2006-2013手机电池和燃料电池市场分析报告

Mobile handset batteries and fuel cells report: 2006-2013

研究公司：visiongainintelligence

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Lead Analyst: Dr Kaushik Das
Publication Date: 24/07/06
Pages: 93  

内容介绍

该英文报告预测了截至2013年，手机和笔记本电脑用微型燃料电池的市场演变，包括市场出货量，收益和成本，分析了核心生产商的产品和战略，指出微型燃料电池技术和锂聚合物电池和其他手机电池技术所存在的竞争点。

该英文报告针对手机和笔记本电脑用微型燃料电池，为以下问题提供了答案：

到2013年，微型燃料电池的成本将有多大的下降空间？在移动及便携式工具市场上，微型燃料电池最多会拥有多大的市场影响力？

谁将成为微型燃料电池的核心生产商？

燃料电池技术和锂聚合物电池有哪些竞争点？

燃料电池供应商如何解决技术难题？他们拥有哪些商业化路线？

微型燃料电池产品及收益会拥有多大的市场规模？该市场规模将会有怎样的演变？

1摘要

市场核心问题

燃料电池收益与动力

燃料电池和用户体验

燃料电池不断受运营商和原始设备生产商的关注

微型燃料电池遇到的壁垒

市场趋势和演变

核心调查

2微型燃料电池

微型燃料电池技术介绍

燃料电池优势

燃料电池使用原理

3战略概述

可回收电池

电池和终端拥护体验

手机用锂电池和锂聚合物电池比较

便携式燃料电池市场壁垒

燃料电池技术难题

燃料电池市场动力

微型燃料电池案例分析

4燃料电池市场机遇

市场发展趋势

手机对燃料电池的技术约束

笔记本电脑对电池的技术要求

燃料电池弥补电力不足的特点

5成本与定价

产量

公众认可意识

手机用电需求

电池标准

产品分销

产品运输安全规则

包装及包装标准

产品检测

原材料，零件成本及产品生产技术

供应商如何取得商业成功

6市场竞争现状

7总结以及建议

对电池供应商提供的建议

对燃料电池生产商提供的建议

对移动运营商提供的建议

If handheld devices continue to improve and demand more power, then traditional batteries will soon be unable to deliver the required energy – FACT.

Power-hungry multimedia applications will drain traditional batteries rapidly and users and the industry demand that the power gap is reduced quickly.

Micro fuel cells are emerging as a viable technology alternative to achieve this goal. However, critical questions remain, such as, when will micro fuel cells be available in commercial handsets and laptops? And how can they help improve the user experience? How much will they cost and what impact this will have on handset costs. Only visiongain’s brand new exclusive management report will tell you.

A longer battery life is essential to both the consumer and enterprise segments, with consumer surveys showing extended battery life to be by far the most desired functionality by end users. What are you doing to satisfy your customers’ requirements? Handset OEMs and mobile operators who can cater to this demand with longer phone operating hours will create a powerful element of product and service differentiation. Shouldn’t you be delivering this demand to your clients, today?

Indeed, OEMs and operators are waking up to the potential on offer by fuel cells for the next generation of mobile phones and laptops. Fuel cell manufacturers are aggressively working beyond R&D to commercialise their products. But is there a business model for micro fuel cells? Which fuel cell manufacturers have the most solid strategies? This report will answer your questions, and more.

Fuel cells, which produce electricity from an external supply of fuel and oxygen, are the most promising technology to solve future energy problems. The fuel cell uses, for example, hydrogen, alcohol (including methanol) or purified and modified form of formic acid as fuels. These fuels, stored in cartridges or canisters, contain high amount of chemical energy that is converted efficiently (without any significant loss) into electrical energy. However issues remain, such as, standardisation, pricing, safety, form factor, and electrical and mechanical interface – these must be addressed before fuel cells become prevalent in mass-market CE devices. What are you and your organisation doing to ensure these issues are tackled?

