Cover Image
市場調查報告書 - 291088

全球固定式燃料電池市場:市場佔有率·市場策略·市場預測

Stationary Fuel Cells: Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020

出版商 WinterGreen Research, Inc.
出版日期 內容資訊 英文 603 Pages
價格
全球固定式燃料電池市場:市場佔有率·市場策略·市場預測 Stationary Fuel Cells: Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020
出版日期: 2014年02月26日 內容資訊: 英文 603 Pages
簡介

固定式燃料電池的全球需求預計將從2013年的12億美元擴大到2020年的143億美元。這個成長預測是基於利用天然氣的分散式發電需求而來。

本報告提供全球固定式燃料電池市場現況與展望調查分析,提供燃料電池的市場背景和各種影響因素,燃料電池的類型·引進處·各地區的出貨數及出貨收益實際成果與預測,能源成本分析,主要產品及技術概要,再加上主要企業的市場佔有率,並彙整主要企業簡介等,為您概述為以下內容。

固定式燃料電池市場佔有率·市場預測

第1章 固定式燃料電池:市場動態·市場概要

  • 固定式燃料電池市場動態·市場概要
  • 分散式發電
  • 固體氧化物燃料電池(SOFC)
  • ClearEdge Power 受到HT-PEMFC技術的推動
  • 分散式發電
  • 追求永續性及高能源效率性的產業化
  • 輸出市場電力額
  • 燃料電池的運作
  • 燃料環境上的課題
  • 電池概要
  • 燃料電池的功能性特徵
  • 燃料電池系統的水
  • 燃料電池的電力
  • 燃料電池:由化學能源直接轉換為電力和熱能
  • 氫燃料電池技術
  • 固定式電力的應用
  • 並聯型·獨立型的課題
  • 放鬆管制的影響
  • 燃料電池的課題
  • 鍋爐
  • 燃料電池的可靠性
  • 燃料電池的供給基礎設施
  • 法律規章

第2章 固定式燃料電池:市場佔有率·市場預測

  • 固定式燃料電池:推動市場成長要素
  • 固定式燃料電池:市場佔有率
  • 固定式燃料電池:市場預測
  • SOFC燃料電池:預測
  • PEM固定式燃料電池:預測
  • MCFC(熔融碳酸鹽燃料電池)固定式燃料電池
  • UTC PAFC白金成本
  • SOFC·PEM·MCFC·MCFC 固定式燃料電池的Distributed Campus Environments
  • 能源市場預測
  • PEM膜/電極
  • 能源成本
  • PEM·SOFC·MCFC·PAFC固定式燃料電池的應用·利用
  • MCFC·SOFC·PEMFC的長期成本預測
  • 固定式燃料電池:優勢·弱點
  • 固定式燃料電池價格
  • 地區分析

第3章 固定式燃料電池:產品概要

  • 燃料電池
  • SOFC
  • Bloom Energy的SOFC
  • Ceramic Fuel Cells的SOFC
  • LG
  • Viessmann Group
  • Ceres 燃料電池
  • Acumentrics
  • Samsung
  • Delphi的SOFC
  • LG的SOFC
  • Phosphoric Acid Fuel Cell (PAFC的)固定式燃料電池
  • ClearEdge的質子交換膜燃料電池(PEMFC)
  • Molten Carbonate Fuel Cell (MCFC的)發電廠
  • FuelCell Energy
  • 質子交換膜燃料電池(PEMFC)
  • Ballard

第4章 固定式燃料電池:技術

  • 燃料電池排放量簡介
  • Verizon啟動提供全國19家企業機構電力的大規模綠色能源工程
  • 燃料電池提供了具有經濟性說服力的屬性平衡
  • 固定式燃料電池的政府法規
  • 使用電解質的燃料電池類型
  • IdaTech的燃料處理技術
  • 磷酸型燃料電池(PAFC)
  • 熔融碳酸鹽燃料電池(MCFC)
  • 固體氧化物燃料電池(SOFC)
  • 燃料改質器
  • 燃料電池概要
  • 鹼性電池型燃料電池(AFC)
  • 克服奈米技術:固定式燃料電池成本上的障礙
  • 補充太陽能:燃料電池技術
  • DMFC燃料電池:已經是個可形成的市場
  • 白金催化劑
  • 燃料電池的硼酸鎳催化劑
  • MCFC用
  • PAFC用
  • PAFC和固定式燃料電池
  • 燃料電池零組件
  • 燃料電池堆疊
  • 電源調節器
  • 奈米複合膜
  • Pall:氫燃料的過濾
  • IdaTech

第5章 企業簡介

圖表

本網頁內容可能與最新版本有所差異。詳細情況請與我們聯繫。

目錄

Fuel Cells used to provide distributed power for campus environments achieve better technology and economies of scale. They have achieved grid parity in many cases. They improve and lower energy costs. They threaten to erode utility profitability.

Stationary Fuel Cells are on the cusp of becoming commercially viable, creating companies that are profitable and produce electricity at or below parity with the grid giving every user alternatives to the grid. Bloom Energy has solved the SOFC engineering challenges. Breakthroughs in materials science, and revolutionary designs give Bloom SOFC technology a cost effective, all-electric solution.

Vendors have solved the SOFC conundrum, developing new materials that make units affordable and provide energy device economies of scale and support for wind and solar renewable energy sources.

Stationary fuel cells represent the base for distributed power generation worldwide. No more new coal plants, no mare extensions to the grid. Distributed power has become mainstream. Distributed generation (DG) refers to power generation at the point of consumption.

Generating power on-site, rather than centrally, eliminates the cost, complexity, interdependencies, and inefficiencies associated with energy transmission and distribution. Distributed energy is evolving in a manner like distributed PC and laptop computing, cars for transportation, and smart phones. As distributed Internet data and telephony have found a place in the market, so also will distributed energy generation become widespread. Distributed power shifts energy generation control to the consumer much to the consternation of the existing utility companies.

Renewable energy is intermittent and needs stationary fuel cells for renewables to achieve mainstream adoption as a stable power source. Wind and solar power cannot be stored except by using the energy derived from these sources to make hydrogen that can be stored. Stationary fuel cells are likely to function as a battery in the long term, creating a way to use hydrogen that is manufactured from the renewable energy sources. It is likely that the wind and tide energy will be transported as electricity to a location where the hydrogen can be manufactured. It is far easier to transport electricity than to transport hydrogen. Hydrogen servers as an energy storage mechanism.

Stationary fuel cell markets need government sponsorship. As government funding shifts from huge military obligations, sustainable energy policy becomes a compelling investment model for government.

