMarkets believes chemical batteries,
ultra-capacitors, and the materials from which they are built represent an
exciting business opportunity that is poised to take off in the near future.
This report is designed to quantify that opportunity and identify the best
strategies to capitalize on it.
By 2016 there will be 33 GW of generating capacity on the grid from solar
panels and wind farms that can swing wildly in their ability to generate
electrical power at any given time. Electrical storage will be a requirement
to level the load when the sun doesn' t shine or the wind doesn' t blow in a
predictable manner. In addition to load leveling, grid storage will allow peak
shaving where stored electricity from non peak demand periods can be used
during peak load times. Peak shaving can reduce the need for new power plants
and reduce the grids overall carbon footprint.
Chemical batteries and ultra-capacitors represent complimentary pieces of the
smart grid storage equation with ultra-capacitors used for smoothing short
term disruptions in power quality and batteries storing current for longer
term load leveling and peak shaving applications. While other technologies
such as hydro and compressed air storage will certainly be integral parts to
the overall storage solution, batteries and ultra-capacitor storage represent
a large attractive near term materials growth sector.
This new market study of materials for chemical batteries and ultra-capacitors
for smart grid applications surveys and analyzes the markets for the various
battery and ultra-capacitor types currently in use and about to enter service
in smart grid applications as well as R&D developments, including those
related to systems. As with all NanoMarkets reports, this report includes a
detailed eight year forecast of materials for smart grid storage applications
and an in-depth discussion of key firms active in the area.
Methodology
The primary source for the opinions and conclusions in this report is
extensive interviews with various industry and academic sources carried out by
NanoMarkets. Secondary research for this report was taken from information
available on the World Wide Web, commercial and government databases, trade
press articles, technical literature, information learned at technical
conferences and trade shows, SEC filings and other corporate literature. The
forecasting approach taken in this report is explained in more detail in
Chapter Four.
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