____________________________________________________________

Gas Turbine Generators
www.GasTurbineGenerators.com

What is a gas turbine?

Gas turbines is a "jet engine" but more accurately described as a "combustion turbine" which, instead of being located on the wing of an aircraft, is permanently mounted - usually in a "sound-attenuated" enclosure on the ground. As fuel is combusted in the turbine, the rotation of the shaft turns a generator and which generates electricity that is sold to homes and businesses. 

What is a gas turbine generator?

Gas turbine generators are gas gas turbines - or "jet engines" - more accurately called "combustion turbines" that have a generator attached via a common shaft, for generating electricity.

What is Energy Resource Planning?

The purpose of Energy Resource Planning (ERP) seeks to utilize and integrate the requisite analytical concepts and tools necessary to approach the problems of planning for an adequate energy supply and demand balance at the local, regional and national levels.  With a greater focus on reducing and eliminating greenhouse gas emissions, there is an increasing emphasis on "Carbon Free Energy" and "Pollution Free Power."  Renewable energy resources and renewable energy technologies are viewed as the preferred path forward for providing for energy supply and demand in conjunction with Demand Side Management.

We Buy, Sell and Repair Gas Turbines
for our Cogeneration & Trigeneration Installations

WE HAVE BUYERS FOR GAS TURBINE GENSETS
IN GOOD WORKING CONDITION

Waste Heat Recovery
www.WasteHeatRecovery.com

What is Waste Heat Recovery?

Many processes, especially in industrial applications, produce large amounts of excess heat – i.e., heat beyond what can be efficiently used in the process.  Waste Heat Recovery methods attempt to extract some of the energy as work that otherwise would be wasted.  

Typical methods of recovering heat in industrial applications include direct heat recovery to the process itself, recuperators, regenerators, and waste heat boilers.  In many applications – especially those with low-temperature waste heat streams, such as automotive applications – the economic benefits of waste heat recovery do not justify the cost of the recovery systems.  Innovative, affordable methods that are highly efficient, applicable to low-temperature streams, and/or suitable for use with corrosive or “dirty” wastes could expand the number of viable applications of waste heat recovery, as well as improve the performance of existing applications.  Our focus is on the development of innovative Waste Heat Recovery processes and techniques that are (1) more efficient than conventional methods, yet still cost-effective; and (2) applicable to waste streams from which heat cannot be recovered easily with conventional methods.

Turning to cooling, air conditioning systems consume approximately 10% of the energy used in U.S. buildings and are key contributors to peak demand.  Consequently, improving the energy efficiency of air conditioning systems would substantially reduce overall energy consumption and enhance grid reliability.  For example, compressors require cooling to dissipate the heat produced during compression and could benefit from improved surface heat transfer – innovative designs could increase the available heat-transfer area or materials enhancement could increase the heat flux between the hot and cool sides of a heat exchanger.  Similarly, a reduction in the requirement for condenser cooling could provide significant energy savings if more-efficient, cost-effective technologies were developed.  

This is where we believe waste heat recovery integrated with our Solar Trigeneration energy systems represents a unique opportunity for commercial and industrial clients. 

Industrial Waste Heat Recovery -  Waste Heat Recovery from exit gases can significantly increase the energy efficiency of industrial processes.  Energy can be recovered from flue and stack gases, vent gases, and combustion gases at a variety of temperatures at large-scale industrial plants (chemical plants, petroleum refineries, biorefineries, pulp and paper mills, etc.).

The Market and Potential for Waste Heat Recovery technologies and solutions

There are more than 500,000 smokestacks in the U.S. that are "wasting" heat, an untapped resource that can be converted to energy with Waste Heat Recovery technologies.

About 10% of these 500,000 smokestacks represent about 75% of the available wasted heat which has a stack gas exit temperature above 500 degrees F. which could generate approximately 50,000 megawatts of electricity annually and an annual market of over $75 billion in gross revenues before tax incentives and greenhouse gas emissions credits.

Waste Heat Recovery technologies represent the least cost solution which provides the greatest return on investment, than any other possible green energy technology or "carbon free energy" opportunity!

____________________________________________________________

Gas Turbine Generators
www.GasTurbineGenerators.com

info@GasTurbineGenerators.com

Advertise Your Company's Products and Services at 
The Leading Site for Gas Turbine Generators

www.GasTurbineGenerators.com

info@GasTurbineGenerators.com

____________________________________________________________