Bharat Book Bureau

Batteries Supercapacitors Alternative Storage for Portable Devices

New technologies call for different forms of battery
Electronics and electrics are becoming ubiquitous, the devices appearing on and in higher and higher volume products including e-labels and e-packaging. This calls for different forms of battery, capacitor and other energy storage because priorities such as environmental credentials, thinness and compatibility with energy harvesting (eg solar cells) come to the fore alongside life and cost. This unique new report is directed towards those developing, marketing and using the new small electronic and electrical devices, particularly those that are self-sufficient. It will also interest those investing in new battery, capacitor and allied companies providing products for these markets and those regulating and supporting these burgeoning industries. To this end, the report is almost devoid of equations but it is replete with summary diagrams and tables, pros and cons, company profiles, new products and applications beyond the familiar ones. There is therefore much to interest those with a technical background as well. The report looks hard at what comes next, particularly over the next ten years.

Designed for a broad range of readers
We use relatively simple language so the report can be useful to as broad a range of readers as possible, enhanced by a glossary. After all, investors, government regulators, journalists and many other people have a great interest in the imminent huge deployment of small self-powered electronic and electrical devices. It will eventually reach hundreds of billions of products yearly, including electronically enhanced drug packs, magazines, disposable medical testers and much more besides. For the more technical, there are many new summary tables and diagrams comparing parameters required and achieved. The parameters, including costs, and the applications are compared and the work of many suppliers is evaluated. No other report on this subject is as broad ranging or up to date. The main emphasis is on what will needed and possible, not on rehearsing the story of traditional cylindrical, laptop and mobile phone batteries. Here we see the future.

Largest mobile energy storage market today
Energy storage for small devices, the subject of this report, forms by far the largest mobile energy storage market today, being much larger and faster growing than the market for heavy energy storage such as automotive and enjoying greater innovation for the future, including transparent and printed batteries. The report mainly concentrates on batteries and capacitors - including the rapid adoption of supercapacitors and hybrids of the two. It explains how they are constructed, how they work and the pros and cons. However, it also touches on the elusive small fuel cells and other options. Focussing on use in small devices, we forecast the market for both single use and rechargeable batteries by numbers and value from 2009-2019 and the market size for supercapacitors, tracking a return to rapid growth from 2010, after the global financial meltdown ends. The market drivers are given as they change over the years. We evaluate the limitations of current devices against what will be needed and what can be done. For example, as the traditional parameters of batteries and capacitors are painfully and slowly improved, some completely different improvements are proving exciting because they can open up completely new markets. These include transparent, edible, stretchable, woven, stitchable, implantable, biodegradable and wide area versions more suited to the world of ubiquitous electronics that is arriving. As wall decoration, windows, apparel, books, posters, consumer goods, pharmaceutical packaging , the sensing skin of an aircraft and the inside of a car and much more become electronic and local harvesting of power becomes commonplace, these are the products we need. We describe the remarkable new approaches including batteries assembled using viruses and carbon nanotubes, biomimetic and magnetic spin batteries and ones that can harvest energy in the human body. Then there are batteries and supercapabatteries only one tenth of a millimeter thick. Which are the most exciting developers and what will be available when? It is all here.

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Energy Harvesting Micro Batteries and Power Management ICs Market Forces and Demand Characteristics Second Edition  
 
Topics Covered Include:
• Wireless Sensor and Wireless Sensor Mesh Applications
• Standards and Regulatory Update
• Energy Storage Trends
• Low-Power Wireless System Trends
• Energy Harvesting Market Analysis
• Standards and Technologies Overview

Energy harvesting, micro batteries and power management ICs are in a position to enable the commercial rollout of the next-generation of low-power electronic devices and systems. Low-power devices are being deployed for wireless as well as wired systems such as mesh networks, sensor and control systems, and micro-electro-mechanical systems (MEMS). Applications include home automation, building automation, industrial process/automated meter reading, medical, military, automotive/tire pressure sensors, radio frequency ID and others.

Battery maintenance and replacement are often cited as the biggest reason to use energy harvesting. The first markets for these new technologies have been applications where batteries are problematic, such a building and home automation, military and avionic devices, communications and location devices, and transportation.

Cost and manufacturability are increasingly becoming key drivers for the adoption of energy harvesting, however. The system “power budget,” initial installation costs, process technology trends, and materials are reaching a point where energy harvesting is a cost-effective value proposition in many applications. Combined with tax credits for certain segments like lighting control, the energy efficiency savings are a convincing argument for many end users.

Semiconductor companies are taking the lead with power management ICs, and thin-film batteries are now commercially available to enable energy harvesting solutions. With potential markets spanning billion-unit industries, energy harvesting is expected to weather worldwide economic volatility and be a good opportunity for power supply companies.

Energy harvesting, small-format batteries and power management ICs are technologies that will enable the commercial rollout of next-generation ultra-low-power electronic devices and systems. Such devices are being deployed for wireless as well as wired systems such as mesh networks, sensor and control systems, micro-electro-mechanical systems (MEMS), radio frequency identification (RFID) devices, and so on.
Energy harvesting, microgenerators and other emerging power management technologies can be the enabler of wireless sensor network adoption. In fact, battery maintenance and replacement is cited as the “biggest reason to use energy harvesting.” The first markets for these new technologies have been applications that can’t be used with batteries. This report will analyze the “next wave” of applications that are likely to adopt advanced power management for ultra-low power devices. It will also provide an overview of the various standards that could help or hinder the adoption of these technologies, along with the power architectures and cost benefits likely to drive commercial viability.

Ultra-low-power (ULP) wireless technologies are primarily employed in applications that are not traditionally considered “portable,” such as commercial building automation, medical monitoring, transportation and avionics, automatic meter reading, RFID, construction, and military. Although not portable systems, the power needs closely mirror the needs of portable devices such as mobile phone handsets and MP3 players. As a result, emerging ULP applications are expected to provide substantial growth opportunities for power management technologies traditionally associated with portable devices (see Figure 1).

ULP wireless applications and portable applications are both low power, although ULP powering is significantly lower. Both are often wireless, and both usually use batteries. They rely on standards that vary by region and application, and both have varying ranges, data rates, and power requirements, depending on standards and applications. The same needs are driving both markets, as well: energy efficiency, small form factors, reduced power requirements, and competition with “wired” systems.

The value-added possibilities that ULP technologies bring include bi-directionality, with data rates and range being particularly important. Network security is important, along with “real-time” monitoring and remote communication with the “host” system. The increasing need to comply with environmental regulations also provides an opportunity for ULP solutions, since they can almost always ensure such compliance.

Energy harvesting is a natural complement to ultra-low-powering, including wireless mesh sensor networks. Sometimes the terms “energy scavenging” or “power harvesting” are used instead; for purposes of consistency, however, this report will use the term “energy harvesting” to designate all three.