Stationary fuel cell markets at $1.2 billion in 2013 are projected to increase to $14.3 billion in 2020. Growth is anticipated to be based on demand for distributed power generation that uses natural gas. Systems provide clean energy that is good for the environment. Growth is based on global demand and will shift from simple growth to rapid growth measured as a penetration analysis as markets move beyond the early adopter stage. The big box retailers including many, led by Walmart, the data centers, and companies like Verizon are early adopters.

Eventually hydrogen will be used as fuel in the same stationary fuel cell devices. The hydrogen is manufactured from solar farms. Stationary fuel cells have become more feasible as the industry is able to move beyond platinum catalysts.

Table of Contents

STATIONARY FUEL CELL MARKET SHARES AND MARKET FORECASTS

  • Stationary Fuel Cell Market Driving Forces
    • Platinum Catalysts
  • Stationary Fuel Cell Market Forecasts

1. STATIONARY FUEL CELL MARKET DYNAMICS AND MARKET DESCRIPTION

  • 1.1. Stationary Fuel Cell Market Dynamics and Market Description
    • 1.1.1. Stationary Fuel Cell Ownership Models
  • 1.2. Distributed Power Generation
    • 1.2.1. On-Site Power:
    • 1.2.2. Utility Grid Support:
  • 1.3. Solid Oxide Fuel Cells (SOFC)
    • 1.3.1. Next Generation SOFC
    • 1.3.2. Bloom Energy Solid Oxide Fuel Cells
  • 1.4. ClearEdge Power Moving away from HT-PEMFC Technology
  • 1.5. Distributed Power Generation
    • 1.5.1. Distributed Clean and Continuous Power Generation
    • 1.5.2. Benefits of Bloom Energy
    • 1.5.3. Stationary Fuel Cell Technology
  • 1.6. Industrialization Requires Sustainable, Highly Efficient Energy
    • 1.6.1. Fuel Cell Cogeneration
    • 1.6.2. Stationary Fuel Cells Address Global Energy Challenge
    • 1.6.3. Petroleum
  • 1.7. Value Of Export Market Electricity
  • 1.8. Fuel Cell Operation
    • 1.8.1. Fuel Cells Definition
    • 1.8.2. Fuel Cell Insulating Nature Of The Electrolyte
    • 1.8.3. Inconsistency Of Cell Performance
    • 1.8.4. Fuel Cell Performance Improvements
    • 1.8.5. Transition To Hydrogen
  • 1.9. Fuel Environmental Issues
    • 1.9.1. Environmental Benefits Of Using Fuel Cell Technology
    • 1.9.2. Greenhouse Gas Emissions
  • 1.10. Battery Description
  • 1.11. Fuel Cell Functional Characteristics
  • 1.12. Water In A Fuel Cell System
  • 1.13. Power Of A Fuel Cell
    • 1.13.1. Gas Control
    • 1.13.2. Temperature Control
  • 1.14. Fuel Cell Converts Chemical Energy Directly Into Electricity And Heat
    • 1.14.1. Types Of Fuel Cells
  • 1.15. Hydrogen Fuel Cell Technology
    • 1.15.1. Types Of Fuel Cells
    • 1.15.2. Alkaline Fuel Cells
    • 1.15.3. Phosphoric Acid Fuel Cells
    • 1.15.4. Molten Carbonate Fuel Cells
    • 1.15.5. Solid Oxide Fuel Cells
    • 1.15.6. PEM Technology
    • 1.15.7. Proton Exchange Membrane (PEM) Fuel Cells
    • 1.15.8. PEM Fuel Cells
    • 1.15.9. Proton Exchange Membrane (PEM) Fuel Cell
    • 1.15.10. Proton Exchange Membrane (PEM) Membranes And Catalysts
    • 1.15.11. Common Types Of Fuel Cells
  • 1.16. Stationary Power Applications
    • 1.16.1. Traditional Utility Electricity Generation
  • 1.17. On Grid And Off Grid Issues
    • 1.17.1. Stationary Public Or Commercial Buildings Fuel Cell Market
    • 1.17.2. Distributed Power Generation
    • 2.1.1. Stationary Fuel Cell Company Operating Models
  • 1.18. Impact Of Deregulation
    • 1.18.1. Excess Domestic Capacity
    • 1.18.2. Power Failures
  • 1.19. Fuel Cell Issues
  • 1.19.1. Fuel Cell Workings
  • 1.19.2. Environmental Benefits Of Fuel Cells
  • 1.19.3. Fuel-To-Electricity Efficiency
  • 1.20. Boilers
    • 1.20.1. Domestic Hot Water
    • 1.20.2. Space Heating Loops
    • 1.20.3. Absorption Cooling Thermal Loads
  • 1.21. Fuel Cell Reliability
    • 1.21.1. Power Quality
    • 1.21.2. Licensing Schedules
    • 1.21.3. Modularity
  • 1.22. Fuel Cell Supply Infrastructure
  • 1.23. Laws And Regulations
    • 1.23.1. National Hydrogen Association
    • 1.23.2. Military Solutions