This 90+ page report specifically focuses on the use of micro-fuel cells for mobile handsets and laptops. It answers questions including:

How will the costs of micro fuel cells fall by 2013? And by how much
What fuel cells solutions will make the biggest market impact in the mobile and portable space?
And who will be the crucial manufacturer?
What competition does fuel cell technology face from Lithium Polymer batteries?
How are fuel cell vendors solving the technical challenges and what are their commercialisation roadmaps?
What is the market size for micro fuel cell units and revenues and how will it evolve?
This focused, high-level report focuses exclusively on the use of micro-fuel cells for mobile handsets and laptops. It analyses the market evolution, including shipment, revenue and cost forecasts until 2013. It evaluates the products and strategies of leading fuel cell manufacturers and discusses the competition that fuel cells face with Lithium Polymer and other standard handset battery technologies. I look forward to receiving your order today.
 
Table of Contents 
Chapter 1 Executive Summary

1.1  Key market issues
1.2  Fuel cell benefits and drivers
1.3  Fuel cells and the user experience
1.4  Carriers and OEMs increasingly view fuel cells as a viable technology alternative
1.5  Barriers limiting micro fuel cell adoption
1.6  Market trends and evolution
1.7  Key findings

Chapter 2 Introduction

2.1  Defining fuel cell technology
2.2  Fuel cell benefits
2.3  How fuel cells work
Figure 2.1:  Typical fuel cell
Table 2.2:  Comparative view of different fuel cell types
2.4  Focus and scope of this report

Chapter 3 Strategic overview

3.1  Rechargeable batteries
3.1.1  Nickel Cadmium
Table 3.1:  NiCD characteristics
3.1.2  Nickel Metal Hydride
Table 3.2:  NiMH characteristics
3.1.3  Lithium ion
Table 3.3:  Li-ion characteristics
3.1.4  Li-polymer
Table 3.4:  Li-Poly characteristics
3.2  Batteries and the end-user experience
3.2.1  Battery power and content delivery
3.3  Li-ion vs Li-Poly batteries in handsets
3.4  Portable fuel cell market barriers
Table 3.5:  Type of battery behind OEM handsets
Table 3.6:  Battery types powering laptop computers
Table 3.7:  Impact of mobile data consumption on battery life (by application)
3.5  Technical challenges affecting fuel cells
3.5.1  Size
3.5.2  Heat generation
3.6  Fuel cell market drivers
3.6.1  Signs of confidence in fuel cell technology
3.6.1.1  Carriers
Table 3.8:  Recent mobile operator fuel cell deals
Table 3.9:  Main Specifications of DoCoMo’s Prototype Micro Fuel Cell
Figure 3.1:  FOMA handset attached to micro fuel cell
3.6.1.2  OEMs
Table 3.10:  Recent handset OEM fuel cell developments
Table 3.11:  Capabilities of various fuel cell technologies
3.7  Business case for micro fuel cells
Chart 3.1:  User experience of a mobile handset with Li-ion battery vs fuel cell
Chart 3.2:  User experience with laptop using fuel cell vs Li-ion battery
3.8  Fuel cells provide a means of differentiating handset offerings

Chapter 4 Fuel cell market opportunities

4.1  Market trends
4.1.1  Power-hungry mobile devices
4.1.2  Advanced services
4.1.3  ARPU
Table 4.1:  Data ARPU of major operators
Table 4.2: Data ARPU drivers
4.2  Handset constraints
Table 4.3:  Handset design issues
Table 4.4:  Battery capacity of various handset models
4.2.1  The impact of handset components on power consumption
Table 4.5: Typical energy consumption by component in GSM handsets
4.2.2  High current bursts
Table 4.6:  Power requirements of GSM and CDMA phones
4.2.3  Power consumption by memory, displays and peripherals
Chart 4.1:  Power consumption by handset component
4.3  Laptop power requirements
Table 4.7: Typical power requirements of a laptop
4.4  Alleviating the power gap through fuel cells
Chart 4.2:  Affect on battery of “heavy pulling”
4.4.1  Fuel cells offer multiple benefits
4.4.2  Fuel Cell Metrics
4.4.2.1  Revenues
Table 4.8:  Global fuel cell market size by device category in 2011
4.4.2.2 Pricing
Table 4.9:  Fuel cell prices by device category, 2006-2013
4.4.2.3  Shipments
Table 4.10:  Fuel cell shipments for mobile devices by region, 2009 & 2011