Table of Contents:

Introduction 4
Wireless Sensor and Wireless Sensor Mesh Applications 7
Home Automation 7
Building Automation 9
Industrial Process/Automated Meter Reading 11
Medical 15
Military/Aerospace and Related 17
Automotive/Tire Pressure Sensors 19
Radio Frequency ID (RFID) 22
Applications/Hybrid Systems 24
Standards and Regulations Update 25
Standards Update 26
Regulatory Update 28
Energy Storage Trends 30
Thin-Film Batteries 31
Ultracapacitors/Supercapacitors 33
Low-Power Wireless System Trends 34
Architectures 34
Advanced Packaging 37
Power Management ICs 38
Energy Harvesting 40
Solar Developments 43
Inductive Coupling 44
Energy Harvesting Market Analysis 44
Critical Success Factors 45
Power Costs 46
Cost Benefit Analysis 48
Installation Costs 50
Materials Developments 54
Appendix A – Standards and Technologies Overview 58

List of Tabels

Table 1 – Thin-Film Market Share Module Cost by Technology 43
Table 2 – General Energy Costs of Wireless Sensor Nodes 47
Table 3 – Comparison of Energy Harvesting Power Sources 49
Table 4 – Energy Harvesting Installation Cost Savings 54

List of Figures:

Figure 1 – Portable versus ULP Technical Needs 5
Figure 2 – Tire Pressure Sensor (Bosch) 21
Figure 3 – LITE*STAR™ Thin Film Rechargeable Battery 32
Figure 4 – TPMS Sensor Node Powered by Energy Harvesting 35
Figure 5 – Piezoelectric Energy Harvesters (IMEC) 41
Figure 6 – Texas Instruments MSP430 Microcontroller 42
Figure 7 – PulseStar™ Lighting Installation 53
Figure 8 – Wireless Standards and Power Consumption 59

Companies Mentioned

4HomeMedia, ABB, Ad Hoc, AdaptivEnergy, Agpo, Air Products, AISD Inc., Aitech, Alerton Inc., Alliant Energy, AlwaysReady, American Society of Heating, Refrigerating and Air Conditioning Engineers, Aqualisa, Art of Technology AG, Audi, austriamicrosystems, Automated Logic Corp.,b+b, Balluff, Barcelona Institute of Materials Science, Beckhoff, Beijing Institute of Technology, Best Buy, BFM AB, Blue Spark Technologies (formerly Thin Battery Technology), Boeing, Bosch, BP Cherry Point Refinery, Brink, Bticino, Building Controls Industry Association,
Building Research Establishment, Cain White, California Energy Commission, CAP-XX, Cellnet+Hunt, Centerpoint, CER, Chipcon, ChipSensors Ltd., Cisco, Clage, Colorado Power Electronics Center, Comverge, Con Edison, Continental Automated Buildings Association, Coronis Systems, Crossbow, Current Group, Cymbet Corp., Cypress Semiconductor, Delta Controls, DEWALT, Digi International, Digital AV, Distech, Dorma, Dow Chemical, EasyTed, Eaton, Echo Controls, EG Holmes and Associates, Electric Power Research Institute, Electronic Industry Association in Japan, Elesta, Elk, Ember, Emerson Process Management, Endress+Hauser, ENEL, Energy Services Network Association, Enfora, Enfucell, EnOcean, EnOcean Alliance, Environmental Protection Agency, EoPlex, European Committee of Manufacturers of Domestic Appliances, Excellatron Solid State, Exceptional Innovation, FACE, Falcom, Fieldbus Foundation, First Alert, Flextron, Ford Motor Co., Fraunhofer Institute, Freescale, Funkstuhl, GE Security, General Dynamics UK, Grässlin, GreenPeak, HART Communication Foundation, Helios, Hitachi Ltd., Holst Centre (IMEC), Honeywell, Hong Kong University of Science and Technology, Hoppe, Höte, iControl Networks,
Infineon Technologies, Infinite Power Solutions, Institute for Micromachining and Information Technology, Integration, Intel, Intellihome, International Electrotechnical Commission, International Energy Agency, Invensys, IP Symcon, Itho bv, Itron,Jäger Direkt, Japan Ministry of International Trade & Industry, Jennic, KCF Technologies, Konnex Association, Krömschroder, Kronos, Lennar Homes, Los Alamos National Lab, LS Research, LV Sensors, Masco, Massachusetts Institute of Technology, MasterCard International, Matsushita Electric Industrial Co. Ltd., Maxwell, Maya, MeshNetics, Messner, ME-Technics, Metglas, Micropower, Microsoft, Mide, Mitsubishi Electric Corp., MK Electric, Moteiv, Motorola, MSR, National Highway Traffic Safety Administration, National Taiwan University, National Tsing Hua University, NEC, NFC Forum, Niko, NIRA Dynamics, Nokia, NURI, NXP Semiconductor, Ohio Supercomputer Center, Omnio, OpenTherm Association, Osram, Oventrop, Pacific Gas & Electric, Pacific Northwest National Laboratory, Peha, Perpetuum, Philips Research, Phönix Contact, Portland General Electric, Portus, Power Paper, Powerline Control Systems, Priva, Profibus Nutzerorganisation e.V., Radio Engineering & Electronics Association, Record, Regent, Reliable Controls Corp., Remeha, Saft, Saia-Burgess, Samsung, San Diego PG&E, Schlaps&Partner, Schunk, Sealed Air Corp., Servodan, Siemens AG, Sierra Wireless, Smarthome, Software Technologies Group, Solicore, Somfy, Sony, Southern California Edison, Southern Company, ST Microelectronics, Steute, Stuhl, Surrey Space Centre, Talon Communications, TCS, Televic, TEM AG, Tendril Networks, Texas Instruments, Texas Piezoelectric, Theben, Thermokon, Theta-J, ThingMagic, TL Marketing, Toshiba Corp., Tour Andover Controls (T.A.C., now owned by Schneider Electric), TXU, Tyndall National Institute, uControl, Uhlemann, UK Ministry of Defence, United Arab Emirates University, Universal Electronics, University of Alabama at Birmingham, University of California at Berkeley, University of California at San Diego, University of California Los Angeles, University of Freiburg, University of Texas at Dallas, US Department of Defense, US Department of Energy, US Federal Communications Commission, US Food and Drug Administration, US Pentagon, Venture Design Services, Vestfold University College, Vienna University of Technology, Vipa, Visa International, Visonic, W&T, Wago, Wal-Mart, Warema, Wavenis Open Standard Alliance, WaveSpace, Wieland, WildCharge Inc., Xanboo, Xcel Energy, Yokogawa, York International, Zarlink Semiconductor, ZigBee Alliance, Zumtobel, Z-Wave Alliance.
 

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Li-ion batteries have become the main power sources of mobile phones, laptops and digital electronic devices since Sony successfully commoditized Li-ion batteries in 1991. In the past, many governments and companies made great effort to develop power Li-ion batteries for HEV (Hybrid Electric Vehicles) and EV (Electric Vehicles). For example Japan developed its Sunshine Project and had participants that included Hitachi, GS-Yuasa and Panasonic. While having obtained a license to deal with nickel-metal hydride batteries, Toyota built a production line for power Li-ion batteries of its own, and attempted to use Li-ion batteries in HEV. And Nedo, another Japanese company, announced its plans for developing new car batteries in February 2007. In Korea, LG also set hand on the development of high-power polymer Li-ion batteries, and has already released two models, which are 6Ah-144Wh/kg and 10Ah-158Wh/kg. The U.S. Department of Energy also supports the development of the third-generation power Li-ion batteries, while French SAFT has developed two models of high-power Li-ion batteries, with a specific power output of 500W/kg and 350W/kg.

Although the Li-ion battery industry started later in China than in Japan, it has been growing quickly, and much funding has gone into research and development of power Li-ion batteries. For instance, Electric Vehicles are a major part of China’s 863 Project, in which the Institute of Physics (of Chinese Academy of Sciences), Beijing Research Institute of Nonferrous Metals, the 18th Research Institute of China Electronics Technology Group Corporation, and other organizations have participated. The batteries would be for both EV and HEV, and some participants adopted manganese compounds as the active cathode materials for the batteries.

While detailing the supply and demand, niche markets, application market and other aspects of China’s Power Li-ion battery industry, this report compares the performance of the products and the operational performance of China’s major Power Li-ion battery producers. In addition, this report forecasts the development trend of the country’s Power Li-ion battery industry and analyzes the opportunities and risk as an investment.