2. STATIONARY FUEL CELL MARKET SHARES AND MARKET FORECASTS

  • 2.1. Stationary Fuel Cell Market Driving Forces
  • 2.2. Stationary Fuel Cell Market Shares
    • 2.2.1. Bloom Energy (SOFC) Fuel Cell Comprised Of Many Flat Solid Ceramic Squares
    • 2.2.2. FuelCell Energy (MCFC)
    • 2.2.3. ClearEdge
    • 2.2.4. ClearEdge / UTC Phosphoric Acid Fuel Cells (PAFCs)
    • 2.2.5. Ballard and IdaTech PEM
    • 2.2.6. Acumentrics
  • 2.3. Stationary Fuel Cell Market Forecasts
    • 2.3.1. Stationary Fuel Cell Units Market Forecasts
    • 2.3.2. Vision For The New Electrical Grid
    • 2.3.3. Fuel Cell Clean Air Permitting
  • 2.4. SOFC Fuel Cell Market Shares and Market Forecasts
    • 2.4.1. SOFC Stationary Fuel Cell Forecasts: Unit Shipment and Installed Base Market Penetration Analysis 161
    • 2.4.2. SOFC ROI Models
    • 2.4.3. SOFC Fuel Cell Markets
    • 2.4.4. SOFC Specialized Ceramics
    • 2.4.5. SOFC Stationary Fuel Cell Market Description
    • 2.4.6. Bloom Energy SOFC
    • 2.4.7. SOFC Methanol Fuel Cells, On The Anode Side, A Catalyst Breaks Methanol
  • 2.5. PEM Stationary Fuel Cell Forecasts
    • 2.5.1. PEM Telecom Fuel Cell Back Up Power Systems
    • 2.5.2. PEM Fuel Cell: High Temperature
    • 2.5.3. PEMFC Efficiency
    • 2.5.4. Challenges for PEMFC Systems
    • 2.5.5. Operating Pressure
    • 2.5.6. Long Term Operation
    • 2.5.7. Proton Exchange Membrane Fuel Cell (PEM) Residential Market
  • 2.6. Molten Carbonate Fuel Cell (MCFC)
    • 2.6.1. MCFC Molten Carbonate Uses Nickel and Stainless Steel as Core Technology
    • 2.6.2. MCFC Stationary Fuel Cell Market Analysis
    • 2.6.3. Molten Carbonate Fuel Cell (MCFC) Fuel Cell Technology 95% Combustion Efficiency
  • 2.7. UTC PAFC Platinum Costs
    • 2.7.1. PAFC
    • 2.7.2. Phosphoric Acid Fuel Cell (PAFC) Technology
  • 2.8. Distributed Campus Environments For SOFC, PEM, MCFC, and MCFC Stationary Fuel Cells
    • 2.8.1. Government Support for Fuel Cell Technology
    • 2.8.2. Competition For Distributed Generation Of Electricity
    • 2.8.3. Stationary Fuel Cell Applications
  • 2.9. Energy Market Forecasts
    • 2.9.1. FuelCell Energy Fuel Cell Stack Module MCFC Costs
    • 2.9.2. FuelCell Energy Cost Breakdown
    • 2.9.3. FuelCell Energy Fuel Cell Stack Module
    • 2.9.4. FuelCell Energy Materials Cost Reduction via Increased Power Density
    • 2.9.5. Fuel Cell Energy Achieving Higher MCFC Power Density
    • 2.9.6. SOFC Unfavorable Fuel Cell Market Characteristics
    • 2.9.7. Phosphoric Acid Fuel Cells (PAFCs)
  • 2.10. PEM Membrane, Or Electrolyte
    • 2.10.1. PEM Proton-Conducting Polymer Membrane, (The Electrolyte)
  • 2.11. Delivered Energy Costs
    • 2.11.1. Nanotechnology Platinum Surface Layer on Tungsten Substrate For Fuel Cell Catalyst
    • 2.11.2. SOFC Fuel Cell Prices
  • 2.12. PEM, SOFC, MCFC, and PAFC Stationary Fuel Cell Applications and Uses:
  • 2.13. MCFC, SOFC, PEMFC Projected Cost Long Term
  • 2.14. Stationary Fuel Cells Strengths and Weaknesses
  • 2.15. Fuel Cell Return On Investment Analysis
    • 2.15.1. Addressable Market
  • 2.16. Stationary Fuel Cell Prices
    • 2.16.1. Solid-Oxide Fuel Cell Stack Prices
    • 2.16.2. MCFC Stationary Fuel Cell Prices
  • 2.17. Stationary Fuel Cell Market Regional Analysis
    • 2.17.1. Stationary Fuel Cells U.S.
    • 2.17.2. Fuel Cells California
    • 2.17.3. Regional Stationary Fuel Cell Competition
    • 2.17.4. CPUC Recently Approved 6 Utility Owned Fuel Cell Projects
    • 2.17.5. Stationary Fuel Cell Installations in California
    • 2.17.6. California Fuel Cell Installations
    • 2.17.7. Campus Fuel Cell Food Processing Agricultural Applications / Gills Onions Stationary Fuel Cells 248
    • 2.17.8. Oxnard DFC Installations
    • 2.17.9. Europe and Japan
    • 2.17.10. Korea
    • 2.17.11. European Photovoltaic Industry Association and Greenpeace Global Investments In Solar Photovoltaic Projects
    • 2.17.12. German Stationary Fuel Cells
    • 2.17.13. Japanese Sales Prospects
    • 2.17.14. New Sunshine Project (Japan)
    • 2.17.15. Fuel Cell Development in Japan
    • 2.17.16. Fuel Cell Cogeneration in Japan
    • 2.17.17. Softbank / Bloom: Bloom Energy Japan
    • 2.17.18. Japanese Government Subsidies
    • 2.17.19. Fuel Cell Cogeneration In Japan
    • 2.17.20. Establishing Codes And Standards Are Very Important For Advancing Fuel Cell Systems In Japan 274
    • 2.17.21. FuelCell Energy Geographic Market Participation
    • 2.17.22. FuelCell Energy within Korea
    • 2.17.23. FuelCell Energy Korean Market Partner POSCO Energy
    • 2.17.24. FuelCell Energy Within the United States
    • 2.17.25. FuelCell Energy Bridgeport Project
    • 2.17.26. FuelCell Energy in Canada
    • 2.17.27. FuelCell Energy in Europe
    • 2.17.28. FuelCell Energy European Market Developments