Chapter 5 Market evolution and commercialization issues

5.1  Costs and pricing
Table 5.1:  Fuel cell prices by device category, 2006-2013
5.2  Volume production
5.3  Public awareness
5.4  Power hungry handsets
5.5  Standardization
Table 5.1:  Micro fuel cell standardisation efforts
5.6  Distribution
5.7  Safety and aircraft transport regulations
5.8  Packaging, regulatory certification and conformance
5.8.1  Packaging for cartridges
5.9  Testing
5.10  Raw materials, cost of components and manufacturing technologies
5.11  What are vendors doing to achieve commercial success?
Figure 5.1:  Strategies for success
5.11.1  Partnerships and collaboration
5.12  Fine-tuning the business model
Table 5.2:  Fuel cell vendor partnership agreements
5.13  Working with mobile operators
5.14  Technology assessment and competitive readiness
5.14.1  Is one fuel cell type likely to dominate the handset market?
Table 5.3:  Fuel cell vendor matrix
 

Chapter 6 Competitive landscape

6.1  Antig Corporation
6.1.1  Technology
6.1.2  Products
Table 6.1:  Typical specification of Antig's products
6.1.3  Power
6.1.4  Commercialization date
6.1.5  Application
6.2  Tekion
6.2.1  Technology
Figure 6.1:  Formira fuel cell
6.2.2  Products
6.2.3  Power and energy
6.2.4  Commercialization date
6.2.5  Application
6.2.6  Customers
6.2.7  Notable developments
6.3  Angstrom Power
6.3.1  Technology
6.3.2  Products
Table 6.2:  V60 specifications
Table 6.3:  G2 specifications
Table 6.4:  P1 specifications
6.3.3  Applications
6.3.4  Customers
6.3.5  Commercialization
6.4  Medis Technologies
6.4.1  Technology
6.4.2  Products
Table 6.5:  Medis PowerPack
6.4.3  Application
6.4.4  Pricing 
6.4.5  Commercialization, marketing and  manufacturing
6.5  SFC Smart Fuel Cell AG
6.5.1  Technology
6.5.2  Products
Table 6.6:  C20-CP specifications
6.5.3  Application
6.5.4  Commercialization and marketing
6.6  Neah Power Systems
6.6.1  Technology
6.6.2  Products
Figure 6.2:  Prototype of Neah’s internal battery cavity fuel cell
6.6.3  Commercialization
6.7  MTI Micro Fuel Cells
6.7.1  Technology
6.7.2  Products
6.7.3  Commercialization
6.8  Ultracell
6.8.1  Technology
6.8.2  Products
6.9  LG
6.10  Samsung
6.11  Toshiba

Chapter 7 Conclusion and Recommendations

7.1  Conclusions
7.2  Recommendations
7.2.1  For battery vendors
7.2.2  For fuel cell manufacturers
7.2.3  Recommendation for Mobile operators

Appendix A Fuel cell technologies, advantages and claims

Appendix B Products, Commercialization roadmap, Customers, and Patents

Appendix C Lead author’s profile

Appendix D About visiongain

Appendix E Report evaluation form

Organisations Listed  
Acer
Angstrom Power
Antig
Apple
Aquafairy
ASE International
Casio
Celestica
Compaq
CSA America
Dell
Fujitsu
General Dynamics
Gillette/Duracell
Hitachi
HP
Hydrocell
Intermec
International Civil Aviation Organization (ICAO)
International Electrotechnical Commission (IEC)
KDDI
Kensington Technology Group
Lenovo (IBM)
LG Chem
LGE
Medis Technologies
Mobile Enterprise Alliance
Motorola Ventures
MTI MicroFuel
Neah Power Systems
NEC
Nokia
Novellus Systems
NTT DoCoMo
O2
Samsung
SFC Smart Fuel Cell
SK Telecom
Sony
Sony Ericsson
Sprint Nextel
Superior Communications
Tekion
Toshiba
TUEV
UltraCell
UN
Underwriters Laboratories (UL)
University of Illinois
US Consumer Product Safety Commission
Verizon
Vodafone