Table of Contents:

Chapter One: General
1.1 Definition of Power Li-ion Battery
1.2 Structure and Advantages of Power Li-ion Battery
1.3 Problems to Overcome for Power Li-ion Battery

Chapter Two: Development of Power Battery in China
2.1 Lead-Acid Battery
2.1.1 Introduction to and Category of Lead-Acid Battery
2.1.2 Size of Global Lead-Acid Battery Market
2.1.3 Production, Consumption and Export of Lead-Acid Battery in China
2.1.4 Major Producers of Lead-Acid Battery in China
2.1.5 Prospect of China’s Lead-Acid Battery Market
2.2 Nickel-Metal Hydride Battery
2.2.1 Introduction
2.2.2 Production and Export in China
2.2.3 Major Producers in China
2.2.3 Trend of Major Technologies
2.3 Nickel-Cadmium Battery
2.4 Fuel Battery
2.5 Other Battery

Chapter Three: Application Markets of Power Li-ion Battery in China
3.1 General
3.2 Electric Bicycle
3.2.1 Status Quo of Electric Bicycle Industry in China
3.2.2 Application of and Forecast for Power Li-ion Battery in Electric Bicycle Industry
3.2.1.1 Status Quo and Prospects for Application of Power Li-ion Batteries in Global Electric Bicycle Industry
3.2.1.2 Status Quo and Prospects for Application of Power Li-ion Batteries in China’s Electric Bicycle Industry
3.3 Electric Tools
3.3.1 Development of China’s Electric Tool Market
3.3.2 Status Quo and Prospects for Application of Power Li-ion Battery in the Electric Tool Industry
3.4 Electric Vehicles
3.4.1 Development of Electric Vehicle Market
3.4.1.1 Pure Electric Vehicles
3.4.1.2 Hybrid Electric Vehicles
3.4.2 Status Quo and Prospects for Application of Power Li-ion Battery in Electric Vehicle Industry
3.4.2.1 Comparison of Major Batteries for Electric Vehicles
3.4.2.2 Status Quo and Prospects for Application of Power Li-ion Battery in Global Electric Vehicle Industry
3.4.2.3 Status Quo and Prospects for Application of Power Li-ion Battery in China’s Electric Vehicle Industry
3.5 Electric Toys
3.6 Other Application Fields for Power Li-ion Battery
3.6.1 Power Source for Miner’s Lamps
3.6.2 Uninterrupted Power Supply
3.6.3 Batteries for Communications Devices
3.6.4 Storage Batteries for New Energy Sources
3.6.5 Application in Aerospace Field
3.6.6 Application in Military Field
3.6.7 Application in Other Fields

Chapter Four: Market of Key Materials for Power Li-ion Battery
4.1 LiCoO2
4.1.1 Competition in LiCoO2 Market
4.1.2 Outlook of LiCoO2 Market
4.1.3 Trend of Competition in LiCoO2 Market
4.2 LiMnO2
4.2.1 Competition in LiMnO2 Market
4.2.2 Outlook of LiMnO2 Market
4.3 LiFePO4
4.3.1 Competition in LiFePO4 Market
4.3.2 Outlook of LiFePO4 Market

Chapter Five: Major Producers of Power Li-ion Battery in China
5.1 Suzhou Phylion Battery Co., Ltd.
5.1.1 Company Profile
5.1.2 Power Li-ion Battery Portfolio
5.2 Shenzhen Thunder Sky Energy Group Limited
5.2.1 Company Profile
5.2.2 Power Li-ion Battery Portfolio
5.3 Henan Huanyu Power Source Company Ltd.
5.3.1 Company Profile
5.3.2 Power Li-ion Battery Portfolio
5.4 Qingdao Aucma Newpower Technology
5.4.1 Company Profile
5.4.2 Power Li-ion Battery Portfolio
5.5 Wuhan Lixun Power Corp. Ltd.
5.5.1 Company Profile
5.5.2 Power Li-ion Battery Portfolio
5.6 Shenzhen B&K Li-ion Battery Co., Ltd.
5.6.1 Company Profile
5.6.2 Power Li-ion Battery Portfolio
5.7 Wangxiang EV Co., Ltd.
5.7.1 Company Profile
5.7.2 Power Li-ion Battery Portfolio
5.8 YOKU Energy Technology Co., Ltd.
5.8.1 Company Profile
5.8.2 Power Li-ion Battery Portfolio
5.9 Powerlong Group
5.9.1 Company Profile
5.9.2 Power Li-ion Battery Portfolio
5.10 Advanced Battery Technologies, Inc.
5.10.1 Company Profile
5.10.2 Power Li-ion Battery Portfolio
5.11 Shenzhen Herewin Technology Co., Ltd.
5.11.1 Company Profile
5.11.2 Power Li-ion Battery Portfolio
5.12 Tianjin Lishen Battery Joint-Stock Co. Ltd.
5.12.1 Company Profile
5.12.2 Power Li-ion Battery Portfolio
5.13 CITIC Guoan Mengguli
5.13.1 Company Profile
5.13.2 Power Li-ion Battery Portfolio
5.14 TCL Hyperpower Batteries Inc.
5.14.1 Company Profile
5.14.2 Power Li-ion Battery Portfolio
5.15 Beijing China Powerel Battery Co., Ltd.
5.15.1 Company Profile
5.15.2 Power Li-ion Battery Portfolio
5.16 Zhejiang Xinghai Energy Technology Co., Ltd.
5.16.1 Company Profile
5.16.2 Power Li-ion Battery Portfolio
5.17 Shanxi Guangyu Power Sources Co., Ltd.
5.17.1 Company Profile
5.17.2 Power Li-ion Battery Portfolio
5.18 Tianjin HangLiYuan Science and Technology Ltd.
5.18.1 Company Profile
5.18.2 Power Li-ion Battery Portfolio
5.19 Suzhou DNT Energy Technology Co., Ltd.
5.19.1 Company Profile
5.19.2 Power Li-ion Battery Portfolio
5.20 Shuang Yi Li (Tianjin) New Energy Co., Ltd.
5.20.1 Company Profile
5.20.2 Power Li-ion Battery Portfolio
5.21 Shenzhen XKTD Li-ion Polymer Batteries
5.21.1 Company Profile
5.21.2 Power Li-ion Battery Portfolio
5.22 Meiya Energy Sources (Jiangxi) Co., Ltd.
5.2.1 Company Profile
5.22.2 Power Li-ion Battery Portfolio
5.23 Tianjin Bluesky Double-Cycle Tech. Co., Ltd.
5.23.1 Company Profile
5.23.2 Power Li-ion Battery Portfolio
5.24 Xinxiang Zhongke Science & Technology Co., Ltd.
5.24.1 Company Profile
5.24.2 Power Li-ion Battery Portfolio
5.25 Harbin Coslight Power Co., Ltd.
5.25.1 Company Profile
5.25.2 Power Li-ion Battery Portfolio
5.26 Shenzhen HYB Battery Co., Ltd.
5.26.1 Company Profile
5.26.2 Power Li-ion Battery Portfolio
5.27 Shenzhen BYD Co., Ltd.
5.27.1 Company Profile
5.27.2 Power Li-ion Battery Portfolio
5.28 Hunan Haixing High-tech Power Battery Co., Ltd.
5.28.1 Company Profile
5.28.2 Power Li-ion Battery Portfolio
5.29 Shenzhen DLG Battery Co., Ltd.
5.29.1 Company Profile
5.29.2 Power Li-ion Battery Portfolio
5.30 Bak Power International (Tianjin) Co., Ltd.
5.30.1 Company Profile
5.30.2 Power Li-ion Battery Portfolio

Chapter Six: Investing in China’s Power Li-ion Battery Industry
6.1 Status Quo of Investment
6.2 Investment Opportunities
6.3 Investment Risks
6.4 Investment Advices
 

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As for the layout of global Li-ion battery production, Japan, South Korea and China’s manufacturers hold the dominant position. Technologically, Japanese enterprises are still in a leading position with a relatively higher degree of equipment automatization. While both China and South Korea assimilate and improve the equipments and technologies after they have been introduced from Japan.
 
In the past 10 years, China’s Li-ion battery industry has risen gradually to replace Japan and the U.S. to become the world’s Li-ion battery manufacturing base. By 2008, China’s production of Li-ion battery had accounted for 41% of the global market; While its export value had reached USD 2.6 billion, which represented about 50% of the total export of various kinds of batteries in China. China has become the world’s second largest Li-ion battery production and export country.
 