3. STATIONARY FUEL CELL PRODUCT DESCRIPTION

  • 3.1. Fuel Cells
  • 3.2. Solid Oxide Fuel Cells (SOFC)
    • 3.2.1. Next Generation SOFC
  • 3.3. Bloom Energy Solid Oxide Fuel Cells
    • 3.3.1. Bloom's Energy SOFC Specifications
    • 3.3.2. Bloom Energy Server Architecture
    • 3.3.3. Bloom Energy E-Bay Data Center Installation
  • 3.4. Ceramic Fuel Cells SOFC
    • 3.4.1. Ceramic Fuel Cells BlueGen
    • 3.4.2. Ceramic Fuel Cells Gennex Fuel Cell Module
    • 3.4.3. Ceramic Fuel Cells Engineered Mixed Oxide Powders
  • 3.5. LG
    • 3.5.1. LG Solid Oxide Fuel Cells SOFC Technology
  • 3.6. SKKG Cultural and Historical Foundation / Hexis SOFC
  • 3.7. Viessmann Group
  • 3.8. The Ceres Fuel Cell
    • 3.8.1. Ceres Power Core Technology
  • 3.9. Acumentrics
    • 3.9.1. Acumentrics Fuel Cell Systems Work
    • 3.9.2. The Fuel Reformer
    • 3.9.3. Acumentrics Small Tubes
    • 3.9.4. Acumentrics Specialized Ceramics
    • 3.9.5. Acumentrics Fuel Cell Technologies Ltd Trusted Power Innovations
  • 3.10. Samsung
  • 3.11. Delphi Solid Oxide Fuel Cells
    • 3.11.1. Delphi / Independent Energy Partners (IEP)
    • 3.11.2. Delphi SOFC
    • 3.11.3. Delphi Solid Oxide Fuel Cell Auxiliary Power Unit
  • 3.12. LG Solid Oxide Fuel Cells
  • 3.13. Phosphoric Acid Fuel Cell (PAFC) Stationary Fuel Cells
  • 3.14. ClearEdge Proton Exchange Membrane PEM Fuel Cells
    • 3.14.1. ClearEdge PureCell® Model 5 System
    • 3.14.2. ClearEdge PureCell® Model 400 System
    • 3.14.3. ClearEdge PureCell® Model 400 System
    • 3.14.4. ClearEdge fuel Cell Fleet Surpasses 1 Million Hours Of Operation
    • 3.14.5. Phosphoric Acid Fuel Cells (PAFCs)
    • 3.14.6. ClearEdge UTC Product : The PureCell™ Model 400 Power Solution Features :
    • 3.14.7. ClearEdge UTC PureComfort® Solutions
    • 3.14.8. ClearEdge UTC PureComfort® Power Solutions Save Energy
    • 3.14.9. ClearEdge UTC CO2 Emissions Reduction
    • 3.14.10. ClearEdge UTC PureComfort® Power Solutions
  • 3.15. Molten Carbonate Fuel Cell (MCFC) Power Plants
  • 3.16. FuelCell Energy
    • 3.16.1. FuelCell Energy Power Plants Operating On Natural Gas
    • 3.16.2. FuelCell Energy DFC Power Plant Benefits:
    • 3.16.3. FuelCell Energy DFC Power Plant Benefits:
    • 3.16.4. FuelCell Energy Cost Breakdown
    • 3.16.5. FuelCell Energy Fuel Cell Stack Module
    • 3.16.6. FuelCell Energy Materials Cost Reduction via Increased Power Density
    • 3.16.7. FuelCell Energy Balance-of-Plant Cost Reduction With Volume Production
    • 3.16.8. FuelCell Energy Conditioning, Installation, and Commissioning
    • 3.16.9. FuelCell Energy to Supply 1.4 MW Power Plant to a California Utility
    • 3.16.10. FuelCell Energy Adding Power Generating Capacity At The Point Of Use Avoids Or Reduces Investment In The Transmission And Distribution System
    • 3.16.11. FuelCell Energy DFC1500
    • 3.16.12. FuelCell Energy Fuel Cells Within South Korean Renewable Portfolio
    • 3.16.13. Enbridge and FuelCell Energy Partner
    • 3.16.14. FuelCell Energy Power Plants
  • 3.17. Proton Exchange Membrane PEM Stationary Fuel Cells
  • 3.18. Ballard
    • 3.18.1. Ballard and IdaTech's PEM
    • 3.18.2. Ballard
    • 3.18.3. Ballard / IdaTech
    • 3.18.4. Ballard Power Systems Fuel Cell Stack to Taiwan-Based M-Field Energy Ltd.

4. STATIONARY FUEL CELL TECHNOLOGY

  • 4.1. Fuel Cell Emissions Profile
    • 4.1.1. Direct FuelCell Technology
  • 4.2. Verizon Launches Massive Green Energy Project to Power 19 Company Facilities Across the Country
  • 4.3. Fuel Cells Offer An Economically Compelling Balance Of Attributes
  • 4.4. Stationary Fuel Cell Government Regulation
  • 4.5. Fuel Cell Type Of Electrolyte Used
    • 4.5.1. PEM Fuel Cells
    • 4.5.2. Fuel Cell Stacks
  • 4.6. IdaTech Fuel Processing Technology
  • 4.7. Phosphoric Acid Fuel Cells (PAFC)
    • 4.7.1. PAFC Platinum-Based Catalyst
  • 4.8. Molten Carbonate Fuel Cells (MCFC)
    • 4.8.1. FuelCell Energy Degradation of the Electrolyte Support
    • 4.8.2. MCFC Stack Cost Analysis
    • 4.8.3. Molten Carbonate Fuel Cell Results
  • 4.9. Solid Oxide Fuel Cells (SOFC)
    • 4.9.1. SOFC Fuel Cell/Turbine Hybrids
    • 4.9.2. Acumetrics Tubular SOFC, Solid Oxide Fuel Cell Technology
    • 4.1.3. Chip-Scale Solid Oxide Fuel Cell Arrays
  • 4.10. Fuel Reformer
    • 4.10.1. Specialized Ceramics
    • 4.10.2. Ceramic Fuel Cells
  • 4.11. Fuel Cell Description
  • 4.12. Alkaline Fuel Cells (AFC)
  • 4.13. Nanotechnology Enables Overcoming Stationary Fuel Cell Cost Barriers
    • 4.13.1. DMFC Micro And Portable Fuel Cells Components and Labor Costs
    • 4.13.2. SOFC Fuel Cells Components and Labor Costs:
    • 4.13.3. MCFC Fuel Cells Components and Labor Costs:
    • 4.13.4. PAFC Fuel Cells Components and Labor Costs:
  • 4.14. Solar Energy Complements Fuel Cell Technology
  • 4.15. DMFC Fuel Cell Already Viable Market
    • 4.15.1. DMFC Micro And Portable Fuel Cells Components and Labor Costs
    • 4.15.2. Polymer-Electrolyte Membrane PEM
    • 4.15.3. PEM Nano Metals And Alloys
    • 4.15.4. PEM
  • 4.16. Platinum Catalyst
    • 4.16.1. Nanotechnology Platinum Surface Layer on Tungsten Substrate For Fuel Cell Catalyst
    • 4.16. 2. Nanotechnology Platinum Catalyst Mid Size Stationary Fuel Cells
    • 4.16.2. Water Electrolysis Technology
  • 4.17. Fuel Cell Nickel Borate Catalyst
    • 4.17.1. Fuel Cell High Cost Products
    • 4.17.2. Development of hydrogen technologies critical for the growth of the fuel cell industry
    • 4.17.3. PEM and SOFC For Home Units
  • 4.18. PAFC and Stationary fuel cells
  • 4.19. For MCFC:
  • 4.20. For PAFC:
  • 4.21. Fuel Cell Components
    • 4.21.1. Fuel Processor (Reformer)
  • 4.22. Fuel Cell Stack
  • 4.23. Power Conditioner
  • 4.24. Nano Composite Membranes
  • 4.25. Pall Filtering of Hydrogen
  • 4.26. IdaTech

