Stationary Fuel Cells Market Worth USD 14.3 Billion By 2020:

ResearchMoz include new market research report”Stationary Fuel Cells: Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020” to its huge collection of research reports.

Browse PDF – Stationary Fuel Cells Market Shares, Strategies, and Forecasts, Worldwide, 2014 to 2020

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.

View Full Report With Complete TOC at

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.

Table Of Contents

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.

Related Reports – 
Energy Harvesters: Market Shares, Strategies, and Forecasts, Worldwide, 2013 to 2019
Advanced storage devices are emerging simultaneously. Storage devices can leverage the power captured by energy harvesting devices. Energy storage technologies of super-capacitors and thin-film batteries have become cost-effective. Energy harvesting devices have attained workable levels of efficiency. There are significant cost reductions. Many applications are related to smarter computing that depends on sensors capturing change in conditions and making adjustments to the environment based on measured change.
Solid State Thin Film Battery: Market Shares, Strategies, and Forecasts, Worldwide, Nanotechnology, 2013 to 2019

Thin film battery market driving forces include creating business inflection by delivering technology that supports entirely new capabilities. Sensor networks are creating demand for thin film solid state devices. Vendors doubled revenue and almost tripled production volume from first quarter. Multiple customers are moving into production with innovative products after successful trials.

A solid state battery electrolyte is a solid, not porous liquid. The solid is denser than liquid, contributing to the higher energy density. Charging is complex. In an energy-harvesting application, where the discharge is only a little and then there is a trickle back up, the number of recharge cycles goes way up. The cycles increase by the inverse of the depth of discharge. Long shelf life is a benefit of being a solid state battery. The fact that the battery housing does not need to deal with gases and vapors as a part of the charging/discharging process is another advantage.

View Full Report With Complete TOC at

About ResearchMoz

ResearchMoz is the one stop online destination to find and buy market research reports & Industry Analysis. We fulfill all your research needs spanning across industry verticals with our huge collection of market research reports. We provide our services to all sizes of organizations and across all industry verticals and markets. Our Research Coordinators have in-depth knowledge of reports as well as publishers and will assist you in making an informed decision by giving you unbiased and deep insights on which reports will satisfy your needs at the best price.

For More Information Kindly Contact:


Leave a Reply

Fill in your details below or click an icon to log in: Logo

You are commenting using your account. Log Out /  Change )

Google+ photo

You are commenting using your Google+ account. Log Out /  Change )

Twitter picture

You are commenting using your Twitter account. Log Out /  Change )

Facebook photo

You are commenting using your Facebook account. Log Out /  Change )


Connecting to %s