This report mainly discussed the global and Chinese Li-ion battery market from the following aspects:
 
- Take a close look at the competitiveness landscape of global Li-ion battery market.
- Developing status in Japan, South Korea and China is provided.
- Production capacity, operation performance etc. of major Li-ion battery manufacturers is presented.
- Status quo and developing trend of major application markets are examined in detail.
- Status quo and developing trend of major raw materials markets are expatiated upon.
- Investment opportunities and risks are analyzed elaborately. Case study is also offered.
 

Table of Contents: 

Chapter One: Overview of the Development of Li-ion Battery
1.1 Development History of Li-ion Battery
1.2 Classification of Li-ion Battery
1.3 Main Materials of Li-ion Battery
 
Chapter Two: Analysis of Global Li-ion Battery Industry Structure
2.1 Overview of Global Li-ion Battery Market
2.2 Japan
2.3 South Korea
2.4 China
 
Chapter Three Development of China’s Li-ion Battery Industry
3.1 Production Capacity
3.1.1 Production Scale
3.1.2 Distribution of Production Capacity
3.2 Market Demand
3.3 Imports and Exports
3.3.1 Imports
3.3.2 Exports
3.4 Major issues
3.4.1 Issues Concerning with Market
3.4.2 The Issue in Specifications
3.4.3 The issue in Products
 
Chapter Four: Analysis of Major Manufacturers
4.1 Japanese Enterprises
4.1.1 Sanyo Electric
4.1.2 Sony
4.2 South Korea Enterprises
4.2.1 Samsung SDI
4.2.2 LG Chemicals and Other Manufacturers
4.3 Chinese Enterprises
4.3.1 Shenzhen BYD
4.3.2 Shenzhen BAK
4.3.3 Tianjin Lishen
 
Chapter Five: Analysis and Prediction of the Development of Li-ion Battery Application Markets in China
5.1 Mobile Phone
5.1.1 Current Status
5.1.1 Current Development of Mobile Phone Li-ion Battery in China
5.1.2 Development Trend of China’s Mobile Phone Li-ion Battery Industry
5.2 Laptop Computer
5.2.1 Current Status of Global Laptop Li-ion Battery Market
5.2.2 Laptop Li-ion Battery Market in China
5.2.3 Competition Landscape of in Laptop Li-ion Battery Industry
5.2.4 Development Trend of Laptop Li-ion Battery
5.3 Electric Bicycle
5.4 Electric Automobiles and Other Fields
 
Chapter Six: Analysis of Raw Material Market of Li-ion Batteries
6.1 Cathode Material Market
6.1.1 Status Quo of Global Cathode Material Market
6.1.2 Status Quo of Cathode Materials in China
6.1.3 Prospect of Chinese Cathode Material Market
6.2 Anode Material Market
6.2.1 Status Quo of Global Anode Material Industry
6.2.2 Status Quo of Anode Material Industry in China
6.3 Li-ion Battery Separator Paper
6.3.1 Status Quo of Global Separator Paper Industry
6.3.2 Research and Production Development of Separator Paper in China
6.3.3 Market Prospects of Separator Papers
6.4 Electrolyte Market
6.5 PVDF Market
 
Chapter Seven: Analysis on Investment into Li-ion Battery and Its Material Market
7.1 Analysis on Investment into Li-ion Batteries
7.1.1 Analysis on Investment Opportunities
7.1.2 Analysis on Investment Key Points
7.1.3 Investment Risks
7.1.4 Case Study of Investment
7.2 Analysis on Li-ion Battery Material Investment
7.2.1 Analysis on Investment Opportunities
7.2.2 Investment Case Study
7.2.2.1 Anode Materials
7.2.2.2 Cathode Materials
 
Chapter Eight: Executive Summary

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Business Monitor International’s Chile Commercial Banking Report provides industry professionals and strategists, corporate analysts, banking associations, government departments and regulatory bodies with independent forecasts and competitive intelligence on the Commercial Banking industry in Chile.

The Report has just been researched at source, and features latest-available data covering production, sales, imports and exports; 5-year industry forecasts through end-; company ranking and competitive landscapes for multinational and local manufacturers and suppliers; and analysis of latest industry developments, trends and regulatory changes.

Key Benefits of Report
Rely On Our Independent 5-Year Forecasts As A Benchmark
to test other views - a key input for successful budgetary and strategic business planning.
Target Business Opportunities & Risks
through our reviews of latest industry trends, regulatory changes, and major deals, projects and investments.
Exploit Latest Competitive Intelligence & Company SWOTS
on your peers and competitors through company rankings by sales, market share, investments and leading products and services.

Chile Commercial Banking Report includes:

Executive Summary & Swot Analysis
Summary of BMI’s key industry forecasts and trend analysis, and commentary on key company and industry headline events. Collection of SWOT studies on local commercial banking market, economy and business environment.

Regional Overview
Cross-border analysis on the structure, size and value of the commercial banking sector, including comparative historical data and forecasts on the region’s assets, loans and deposits, as well as bond portfolios.

Market Overview
Outlook of local market, commenting on its structure, size and value.

BMI 5-Year Industry Forecast
Annual average growth forecasts for assets, loans and deposits.

BMI 5-Year Macroeconomic Forecast
BMI forecasts for all headline macroeconomic indicators, including real GDP growth, inflation, fiscal balance, trade balance, current account and external debt.

Competitive Landscape
Comparative company analyses and rankings by production, sales, % market share, employees, registration date and ownership structure.

Company Profiles & SWOTS
Company profiles, including SWOT (Strengths, Weaknesses, Opportunities & Threats)analyses, fully researched senior executives and full contact details, business activity, leading products and services.

Executive Summary

The real macroeconomic effects of the global credit crunch have already begun to play out in Chile and we expect a continuation of this well into 2009. Collapsing global copper prices have seen Chilean exports fall by a staggering 24.4% year-on-year (y-o-y) in December, marking the largest drop in exports in a single month in over a decade. Chile’s trade surplus almost halved, to US$12.9bn from US$23.7bn, in 2007 on the back of anaemic export growth. Chile relies heavily on raw material exports and as such is vulnerable to the economic slowdown .The banking system will be particularly hard hit with asset and credit growth likely to fall both on the back of rising external borrowing costs and declining domestic demand for new loans. That said, we do stress that currently we are not forecasting a recession in Chile and the banking system in not expected to have a systemic crisis. As such, over a multi-year time horizon, we retain our view that Chile will be in a better position to recover.

This report is being written at a time when the global financial crisis – which arose as a result of the evaporation of inter-bank liquidity – has moved into a new phase. Stock market participants appear – reasonably – to have taken the view that the policy responses taken by governments, central banks and multi-lateral institutions will be sufficient to prevent a total collapse of the global financial system. Instead, stock market participants are focusing on the impact of a near-global recession on the earnings of non-financial companies.

Table of Contents :

Chapter - Executive Summary
Table: Levels (CLPbn)
Table: Levels (US$bn)
Table: Levels At December 31 2007
Table: Annual Growth Rate Projections, 2007-2012 (%)
Table: Ranking Out Of 59 Countries Reviewed In Q208
Table: Projected Levels, 2007-2012 (CLPbn)
Table: Projected Levels, 2007-2012 (US$bn)
Chapter - Key Issues
Changes To The Commercial Banking Report
The Global Financial Crisis – Continued
Table: Selected European Countries – Projected Budget And Current Account, 2008 (as % of GDP)
New Information From Q209
Chile Commercial Banking SWOT
Chapter - Commercial Banking Business Environment Rating
Table: Chile’s Commercial Banking Business Environment Ratings
Table: Latin America’s Commercial Banking Business Environment Ratings
Chapter - Bank Lending
Table: Lending Overview, 2006 And 2007 (CLPbn)
Total Assets, Client Loans And Client Deposits
Table: Comparison Of Total Assets, Client Loans And Client Deposits (US$bn)
Per-Capita Deposits
Table: Comparison Of Per-Capita Deposits, Late 2007 (US$)
Chapter - Country Outlook
Macroeconomic Forecasts
Table: Chile – Economic Activity
Political Outlook
Table: Political Overview Of Chile
Chapter - Industry Forecast Scenario
Table: Annual Growth Rate Projections, 2007-2012 (%)
Table: Projected Levels, 2007-2012 (CLPbn)
Table: Projected Levels, 2007-2012 (US$bn)
Comment On Developments Over Last Year
Comment On Forecasts
Comment On Trends And Ratios
Table: Comparison Of Loan/Deposit, Loan/Asset And Loan/GDP Ratios, Late 2007/Early 2008
Chapter - Banks’ Bond Portfolios
Table: Bond Portfolios, Late 2007
Chapter - Competitive Landscape And Protagonists
Country Snapshot: Chile Demographic Data
Section 1: Population
Table: Demographic Indicators, 2005-2030
Table: Rural/Urban Breakdown, 2005-2030
Section 2: Education And Healthcare
Table: Education, 2002-2005
Table: Vital Statistics, 2005-2030
Section 3: Labour Market And Spending Power
Table: Employment Indicators, 2001-2006
Table: Consumer Expenditure, 2000-2012 (US$)
Table: Average Annual Wages, 2000-2012
Chapter - Methodology
Basis Of Projections
Commercial Bank Business Environment Rating
Table: Commercial Banking Business Environment Indicators And Rationale
Table: Weighting Of Indicators