5. STATIONARY FUEL CELL COMPANY PROFILES

  • 5.1. Stationary Fuel Cell Acquisitions
    • 5.1.1. 2013: ClearEdge Power Acquires UTC Power
    • 5.1.2. BASF Exits High-Temperature Proton Exchange Membrane Fuel Cell Business
    • 5.1.3. GE
    • 5.1.4. Air Liquide Invests in Plug Power
    • 5.1.5. Ballard Buys IdaTech
    • 5.1.6. Viessmann Group Acquires 50 Percent Share in Hexis AG
    • 5.1.7. Acumentrics Acquired Fuel Cell Technologies Ltd
    • 5.1.8. FuelCell Energy / Versa Power Systems Acquisition
    • 5.1.9. Rolls Royce Sells Its Stationary Fuel Cell Operations Interests to LG
    • 5.1.10. Other Transactions and Consolidation of Stationary Fuel Cell Market
  • 5.2. Acumentrics
    • 5.2.1. Acumentrics Technologies Ltd Rugged UPS™
    • 5.2.2. Acumentrics UPS Products
    • 5.2.3. Acumentrics / Fuel Cell Technologies Ltd Trusted Power Innovations
    • 5.2.4. Acumentrics / Fuel Cell Technologies
  • 5.3. Advent Technologies
    • 5.3.1. Advent Technologies Investors
    • 5.3.2. Advent Technologies Target Markets For HT-PEMFC
    • 5.3.3. Advent Target Markets
  • 5.4. AFC Energy
  • 5.5. Altergy
    • 5.5.1. Altergy Mass Production And Commercial Deployment Of Rugged, Low Cost Fuel Cells
    • 5.5.2. Altergy Global Leader In Telecom/Critical Infrastructure
  • 5.6. Ansaldo Fuel Cells
  • 5.7. Ballard Power Systems
    • 5.7.1. Ballard Power Systems / IdaTech LLC / ACME Group (Gurgaon, Haryana)
    • 5.7.2. Ballard Expanded Single Fuel Cell
    • 5.7.3. Ballard Hydrogen
    • 5.7.4. Ballard Buys IdaTech
    • 5.7.5. IdaTech acquires Plug Power's LPG Off-Grid, Backup Power Stationary Product Lines
    • 5.7.6. IdaTech Applications
    • 5.7.7. IdaTech Wireline Communications Networks
    • 5.7.8. Ballard Third Quarter 2013 Revenue
    • Ballard Third Quarter 2013 Highlights
  • 5.8. BASF
  • 5.9. Blasch Precision Ceramics
  • 5.10. Bloom Energy
    • 5.10.1. Bloom Energy Fuel Cells Customer Adobe
    • 5.10.2. Bloom Energy / University Of Arizona NASA Mars Space Program
    • 5.10.3. SoftBank & Bloom Energy Form Joint Venture
  • 5.11. ClearEdge Power / UTC Power
    • 5.11.1. ClearEdge / United Technologies
  • 5.12. Ceramic Fuel Cells
  • 5.13. Delphi
    • 5.13.1. Delphi Automotive LLP Revenue
    • 5.13.2. Delphi Solid Oxide Fuel Cell Auxiliary Power Unit
  • 5.14. Doosan Corporation
  • 5.15. Elcore
  • 5.16. Electro Power Systems
  • 5.17. Enbridge
  • 5.18. FuelCell Energy
    • 5.18.1. FuelCell Energy Production Capacity
    • 5.18.2. FuelCell Energy POSCO 121.8 MW Order
    • 5.18.3. FuelCell Energy / Versa
    • 5.18.4. FuelCell Energy Leading Integrated Fuel Cell Company
    • 5.18.5. FuelCell Energy Revenue 2012, 2013
    • 5.18.6. FuelCell Energy / Versa Power Systems, Inc. Acquisition
    • 5.18.7. FuelCell Energy Market Activity
    • 5.18.8. Stationary Fuel Cell ROI
    • 5.18.9. FuelCell Energy Versa Power Systems Solid Oxide Fuel Cell Development:
    • 5.18.10. FuelCell Energy / Versa Systems Solid Oxide Fuel Cells
    • 5.18.11. FuelCell Energy DFC 3000 Cost Savings
    • 5.18.12. FuelCell Energy Production and Delivery Capabilities
    • 5.18.13. FuelCell Energy Food & Beverage Processing
    • 5.18.14. FuelCell Energy Strategic Alliances and Market Development Agreements
    • 5.18.15. FuelCell Energy Service Company Partners
    • 5.18.16. FuelCell Energy Business Strategy
  • 5.19. Fuji Electric
  • 5.20. GE
    • 5.20.1. GE Unmanned Aircraft
    • 5.20.2
    • GE HPGS
  • 5.21. HydroGen LLC
  • 5.22. Hydrogenics
    • 5.22.1. Hydrogenics Revenue
  • 5.23. ITN Lithium Technology
    • 5.23.1. ITN's Lithium EC sub-Division Focused On Development And Commercialization of EC
    • 5.23.2. ITN's SSLB Division Thin-Film Battery Technology
    • 5.23.3. ITN Lithium Air Battery
    • 5.23.4. ITN Fuel Cell
    • 5.23.5. ITN Thin-film Deposition Systems
    • 5.23.6. ITN Real Time Process Control
    • 5.23.7. ITN Plasmonics
  • 5.24. LG Electronics
    • 5.24.1. LG Business Divisions and Main Products
    • 5.24.2. LG Telemonitoring Smartcare System
    • 5.24.3. Rolls Royce Sells Its Stationary Fuel Cell Operations Interests to LG
  • 5.25. Nuvera
  • 5.26. Plug Power
    • 5.26.1. Plug Power Revenue by Quarters
  • 5.27. POSCO Power
  • 5.28. Rolls Royce
  • 5.29. SafeHydrogen LLC
  • 5.30. Samsung Everland
    • 5.30.1. Samsung
    • 5.30.2. Samsung Finds Talent And Adapts Technology To Create Products
    • 5.30.3. Samsung Adapts to Change, Samsung Embraces Integrity
    • 5.30.4. Samsung Telecom Equipment Group
    • 5.30.5. Samsung Electronics Q2 2013 Revenue
    • 5.30.6. Samsung Memory Over Logic
  • 5.31. Serenergy
  • 5.32. Siemens AG
  • 5.33. SoftBank
  • 5.34. Southern California Edison
  • 5.35. Truma