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This comprehensive report, updated and revised in March 2009 to take into account the global economic situation, gives a thorough analysis of printed and thin film photovoltaics and batteries, with 10 year forecasts to 2019. Included are detailed profiles of 48 companies working on the many different types of technologies.

Report covering all aspects of the new photovoltaics
This comprehensive report, updated and revised in March 2009 to take into account the global economic situation, gives a thorough analysis of printed and thin film photovoltaics and batteries, with 10 year forecasts to 2019. Included are detailed profiles of 48 companies working on the many different types of technologies.

The report covers companies, research institutes and universities that are active in developing and commercializing thin film technologies for photovoltaics and batteries. Photovoltaic technologies covered include CIGS, CdTe, DSSC, a-Si and organic photovoltaics. Learn how these technologies (each at a different stage of development and adoption) are driven forward by both government and leading companies in the field.

The report also describes materials (both organic and inorganic) and device structures as well as various high-speed printing technologies employed.

IDTechEx find that the market for thin film inorganic photovoltaic technologies beyond crystalline silicon will reach at least $20 billion in 2014. The global solar energy market is expected to reach $34 billion in 2010 and $100 billion in 2050 and most of that latter figure is expected to be achieved by non-silicon photovoltaics.

Along with other manufacturing techniques, printing (or printing-like) technologies are gradually being adopted (Nanosolar, G24 Innovations in the PV sector, Power Paper, Solicore and Thin Battery technology in the batteries sector), as they can be considered to be some of the fastest, least expensive and highest volume manufacturing techniques. With printed electronics becoming more prevalent, there is an increasing need for power to supply them; printing is amenable to a large number of different types of devices with the possibility of integration (e.g. to provide onboard power etc.)

This report provides a comprehensive list of key companies that are active in each of the thin film photovoltaic and battery technologies. Compiled and analyzed by Dr Harry Zervos, technology analyst with IDTechEx, company profiles are given along with 20 year forecasts for the growth of the market share of these technologies. Dr Bruce Kahn, consultant and academic, gives a thorough analysis of the science and technology behind thin film photovoltaics and batteries, as well as a comparison of different high-speed printing techniques.

New Technologies Emerging
Silicon photocells are seen in many places but the technology is limited. Crystalline silicon will never give tightly rollable devices let alone transparent ones or even low cost power generation on flexible substrates.

Fortunately there are many new alternatives. Proprietary nano-particle silicon printing processes are developed by companies such as Innovalight and Kovio and it promises many of the photovoltaic features that conventional silicon can never achieve. It can be printed reel to reel on stainless steel or other high temperature substrates.

However, most of the work on the next generation of photovoltaics is directed at printing onto low cost flexible polymer film and ultimately on common packaging materials. The main contenders are currently:
CIGS
CdTe
DSSC
Organic Photovoltaics

Several companies, universities and research institutes are hard at work in different development stages of these technologies with large scale plants being built across the globe.

Table of Contents:

EXECUTIVE SUMMARY
2. INTRODUCTION AND SCOPE
3. BATTERIES
3.1. Introduction
3.2. History
3.3. Structure
3.4. Key Products in Printed Batteries Industry
3.5. Principles and Operation
3.6. Supercapacitors supplement or rival batteries?
3.7. Thin Film Batteries - key companies
3.7.1. Power Paper
3.7.2. Thin Battery Technologies Inc.
3.7.3. Enfucell
3.7.4. Cymbet Corporation
3.7.5. Solicore
3.7.6. Infinite Power Solutions (IPS)
3.7.7. Excellatron
4. PHOTOVOLTAICS
4.1. Introduction
4.2. History
5. COMPANY PROFILES BY TECHNOLOGY
5.1. Principles and operations
5.2. Amorphous/nanoparticle Si
5.2.1. Introduction-Brief Description of technology
5.3. Amorphous /nanoparticle Si - Key Companies
5.3.1. Sharp
5.3.2. United Solar Ovonics
5.3.3. Mitsubishi Heavy industries
5.3.4. Kaneka
5.3.5. Q-cells (SONTOR and VHF-Technologies SA)
5.3.6. Fuji Electric Systems Co., Ltd.
5.3.7. ersol Solar Energy AG
5.3.8. Innovalight
5.4. CdTe
5.4.1. Introduction-Brief Description of technology
5.5. CdTe Key Companies
5.5.1. First Solar
5.5.2. Calyxo
5.5.3. AVA Solar
5.5.4. PrimeStar Solar
5.5.5. Matsushita Battery Industrial Co., Ltd.
5.6. CIGS - CIS
5.6.1. Introduction-Brief Description of technology
5.7. CIGS - Key Companies
1. EXECUTIVE SUMMARY
2. INTRODUCTION AND SCOPE
3. BATTERIES
3.1. Introduction
3.2. History
3.3. Structure
3.4. Key Products in Printed Batteries Industry
3.5. Principles and Operation
3.6. Supercapacitors supplement or rival batteries?
3.7. Thin Film Batteries - key companies
3.7.1. Power Paper
3.7.2. Blue Spark Technologies Inc.
3.7.3. Enfucell
3.7.4. Cymbet Corporation
3.7.5. Solicore
3.7.6. Infinite Power Solutions (IPS)
3.7.7. Excellatron
3.7.8. Nanotecture
4. PHOTOVOLTAICS
4.1. Introduction
4.2. History
5. COMPANY PROFILES BY TECHNOLOGY
5.1. Principles and operations
5.2. Amorphous/nanoparticle Si
5.2.1. Introduction-Brief Description of technology
5.3. Amorphous /nanoparticle Si - Key Companies
5.3.1. Sharp
5.3.2. United Solar Ovonic
5.3.3. Mitsubishi Heavy industries
5.3.4. Kaneka
5.3.5. Q-cells (SONTOR and VHF-Technologies SA)
5.3.6. Fuji Electric Systems Co., Ltd.
5.3.7. ersol Solar Energy AG
5.3.8. Innovalight
5.4. CdTe
5.4.1. Introduction-Brief Description of technology
5.5. CdTe Key Companies
5.5.1. First Solar
5.5.2. Calyxo
5.5.3. Abound Solar
5.5.4. PrimeStar Solar
5.6. CIGS - CIS
5.6.1. Introduction-Brief Description of technology
5.7. CIGS - Key Companies
5.7.1. Ascent Solar Technologies, Inc.
5.7.2. Avancis
5.7.3. DayStar Technologies
5.7.4. Global Solar Energy
5.7.5. HelioVolt
5.7.6. Honda Soltec Co., Ltd.
5.7.7. Johanna Solar Technology
5.7.8. Miasolé
5.7.9. Nanosolar
5.7.10. Odersun
5.7.11. Showa Shell Sekiyu
5.7.12. Solibro
5.7.13. Solyndra
5.7.14. Sulfurcell
5.7.15. Würth Solar
5.8. DSSC
5.8.1. Introduction-Brief Description of technology
5.9. DSSC - Key Companies
5.9.1. G24 Innovations
5.9.2. Dyesol
5.10. Organic Photovoltaics
5.10.1. Introduction - Brief Description of technology
5.11. Organic Photovoltaics - Key Companies
5.11.1. Konarka
5.11.2. Plextronics
5.11.3. Solarmer
5.11.4. Heliatek
5.12. Research Institutes/Universities involved with thin film photovoltaic technologies
5.12.1. AIST - National Institute of Advanced Industrial Science and Technology
5.12.2. Arizona State University
5.12.3. Colorado State University
5.12.4. École Polytechnique Fédérale de Lausanne
5.12.5. Florida Solar Energy Centre
5.12.6. Fraunhofer ISE
5.12.7. Helsinki University of technology (TKK)
5.12.8. IMEC
5.12.9. Imperial College London
5.12.10. Idaho National Laboratory (INL)
5.12.11. KAIST - Korean Advanced Institute of Science and Technology
5.12.12. Lawrence Berkeley National Laboratory
5.12.13. Massachusetts Institute of Technology (MIT)
5.12.14. National Renewable Energy Laboratory (NREL)
5.12.15. University of Delaware - Institute of Energy Conversion (IEC)
6. APPLICATIONS
6.1. Applications of printed batteries
6.2. Batteries
6.2.1. Radio Frequency Identification (RFID)
6.2.2. Smart Cards
6.2.3. Iontophoretic Devices
6.2.4. Other Devices
6.3. Photovoltaics
6.3.1. Building integrated solar electric power
6.3.2. Solar Chargers
6.3.3. Military applications
6.3.4. Other applications
7. FUTURE TRENDS AND FORECASTS FOR PRINTING TECHNOLOGIES
APPENDIX 1: PRINCIPLES AND OPERATION OF DSSCS AND ORGANIC SOLAR CELLS
APPENDIX 2: MATERIALS
APPENDIX 3: PRINTING/PATTERNING TECHNIQUES
APPENDIX 4: IDTECHEX PUBLICATIONS AND CONSULTANCY
TABLES
2.1. Market size for thin film photovoltaic technologies beyond silicon technologies % of the market that is printed and flexible
2.2. Market size for thin film batteries % of the market that is printed and flexible
3.1. Important milestones in battery history
3.2. Printed battery product and specification comparison
3.3. Printed battery materials comparison.
3.4. The half cell and overall chemical reactions that occur in a Zn/MnO2 battery
3.5. Discharge rate, current, and load.
3.6. Parameter ranking for different battery chemistries
3.7. Battery characteristics
4.1. Comparison of the power conversion technologies of different types of solar cell technologies
4.2. Important milestones in the development of photovoltaic cells
6.1. Applications of printed batteries by vendor
6.2. Technical differences between Active and Passive RFID technologies
6.3. Summary of functional capabilities of Active and Passive RFID technologies
6.4. Some of the manufacturers that provide printed batteries for smart card applications
7.1. Market size for thin film photovoltaic technologies beyond silicon technologies % of the market that is printed and flexible
7.2. Market size for thin film batteries % of the market that is printed and flexible
FIGURES
3.1. Internal structure of Power Paper Battery.
3.2. Diagram of the operation of a battery
3.3. Discharge characteristics of a Power Paper STD-3 printed battery
3.4. Enfucell SoftBattery;
3.5. The Cymbet EnerChip;
3.6. Flexion;
3.7. LiTE;STAR;.
3.8. Thin-film solid-state batteries by Excellatron
4.1. Average Potential electricity production with photovoltaics
4.2. Worldwide PV Shipments 1988-2004
4.3. Progress of confirmed research-scale photovoltaic device efficiencies, under AM 1.5 simulated solar illumination, for a variety of technologies
4.4. Progress in power conversion efficiency for a-Si, polymer, and small molecule photovoltaic cells
4.5. Comparison of the efficiency (in arbitrary units, since no spectral mismatch correction was performed) of “printed like” (doctor bladed) vs. spin-coated organic solar cells
5.1. Typical a-Si p-i-n design
5.2. a-Si hydrogenation
5.3. United Solar Ovonics thin film amorphous silicon cell configuration
5.4. Kaneka semi-translucent PV module
5.5. FES F-WAVE
5.6. Innovalight Cell
5.7. CdTe thin film solar cell
5.8. Schematic representation of a CIGS thin film solar cell
5.9. Ascent Solar’s Flexible Products
5.10. Honda Soltec’s manufacturing facility
5.11. Model and design of Johanna Solar’s production facility in Brandenburg
5.12. Parts of Nanosolar’s module manufacturing process
5.13. The POGO designer bag produced by Berlin manufacturer Bagjack
5.14. Würth Solar’s production plant, CISfab in Schwäbisch Hall
5.15. Dyesol’s Dye Solar Cells interconnected and integrated into modules (tiles).
5.16. Konarka’s Power Plastic®
5.17. The Tsukuba Center Solar Power Plant
5.18. Transparent dye solar module manufactured at Fraunhofer ISE with a screen printing procedure using glass frit technology.
5.19. Schematic layer structure of a pentacene-C60 tandem organic solar cell
6.1. Patents containing the terms RFID and Battery
6.2. Active RFID patents
6.3. Schematic diagram of PowerCosmetics Micro-electronic patch
6.4. Estee Lauder Perfectionist Power Correcting Patch
6.5. Anti-wrinkle demonstration
6.6. Audio paper capable of recording and playing back audio
6.7. Hasbro Thin-Tronix ; Poster Phone and Poster Radio
6.8. PowerFilm AA Charger
6.9. Two wire photovoltaic fiber concept
For more information kindly visit: http://www.bharatbook.com/Market-Research-Reports/Thin-Film-Photovoltaics-and-Batteries.html

New technologies call for different forms of battery
Electronics and electrics are becoming ubiquitous, the devices appearing on and in higher and higher volume products including e-labels and e-packaging. This calls for different forms of battery, capacitor and other energy storage because priorities such as environmental credentials, thinness and compatibility with energy harvesting (eg solar cells) come to the fore alongside life and cost. This unique new report is directed towards those developing, marketing and using the new small electronic and electrical devices, particularly those that are self-sufficient. It will also interest those investing in new battery, capacitor and allied companies providing products for these markets and those regulating and supporting these burgeoning industries. To this end, the report is almost devoid of equations but it is replete with summary diagrams and tables, pros and cons, company profiles, new products and applications beyond the familiar ones. There is therefore much to interest those with a technical background as well. The report looks hard at what comes next, particularly over the next ten years.

Designed for a broad range of readers
We use relatively simple language so the report can be useful to as broad a range of readers as possible, enhanced by a glossary. After all, investors, government regulators, journalists and many other people have a great interest in the imminent huge deployment of small self-powered electronic and electrical devices. It will eventually reach hundreds of billions of products yearly, including electronically enhanced drug packs, magazines, disposable medical testers and much more besides. For the more technical, there are many new summary tables and diagrams comparing parameters required and achieved. The parameters, including costs, and the applications are compared and the work of many suppliers is evaluated. No other report on this subject is as broad ranging or up to date. The main emphasis is on what will needed and possible, not on rehearsing the story of traditional cylindrical, laptop and mobile phone batteries. Here we see the future.