List of Tables and Figures

  • Table ES-1: Stationary Fuel Cell Market Driving Forces
  • Table ES-2: Stationary Fuel Cell Market Growth Drivers Worldwide
  • Table ES-3: Worldwide Stationary Fuel Cell Market Campus Segments
  • Figure ES-4: Stationary Fuel Cell Market Shares, Dollars, 2013
  • Figure ES-5: Stationary Fuel Cell Shipment Market Forecasts, Dollars, Worldwide, 2014-2020
  • Figure 1-1: Traditional Power Distribution Network vs. Fuel Cell Solution
  • Table 1-2: Methods Of Producing Energy
  • Table 1-3: Key Aspects Of Fuel Cell Stack Costs
  • Figure 1-4: Fuel Cell Operation
  • Table 1-5: Fuel Cell Operation
  • Figure 1-6: Stationary Fuel Cell Distributed Power Generation
  • Figure 1-7: Conventional Power System with Central Generation
  • Figure 1-8: Utility Power Systems with Distributed 1MW Fuel Cell System
  • Table 1-9: Fuel Cell Characteristics
  • Table 1-10: Fuel Cell Description
  • Table 1-11: Fuel Cell Categories
  • Table 1-12: Fuel Cell Performance Improvements
  • Table 1-13: Environmental Concerns Relating To Energy
  • Table 1-14: Environmental Benefits Of Using Fuel Cell Technology
  • Table 1-15: Fuel Cell Advantages Compared To Internal Combustion Engine
  • Table 1-15 (Continued): Fuel Cell Advantages Compared To Internal Combustion Engine
  • Table 1-16: Low-carbon production systems
  • Table 1-17: Fuel Cell Functional Characteristics
  • Table 1-17 (Continued): Fuel Cell Functional Characteristics
  • Table 1-18: Characteristics Of Water In Fuel Cells
  • Figure 1-19: Stationary Fuel Cell Growth Opportunities
  • Table 1-20: Types Of Fuel Cells
  • Table 1-21: Classes Of Fuel Cells
  • Table 1-22: Fuel Cell Applications
  • Table 1-23: Types Of Fuel Cells
  • Table 1-24: Classes Of Fuel Cells
  • Table 1-25: Fuel Cell Applications
  • Table 1-26: Alkaline Fuel Cell Features
  • Table 1-27: Phosphoric acid fuel cells applications
  • Table 1-28: Phosphoric Acid Fuel Cell Features
  • Table 1-29: Molten Carbonate Fuel Cells
  • Table 1-30: Solid Oxide Fuel Cell Features
  • Table 1-31: Proton Exchange Membrane (PEM) Fuel Cell Functions
  • Table 1-31 (Continued): Proton Exchange Membrane (PEM) Fuel Cell Functions
  • Figure 1-32: Stationary Fuel Cell Company Operating Models
  • Table 1-33: Fuel Cell Issues
  • Table 1-34: Fuel Cell System
  • Table 1-35: Operation of a Fuel Cell.
  • Table 1-36: Fuel Cell System Relative Efficiencies
  • Table 1-37: Fuel Cell Reliability Research And Development Issues
  • Table 2-1: Stationary Fuel Cell Market Driving Forces
  • Table 2-2: Stationary Fuel Cell Market Growth Drivers Worldwide
  • Table 2-3: Worldwide Stationary Fuel Cell Market Campus Segments
  • Figure 2-4: Stationary Fuel Cell Market Shares, Dollars, 2013
  • Table 2-5: Stationary Fuel Cell Market Shares, Dollars, 2013
  • Figure 2-6: Bloom Energy Server
  • Figure 2-7: FuelCell Energy Electrochemical Device
  • Figure 2-8: Stationary Fuel Cell Shipment Market Forecasts, Dollars, orldwide, 2014-2020
  • Table 2-9: Stationary Fuel Cell Shipment Market Forecasts Dollars, Worldwide, 2014-2020
  • Figure 2-10: Stationary Fuel Cell Shipment Market Forecasts, Units, Worldwide, 2014-2020
  • Table 2-11: Stationary Fuel Cell Shipment Market Forecasts Units, Worldwide, 2014-2020
  • Table 2-12: Stationary Fuel Cell Market Forces
  • Figure 2-13: SOFC Market Shares, Dollars, Worldwide, 2013
  • Table 2-14: SOFC Stationary Fuel Cell Market Shares, Dollars, Worldwide, 2013
  • Figure 2-15: Stationary SOFC Fuel Cell Market Forecasts, Dollars, Worldwide, 2014-2020
  • Figure 2-16: Stationary Fuel Cell SOFC Market Forecasts, Number Shipped, Worldwide, 2014-2020
  • Table 2-17: Solid Oxide Fuel Cells (SOFC) Stationary Fuel Cell Shipment Market Forecasts, Units and Dollars, Worldwide, 2014-2020
  • Table 2-18: Solid Oxide Fuel Cells (SOFC) Stationary Fuel Cell Shipment Installed Base and Market Penetration Forecasts Units, Worldwide, 2014-2020
  • Figure 2-19: Reducing Hydrogen Crossover Using Nanotechnology
  • Table 2-20: Ceramic Fuel Cells Advantages
  • Figure 2-21: Stationary Fuel Cell PEM, Market Forecasts, Dollars, Worldwide, 2014-2020
  • Table 2-22: Proton Exchange Membrane Fuel Cell PEM Stationary Fuel Cell Shipment Market Forecasts, Units and Dollars, Worldwide, 2014-2020
  • Figure 2-23: Stationary Fuel Cell Proton Exchange Membrane (PEM) Market Forecasts, Units, Worldwide, 2014-2020
  • Table 2-24: PEMFC Efficiency
  • Table 2-25: Stationary Fuel Cell Long-Term Operation
  • Table 2-26: MCFC Technology Development Functions
  • Table 2-27: MCFC Near-zero NOX, SOX and low CO2 emissions
  • Figure 2-28: FuelCell Energy 2.4 MW Fuel Cell Power Plant Inchon, South Korea
  • Table 2-29: MCFC Stationary Fuel Cell Technology
  • Table 2-30: Stationary Fuel Cell Distributed Campus Environments Target Markets Worldwide, 2013
  • Table 2-31: Stationary Fuel Cell Shipment SOFC, PEM, MCFC, and MCFC Market Forecasts, Dollars, Worldwide, 2014-2020
  • Table 2-32: Stationary Fuel Cell Shipment SOFC, PEM, MCFC, and MCFC Market Forecasts, Units, Worldwide, 2014-2020
  • Figure 2-33: Stationary Fuel Cell Applications
  • Figure 2-34: Global Demand For Electric Power
  • Figure 2-35: Cost of Electricity Grid and Stationary Fuel Cell
  • Table 2-36: Complete Fuel Cell Power Plant
  • Table 2-37: Opportunity for PAFC Cost Reductions Opportunity Area
  • Table 2-38: PAFC Stack Costs
  • Figure 2-39: Fuel Cell Image
  • Table 2-40: PEM Stack Costs
  • Figure 2-42: Delivered Energy Costs
  • Table 2-43: Stationary Fuel Cell Markets
  • Table 2-45: Stationary Fuel Cells Strengths and Weaknesses
  • Table 2-46: Cost Comparison of Available Technologies for a 5kW Plant
  • Table 2-47: Unsubsidzed Levelized Cost of Energy
  • Table 2-48: MCFC Stack Costs
  • Table 2-49: Stationary Fuel Cell Regional Market Segments, Dollars, 2013
  • Table 2-50: Stationary Fuel Cell Regional Market Segments, 2013
  • Figure 2-51: Stationary Fuel Cell Installations in California
  • Figure 2-51 (Continued): Stationary Fuel Cell Installations in California
  • Figure 2-52: Efficient Pipeline Pressure Reduction
  • Table 2-53: Types Of Campus Fuel Cell Power Plants
  • Figure 2-54: FuelCell Energy 600 KW DFC, Gills Onions Oxnard, CA
  • Figure 2-55: Korea's Energy Mix 2030
  • Figure 2-57: Korea's Energy Application Sectors
  • Figure 2-58: Korean NRE New and Renewable Energy
  • Figure 2-59: Korean Research & Development in NRE
  • Figure 2-60: Korean Local Plan for Promoting NRE
  • Figure 2-61: FuelCell Energy Environmental Tangible Benefits
  • Figure 2-62: Hybrid Electric Vehicles Costs
  • Figure 2-63: US Energy Costs
  • Figure 2-64: Hydrogen Cost From On Site Steam
  • Figure 2-65: German Bonus for Electricity Produced Through CHP Units
  • Table 2-66: Japanese Sales Prospects
  • Figure 2-67: FuelCell Energy Regional Positioning
  • Figure 2-68: FuelCell Energy Regional Business Activity
  • Figure 3-1: Bloom ES-5700 Fuel Cell
  • Figure 3-2: Bloom's Energy SOFC Specifications
  • Table 3-3: Bloom Energy SOCF Fuel Cell Specifications
  • Table 3-3 (Continued): Bloom Energy SOCF Fuel Cell Specifications
  • Figure 3-4: Bloom Energy Server
  • Table 3-5: Bloom Performance Gain From Modular Architecture
  • Figure 3-6: Bloom Energy Data Center Installation
  • Figure 3-7: Ceramic Fuel Cells BlueGen Products
  • Figure 3-8: Ceramic Fuel Cells BlueGen Installation
  • Figure 3-9: Ceramic Fuel Cells BlueGen Efficiency Comparison
  • Figure 3-10: LG 1 MW SOFC System
  • Figure 3-11: LG Fuel Cell Power Generation Used to Power Electronics and Excess Sold to Grid
  • Figure 3-12: LG Integrated Planar Solid Oxide Fuel Cells SOFC
  • Figure 3-13: LG Integrated Planar Solid Oxide Fuel Cells SOFC 60 Cell Technology
  • Figure 3-14: LG Integrated Planar Solid Oxide Fuel Cells SOFC
  • Figure 3-15: Ceres Power SOFC Fuel Cell
  • Figure 3-16: Acumentrics Fuel Cell Systems Functions
  • Figure 3-17: Acumentrics Small Tubes
  • Table 3-18: Acumentrics Tubular Solid Oxide Fuel Cells Functions
  • Figure 3-19: Delphi Solid Oxide Fuel Cells
  • Table 3-20: Delphi Solid Oxide Fuel Cells Benefits
  • Table 3-21: Delphi Solid Oxide Fuel Cells Typical Applications
  • Figure 3-22: Delphi Solid Oxide Fuel Cells Transportation Application
  • Figure 3-23: LG Fuel Cell Process
  • Table 3-24: LG Solid Oxide Fuel Cells Features
  • Table 3-24 (Continued): LG Solid Oxide Fuel Cells Features
  • Figure 3-25: ClearEdge PureCell® Model 5 System Generates 5 kW
  • Figure 3-26: PureCell® Model 5 System Specifications
  • Table 3-27: ClearEdge The Model 5 System Benefits
  • Table 3-28: ClearEdge The Model 5 System Functions
  • Table 3-29: ClearEdge The Model 5 system Functions
  • Figure 3-30: ClearEdge PureCell® Model 400 System
  • Figure 3-31: ClearEdge PureCell® Model 400 System Characteristics
  • Figure 3-32: UTC Power Fuel Cells Also Qualify For LEED® (Leadership in Energy and Environmental Design) Points.
  • Table 3-33: UTC PureCell system Features
  • Figure 3-34: UTC Fuel cell Supplier To NASA For Space Missions For Over 40 Years
  • Table 3-35: UTC Performance Characteristics POWER
  • Figure 3-36: ClearEdge UTC PureCell Solution Emissions
  • Table 3-37: ClearEdge UTC Stationary Fuel Cell Energy Efficiency Positioning
  • Table 3-38: ClearEdge UTC Microturbine Chiller/Heater and System Level Functions
  • Table 3-39: ClearEdge UTC stationary Fuel cell Benefits :
  • Table 3-40: ClearEdge UTC Stationary Fuel Cell Emissions Benefits
  • Table 3-41: ClearEdge UTC Stationary Fuel Cell Emissions CO2 Emissions Reduction Calculations
  • Figure 3-42: ClearEdge UTC Pollutant Emissions Comparisons
  • Table 3-43: ClearEdge UTC PureComfort® Power Solutions
  • Table 3-44: FuelCell Energy Power Plant Advantages:
  • Table 3-45: FuelCell Energy Product Advantages
  • Table 3-46: FuelCell Energy Fuel Cell Power Plant Models
  • Table 3-47: FuelCell Energy DFC Power Plant Benefits:
  • Figure 3-48: Fuel Cell Electrochemical Device
  • Figure 3-49: Direct Fuel Cell (DFC) Power Plants Offer The Highest Efficiency Which Is Key To Customer Value
  • Figure 3-50: FuelCell Energy 1 MW DFC California State University - Northridge
  • Table 3-51: FuelCell Energy Cost Reduction Opportunities for the DFC 1500 Power Plant Operating On Pipeline-Quality Natural Gas
  • Figure 3-52: Enbridge and FuelCell Energy
  • Figure 3-53: Direct Fuel Cell Power Plant
  • Table 3-54: Ballard Power Systems Comprehensive Portfolio Of Fuel Cell Products