Largest mobile energy storage market today
Energy storage for small devices, the subject of this report, forms by far the largest mobile energy storage market today, being much larger and faster growing than the market for heavy energy storage such as automotive and enjoying greater innovation for the future, including transparent and printed batteries. The report mainly concentrates on batteries and capacitors - including the rapid adoption of supercapacitors and hybrids of the two. It explains how they are constructed, how they work and the pros and cons. However, it also touches on the elusive small fuel cells and other options. Focussing on use in small devices, we forecast the market for both single use and rechargeable batteries by numbers and value from 2009-2019 and the market size for supercapacitors, tracking a return to rapid growth from 2010, after the global financial meltdown ends. The market drivers are given as they change over the years. We evaluate the limitations of current devices against what will be needed and what can be done. For example, as the traditional parameters of batteries and capacitors are painfully and slowly improved, some completely different improvements are proving exciting because they can open up completely new markets. These include transparent, edible, stretchable, woven, stitchable, implantable, biodegradable and wide area versions more suited to the world of ubiquitous electronics that is arriving. As wall decoration, windows, apparel, books, posters, consumer goods, pharmaceutical packaging , the sensing skin of an aircraft and the inside of a car and much more become electronic and local harvesting of power becomes commonplace, these are the products we need. We describe the remarkable new approaches including batteries assembled using viruses and carbon nanotubes, biomimetic and magnetic spin batteries and ones that can harvest energy in the human body. Then there are batteries and supercapabatteries only one tenth of a millimeter thick. Which are the most exciting developers and what will be available when? It is all here.

Table of Contents:

EXECUTIVE SUMMARY AND CONCLUSIONS
1. INTRODUCTION
1.1. Small electrical and electronic devices
1.2. What is a battery?
1.2.1. Battery definition
1.2.2. Battery history
1.2.3. Analogy to a container of liquid
1.2.4. Construction of a battery
1.2.5. Many shapes of battery
1.2.6. Single use vs rechargeable batteries
1.2.7. Challenges with batteries in small devices
1.3. What is a capacitor?
1.3.1. Capacitor definition
1.3.2. Capacitor history
1.3.3. Analogy to a spring
1.3.4. Capacitor construction
1.4. Limitations of energy storage devices
1.4.1. The electronic device and its immediate support
1.4.2. Safety
1.4.3. Improvement in performance taking place
1.5. Standards
2. RECHARGEABLE BATTERIES
2.1. Technology successes and failures
2.2. Lithium polymer vs lithium ion
2.3. New shapes - laminar and flexible batteries
2.3.1. Laminar lithium batteries
2.3.2. Ultrathin battery from Front Edge Technology
2.4. Transparent battery - NEC and Waseda University
2.5. New methods of charging
2.6. Technology Challenges
2.7. Threat to lithium prices?
2.8. New applications for new laminar rechargeable batteries
3. SINGLE USE BATTERIES
3.1. Tadiran Batteries twenty year batteries
3.2. Laminar printed manganese dioxide batteries
3.2.1. Printed battery construction
3.2.2. Printed battery production facilities
3.2.3. Applications of printed batteries
3.2.4. Printed battery specifications
3.3. Other emerging needs for laminar batteries - apparel and medical
3.3.1. Electronic apparel
3.3.2. Wireless body area network
3.4. Nanotube flexible battery
3.5. Biobatteries do their own harvesting
3.6. Microbatteries built with viruses
3.7. Biomimetic energy storage system
3.8. Magnetic spin battery
4. CAPACITORS AND SUPERCAPACITORS
4.2. Example of capacitor storage application - e-labels
4.3. Many shapes of capacitor
4.4. Capacitors for small devices
4.5. Technology of capacitors
4.5.1. Technology of non-polar capacitors
4.5.2. Technology of the electrolytic capacitor
4.5.3. Development path
4.6. Aluminum electrolytic capacitors
4.6.2. High capacitance but at a price
4.6.3. Non-polar electrolytic
4.6.4. Safety issues
4.6.5. Polarity
4.6.6. The dielectric is fragile
4.6.7. Electrolyte
4.7. Tantalum electrolytic capacitors
5. SUPERCAPACITORS = ULTRACAPACITORS
5.1. Where supercapacitors fit in
5.2. Advantages and disadvantages
5.3. How it all began
5.4. Applications
5.5. Uses in small devices.
5.6. Relevance to energy harvesting
5.6.1. Perpetuum harvester
5.6.2. Human power to recharge portable electronics
5.6.3. Use in nanoelectronics
5.7. Can supercapacitors replace capacitors?
5.8. Can supercapacitors replace batteries?
5.9. Electric vehicle demonstrations and adoption
5.10. How an ELDC supercapacitor works
5.10.1. Basic geometry
5.10.2. Properties of EDL
5.10.3. Charging
5.10.4. Discharging and cycling
5.10.5. Energy density
5.10.6. Achieving higher voltages
5.11. Improvements coming along
5.11.1. Better electrodes
5.11.2. Better electrolytes
5.11.3. Better carbon technologies
5.11.4. Carbon nanotubes
5.11.5. Carbon aerogel
5.11.6. Solid activated carbon
5.11.7. Carbon derived carbon
5.11.8. Graphene
5.11.9. Polyacenes or polypyrrole
5.12. Supercapacitor performance without EDL - EEstor
5.13. Supercabatteries or bacitors
6. FUEL CELLS AND OTHER ALTERNATIVES
6.1. Fuel cells
6.2. New forms of miniature fuel cells
6.2.1. Microbial fuel cells
6.2.2. Lightweight hydrogen generating fuel cell
6.2.3. Biomimetic approach with MIT fuel cell
6.3. Mechanical storage
7. ORGANISATION PROFILES
7.1. Blue Spark Technologies USA
7.2. Cap-XX Australia
7.3. Celxpert Energy Corp. Taiwan Head Quarter
7.4. Cymbet USA
7.5. Duracell USA
7.6. Enfucell Finland
7.7. Excellatron USA
7.8. Freeplay Foundation UK
7.9. Front Edge Technology USA
7.10. Frontier Carbon Corporation Japan
7.11. Harvard University USA
7.12. Hitachi Maxell
7.13. Holst Centre Netherlands
7.14. Infinite Power Solutions USA
7.15. Institute of Bioengineering and Nanotechnology Singapore
7.16. Lebônê Solutions South Africa
7.17. Massachusetts Institute of Technology USA
7.18. Matsushita Battery Industrial Company Ltd.
7.19. Maxwell Technologies Inc., USA
7.20. Nanotecture, UK
7.21. National Renewable Energy Laboratory USA
7.22. NEC Japan
7.23. Nippon Chemi-Con Japan
7.24. Oak Ridge National Laboratory USA
7.25. Planar Energy Devices USA
7.26. Power Paper Israel
7.27. Prelonic Technologies
7.28. Renata Batteries
7.29. ReVolt Technologies Ltd
7.30. Sandia National Laboratory USA
7.31. Solicore USA
7.32. Tadiran Batteries
7.33. Technical University of Berlin Germany
7.34. Sony Japan
7.35. University of California Los Angeles USA
7.36. University of Michigan USA
7.37. University of Sheffield UK
7.38. University of Wollongong Australia
7.39. Waseda University
8. MARKETS AND FORECASTS
8.1. Market for batteries, supercapacitors, other
8.2. Total global battery market
8.3. Global battery market by use
8.3.1. Batteries for RFID
8.3.2. Batteries for gift cards
8.3.3. Batteries for car keys
8.3.4. Printed and thin film batteries 2009-2019
9. GLOSSARY
APPENDIX 1: IDTECHEX PUBLICATIONS AND CONSULTANCY
APPENDIX 2 INTRODUCTION TO PRINTED ELECTRONICS
TABLES
1.1. Five ways in which a capacitor acts as the electrical equivalent of the spring
1.2. Advantages and disadvantages of some options for supplying electricity to small devices
1.3. Some limitations of batteries in small electronic devices and some solutions
3.1. Tadiran cylindrical battery ratings
3.2. Printed and thin film battery product and specification comparison
3.3. Printed battery materials comparison
3.4. The half cell and overall chemical reactions that occur in a Zn/MnO2 battery
4.1. Comparison of the three types of capacitor when storing one kilojoule of energy.
4.2. Examples of energy density figures for batteries, supercapacitors and other energy sources
6.1. Challenges faced in developing satisfactory fuel cells for vehicles
6.2. Types of fuel cell and characteristics
8.1. Global market for all batteries for use in portable devices $ billion
8.2. Global market for supercapacitors for use in portable devices $ billion
8.3. Total and small device battery market 2009 and 2019 $billions
8.4. Split of small device battery market in 2009 by shape, giving number, unit value, total value
8.8. Market forecast for printed and potentially printed batteries in US $ billions 2009-2019
FIGURES
1.1. Construction of a battery cell
1.2. MEMS compared with a dust mite less than one millimetre long
1.3. Power in use vs duty cycle for portable and mobile devices showing zones of use of single use vs rechargeable batteries
1.4. Principle of the creation and maintenance of an aluminium electrolytic capacitor
1.5. Construction of wound electrolytic capacitor
1.6. Comparison of construction diagrams of three basic types of capacitor
1.7. Types of ancillary electrical equipment being improved to serve small devices
1.8. Rapid progress in the capabilities of small electronic devices and their photovoltaic energy harvesting contrasted with more modest progress in improving the batteries they employ
2.1. Volumetric energy density vs gravimetric energy density for rechargeable batteries
2.2. Laminar lithium ion battery
2.3. Typical active RFID tag showing the problematic coin cells
2.4. Construction of a lithium rechargeable laminar battery
2.5. Reel to reel construction of rechargeable laminar lithium batteries
2.6. Ultra thin lithium rechargeable battery
2.7. Construction of a thin-film battery
2.8. NanoEnergy® powering a blue LED
2.9. Examples of transparent flexible technology
2.10. Flexible battery that charges in one minute
2.11. Battery assisted passive RFID label with rechargeable thin film lithium battery recording time-temperature profile of food, blood etc in transit
2.12. Bolivian salt flats
2.13. Chevrolet Volt
2.14. Electric Smart car
3.1. Tadiran in EZ pass
3.2. Tadiran’s new high voltage/high rate AA-sized lithium battery
3.3. Internal structure of Power Paper Battery
3.4. Power Paper printed manganese dioxide zinc battery that gathers moisture from the air
3.5. Screen printing of Blue Spark Technology flexible, sealed, manganese dioxide zinc batteries
3.6. Power Paper production line for printed batteries
3.7. Power Paper skin patch that delivers cosmetic through the skin by means of a printed battery and electrodes
3.8. Skin patches electronically communicating to skin patches powered by laminar batteries, coin cells being unacceptable
3.9. Audio Paper TM
3.10. Electronic apparel - sports bra with diagnostic electronics and animated t-shirt displaying music
3.11. Wireless body area network
3.12. Disposable digital plaster
3.13. Sensium system
3.14. Flexible battery made of nanotube ink
3.15. Microbattery built with viruses
3.16. Biomimetic energy storage
4.1. E-labels with capacitor and no battery.
4.2. Examples of small aluminum electrolytic capacitors
4.3. Simplest common modeling circuit for an electrolytic capacitor
5.1. Where supercapacitors fit in
5.2. Energy density vs power density for storage devices
5.3. Small carbon aerogel supercapacitors
5.4. Bikudo supercapacitor
5.5. Laminar supercapacitor one millimetre thick
5.6. Mobile phone modified to give much brighter flash thanks to supercapacitor outlined in red
5.7. Perpetuum energy harvester with its supercapacitors
5.8. Citizen Eco-DriveTM solar powered wristwatch with rechargeable battery
5.9. Symmetric supercapacitor construction
5.10. Symmetric compared to asymmetric supercapacitor construction
5.11. Single sheets of graphene
5.12. Graphene supercapacitor cross section
6.1. MIT Biomimetic fuel cell
6.2. Freeplay wind up radio in Africa
7.1. Blue Spark laminar battery
7.2. Celxpert notebook battery pack
7.3. Interchangeable notebook battery pack
7.4. The Cymbet EnerChip
7.5. Duracell NiOx batteries
7.6. Enfucell SoftBattery
7.7. Thin-film solid-state batteries by Excellatron
7.8. Solar-powered Lifeline radio
7.9. The world’s thinnest self standing rechargeable battery claims FET
7.10. Light in Africa
7.11. LiTESTAR
7.12. Comparison of an electrostatic capacitor, an electrolytic capacitor and an EDLC
7.13. Comparison of an EDLC with an asymmetric supercapacitor sometimes painfully called a bacitor or supercabattery
7.14. Researchers from Planar Energy -Devices, Inc., insert a sample into the vacuum chamber of the company’s thin-film deposition system
7.15. Planar Energy Devices has advanced the solid-state lithium battery from NREL’s crude prototype (below) to a miniaturized, integrated device (bottom)
7.16. Flexible battery that charges in one minute
7.17. Nippon Chemi-Con ELDCs - supercapacitors
7.18. New Planar Energy Devices high capacity laminar battery
7.19. Power Paper’s battery technology
7.20. Prelonic printed batteries

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Energy harvesting, micro batteries and power management ICs are in a position to enable the commercial rollout of the next-generation of low-power electronic devices and systems. Low-power devices are being deployed for wireless as well as wired systems such as mesh networks, sensor and control systems, and micro-electro-mechanical systems (MEMS). Applications include home automation, building automation, industrial process/automated meter reading, medical, military, automotive/tire pressure sensors, radio frequency ID and others.

Battery maintenance and replacement are often cited as the biggest reason to use energy harvesting. The first markets for these new technologies have been applications where batteries are problematic, such a building and home automation, military and avionic devices, communications and location devices, and transportation.

Cost and manufacturability are increasingly becoming key drivers for the adoption of energy harvesting, however. The system “power budget,” initial installation costs, process technology trends, and materials are reaching a point where energy harvesting is a cost-effective value proposition in many applications. Combined with tax credits for certain segments like lighting control, the energy efficiency savings are a convincing argument for many end users.

Semiconductor companies are taking the lead with power management ICs, and thin-film batteries are now commercially available to enable energy harvesting solutions. With potential markets spanning billion-unit industries, energy harvesting is expected to weather worldwide economic volatility and be a good opportunity for power supply companies.

Energy harvesting, small-format batteries and power management ICs are technologies that will enable the commercial rollout of next-generation ultra-low-power electronic devices and systems. Such devices are being deployed for wireless as well as wired systems such as mesh networks, sensor and control systems, micro-electro-mechanical systems (MEMS), radio frequency identification (RFID) devices, and so on.
Energy harvesting, microgenerators and other emerging power management technologies can be the enabler of wireless sensor network adoption. In fact, battery maintenance and replacement is cited as the “biggest reason to use energy harvesting.” The first markets for these new technologies have been applications that can’t be used with batteries. This report will analyze the “next wave” of applications that are likely to adopt advanced power management for ultra-low power devices. It will also provide an overview of the various standards that could help or hinder the adoption of these technologies, along with the power architectures and cost benefits likely to drive commercial viability.

Ultra-low-power (ULP) wireless technologies are primarily employed in applications that are not traditionally considered “portable,” such as commercial building automation, medical monitoring, transportation and avionics, automatic meter reading, RFID, construction, and military. Although not portable systems, the power needs closely mirror the needs of portable devices such as mobile phone handsets and MP3 players. As a result, emerging ULP applications are expected to provide substantial growth opportunities for power management technologies traditionally associated with portable devices (see Figure 1).

ULP wireless applications and portable applications are both low power, although ULP powering is significantly lower. Both are often wireless, and both usually use batteries. They rely on standards that vary by region and application, and both have varying ranges, data rates, and power requirements, depending on standards and applications. The same needs are driving both markets, as well: energy efficiency, small form factors, reduced power requirements, and competition with “wired” systems.

The value-added possibilities that ULP technologies bring include bi-directionality, with data rates and range being particularly important. Network security is important, along with “real-time” monitoring and remote communication with the “host” system. The increasing need to comply with environmental regulations also provides an opportunity for ULP solutions, since they can almost always ensure such compliance.

Energy harvesting is a natural complement to ultra-low-powering, including wireless mesh sensor networks. Sometimes the terms “energy scavenging” or “power harvesting” are used instead; for purposes of consistency, however, this report will use the term “energy harvesting” to designate all three.

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