  • Table 3-55: Ballard Power Systems Fuel Cell Products
  • Figure 3-56: Ballard Power Systems Cleargen Mulit-Megawatt Fuel Cell System
  • Figure 3-57: IdaTech Fuel Cell System
  • Table 3-58: Ballard / IdaTech ElectraGen ME System Functions
  • Table 3-59: Ballard / IdaTech ElectraGen ME System Functions
  • Table 4-1: Favorable Emissions Profile Of DFC Power Plants
  • Table 4-2: DFC Technology Advantages
  • Table 4-3: Fuel Cell Types Of Electrical Efficiency, Operating Temperature, Expected Capacity Range, And Byproduct Heat
  • Table 4-4: Fuel Cell Technologies
  • Table 4-5: Fuel Cells By Fuel
  • Figure 4-6: Fuel Cells Offer An Economically Compelling Balance Of Attributes
  • Figure 4-7: Efficiency Differences Among Fuel Cell Technologies
  • Table 4-8: Stationary Fuel Cell Products Regulation
  • Table 4-9: Fuel cell Types By T Electrolyte
  • Figure 4-10: Polymer Electrolyte Membrane (PEM) Fuel Cells
  • Figure 4-11: PEM Fuel Cell Operation
  • Figure 4-12: Fuel Cell Stacks
  • Figure 4-13: Fuel Cell Stack Components
  • Table 4-14: Opportunity for PAFC Cost Reductions Opportunity Area
  • Table 4-15: Molten Carbonate Fuel Cell R&D areas to be addressed
  • Figure 4-16: MCFC Cost Components of Electricity vs. Fuel Cell Capital Cost
  • Figure 4-17: Siemens Westinghouse's 250-Kilowatt Atmospheric Pressure Combined Heat And Power Fuel Cell System
  • Figure 3-18: Chip-Scale Solid Oxide Fuel Cell Arrays
  • Figure 3-19: Use of Vanadium Oxide Anode Allows Energy Storage In Quasi-2d Oxide Fuel Cell Membranes
  • Table 4-20: Ceramic Fuel Cells Advantages
  • Figure 4-21: Bloom Energy Fuel Cell Description
  • Figure 4-22: Bloom Energy Fuel Cell Description (2)
  • Figure 4-23: Bloom Energy Fuel Cell Description (3)
  • Figure 4-24: Bloom Energy Fuel Cell Description
  • Figure 4-25: Bloom Energy Fuel Cell Description (5)
  • Figure 4-26: Fuel Cell Flow Plates
  • Figure -4-27: Home Hydrogen Refueler
  • Figure 4-28: Fuel Cell Components
  • Figure4-29: How A Fuel Cell Works
  • Figure4-30: Stationary Fuel Cell Steam Reformer
  • Figure 4-31: Hydrogen Reformer Components
  • Figure 4-32: 1 Fuel Processor (Reformer); 2 Fuel Cell Stack; 3 Power Conditioner.
  • Figure 4-33: Reducing Hydrogen Crossover Using Nanotechnology
  • Figure 4-34: Comparison of the Performance of Nanocomposite Membranes
  • Figure 4-35: Catalytic Reformer and Refinery Hydrogen System
  • Table 5-1: Acumentrics Technologies Ltd Rugged UPS™
  • Table 5-2: Acumentrics UPS™ Products Target Markets
  • Table 5-3: Acumentrics UPS™ Customers
  • Table 5-4: Acumentrics Rugged-UPS™ Designs
  • Figure 5-5: Acumentrics Fuel Cell Power Generator
  • Table 5-6: Acumentrics Tubular Solid Oxide Fuel Cells Functions
  • Figure 5-7: Acumentrics / Fuel Cell Technologies (FCT) Fuel Cell Test Station QA Testing Area
  • Figure 5-8: Altergy Mass Production Of Rugged, Low Cost Fuel Cells
  • Figure 5-9: Altergy Fuel Cells
  • Figure 5-10: Altergy Freedom PowerFuel Cell, Generator, Unconditioned Batteries and Conditioned Batteries Comparison TCO
  • Table 5-11: Altergy's Market Leading Freedom Power™ Systems
  • Figure 5-12: Ballard® Fuel Cell
  • Table 5-13: Ballard Hydrogen Systems
  • Table 5-14: Bloom Energy Customers
  • Figure 5-15: Bloom Energy Customers
  • Table 5-16: Elcore Stationary Fuel Cell Technical Details
  • Figure 5-17: Enbridge Overview
  • Table 5-18: Enbridge Statistics
  • Figure 5-19: Enbridge Hybrid Fuel Cell
  • Figure 5-20: FuelCell Energy Positioning
  • Table 5-21: FuelCell Energy Positioning
  • Figure 5-22: Fuel Cell Energy Revenue
  • Figure 5-23: FuelCell Quarterly Financial Highlights
  • Table 5-24: FuelCell Energy Leading Customers
  • Figure 5-25: Fuel Cell Energy Product Cost per kW
  • Table 5-26: FuelCell Energy Key Installations
  • Figure 5-27: Versa Systems Solid Oxide Fuel Cells
  • Figure 5-28: Versa Systems Solid Oxide Fuel Cell Technology
  • Figure 5-29: FuelCell Energy DFC 3000 Cost Savings
  • Figure 5-30: FuelCell Energy Production Capabilities
  • Table 5-31: FuelCell Energy Active Project Pipelines
  • Figure 5-32: FuelCell Energy Tangible Environmental Benefits
  • Figure 5-33: FuelCell Energy Efficiency Differences Between Technologies
  • Table 5-34: FuelCell Energy Markets
  • Table 5-35: FuelCell Energy Global Relationships
  • Table 5-36: FuelCell Energy Partner Descriptions
  • Figure 5-37: FuelCell Energy Installation Strategic Execution
  • Figure 5-38: FuelCell Energy Installation Business Activity
  • Figure 5-39: FuelCell Energy Installed Base
  • Table 5-40: ITN Technologies
  • Figure 5-41: ITN Thin Film Battery Technology
  • Figure 5-42: ITN Battery
  • Figure 5-43: ITN Thin-Film Deposition Systems
  • Figure 5-44: ITN's Thin-Film Deposition Systems
  • Table 5-45: ITN Thin-Film Deposition Systems Products and Services Offered
  • Table 5-46: ITN Thin-Film Deposition Systems
  • Figure 5-47: ITNIYN Fuel Cells
  • Figure 5-48: LG Corp Holding Structure
  • Figure 5-49: LG Global Sales
  • Figure 5-50: LG Business Divisions and Main Products
  • Table 5-51: LG Product Offerings
  • Figure 5-52: LG Global Network
  • Figure 5-53: LG Faster and Smarter Technology Innovation
  • Figure 5-54: LG Global Marketing
Back to Top