Awarded a prestigious POPULAR MECHANICS Breakthrough Award in 2006, this warm air residential heating system also generates electric power. We recently installed one of Climate Energy's co-generation systems at Howard Hall Farm. We were the first home in New York to get one, and after visiting the showroom, and exploring the advantages of this integrated efficiency system, many of our friends are following suit. By combining innovative technology such as this one with enduring historic processes, we can dramatically increase the efficiency of historic buildings to conserve natural resources, and reduce CO2 emissions.

To schedule an appointment to view a FREEWATT SYSTEM on site in Athens, N.Y., call 518.945.1253 or email: info@howardhallfarm.com

CLICK HERE FOR COGENERATION FAQ Or click here to see photos of the room where our new cogeneration system 'lives'.

The Climate Energy Warm Air freewatt system

The Climate Energy freewatt system is an integrated package of four parts, a power generation module, a space heating module, a cogeneration heat exchanger module and a supervisory control system. These components are engineered to work together and provide a new level of comfort and economic savings to North American homes.

Power Generation Module

The power generation module, produced by the Honda Motor Company, is called the MCHP unit. This unit is an incredibly quiet (only 47 dBA at 1 meter) and long life small engine-generator that has already been installed in over 50,000 homes in Japan. The internal combustion engine runs on clean natural gas and can be located in a basement or utility room. This engine produces 1,200 watts of electric power and about 12,000 BTUs per hour of heat for the home.

Before the power from any generator is connected to the grid the electric power quality must meet certain standards. The MCHP uses advanced Honda solid-state inverter technology to automatically insure that the output power supplied to the home and to the electric grid is noise free, is the proper voltage and is synchronized with the AC power of the grid. In the event of a power failure the inverter immediately detects this upset condition and stops delivering power to the grid. This safety feature protects the grid equipment and service personnel.

Space Heating Module

The Climate Energy Warm Air freewatt system integrates a custom state of the art Energy Star qualified* high efficiency furnace produced by ECR International, Inc. with the Honda MCHP unit. The furnace is sized to meet the total heating load and provides the heat distribution to the home. When the household heat demand increases beyond what can be supplied by the engine alone, the furnace kicks in to provide the balance.

Cogeneration Heat Exchanger Module

The heat produced by the MCHP engine's cooling, lubrication and exhaust systems is captured and is transferred to a coolant loop that supplies heat to the furnace through the cogeneration heat exchanger module.

Supervisory Control System

A supervisory control system is used to maximize the hours that the MCHP unit will run and to enhance the thermal comfort of the home. Homeowner control of the system is first accomplished through a programmable electronic wall thermostat like any modern high end heating system. The controller also enables the freewatt system to provide a variety of Internet related features. The system can be controlled remotely via any device with a web browser. Included is a web page display of the power and economic savings resulting from the use of the freewatt system as well as maintenance and diagnostic communication features.

U.S. Patent Number 7,040,544

1. Power Generation Module

System Efficiency: 83%-90%
1.2 kW of Electricity Production
Smart Controller
Base Load Heat Production
PVC Exhaust Vent
Quiet (47 dBA)
Quick Connect Cables/Coolant lines

2. Space Heating Module

Energy Star qualified*
93% AFUE for Auxiliary Heat as needed
ECM Blower Motor - Low Power Consumption
High Efficiency AL29-4C Condensing Heat Exchanger
Top Exhaust Vent-PVC
Left/Right Return Duct

3. Cogeneration Heat Exchanger Module

Air Coil Heat Exchanger
Pump - Low Power Consumption
Coolant Reservoir
High Efficiency Air Filter

4. Supervisory Control System

freewatt System Controller
Communicating Thermostat
Internet Connection
Advanced Heating Algorithm
Compatible with Conventional Air/Conditioning Systems

* As an Energy Star partner, Climate Energy has determined that the furnace included as part of the warm air freewatt™ system meets Energy Star guidelines for energy efficiency.

Warm Air Micro CHP Characteristics

U.S. Patent Number 7,040,544

Ratings

	Input	Heating Capacity	Overall Efficiency	Net Power	Weight
	(MBH)	(MBH)	(%)	(kW)	(Lbs.)
Engine/Generator Module	18.5	12.0	83-90%	1.2	180
Furnace Module	60 to 100	56 to 93	93%		120 to 160

Connections

Electrical
- Engine/Generator	240 VAC, 60 Hz, 1 Phase, less than 10 Amps
- Furnace	120 VAC, 60 Hz, 1 Phase, less than 12 Amps
Vent/Air Intake Pipe
- Engine/Generator	Vent – 1½” Schedule 40 PVC
- Furnace	Vent – 3” Schedule 40 PVC
- Furnace	Air Intake – 2” Schedule 40 PVC
Gas Supply Pipe
- Engine/Generator	½” NPT (4” to 10” w.c. inlet pressure)
- Furnace	½” NPT (5” to 14” w.c. inlet pressure)
Condensate Drain
- Engine Generator and Furnace	½” Schedule 40 PVC or ½” ID Tubing

The Climate Energy freewatt system is installed using nearly the same methods as that of a standard heating appliance. This includes the connection of the heating unit to the heat distribution system, whether it is an air or hot water system. Natural gas is connected to both the furnace and the MCHP unit.

Proven Reliability

Climate Energy has developed the Warm Air freewatt system from reliable system components, including the Honda MCHP engine/generator unit, the ECR high efficiency condensing furnace and Climate Energy's cogeneration heat exchanger module and supervisory control system. The Honda MCHP has over 50,000 installations worldwide and ECR International is a respected HVAC equipment manufacturer with hundreds of thousands of furnace installations over the last 50+ years. The system controller is a proven hardware design with custom-engineered software developed and tested by Climate Energy's Comfort Control Department.

Green Power

The Climate Energy freewatt system operates with a 93% AFUE furnace heating efficiency and the engine/generator provides an overall heat and power efficiency of 83-90%, helping to lower your energy costs. The electric power produced by the freewatt system will displace electric power generated by inefficient central power plants, thereby conserving our natural resources and reducing CO2 emissions. The Climate Energy freewatt system breaks through the energy efficiency barriers of all conventional home heating systems.

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HOWARD HALL FARM HOME

COGENERATION FAQ:

1 Overview
2 Types of plants

2.1 MicroCHP

2.2 MiniCHP
3 See also
4 References
5 External links

Cogeneration

From Wikipedia, the free encyclopedia

Energy Portal

For other uses, see CHP.

Cogeneration (also combined heat and power, CHP) is the use of a heat engine or a power station to simultaneously generate both electricity and useful heat.

Conventional power plants emit the heat created as a byproduct of electricity generation into the environment through cooling towers, flue gas, or by other means. CHP or a bottoming cycle captures the byproduct heat for domestic or industrial heating purposes, either very close to the plant, or —especially in Scandinavia and eastern Europe—for distribution through pipes to heat local housing.

In the United States, Con Edison produces 30 billion pounds of steam each year through its seven cogeneration plants (which boil water to 1,000°F/538°C before pumping it to 100,000 buildings in Manhattan—the biggest commercial steam system in the world.[1][2]

Byproduct heat at moderate temperatures (212-356°F/100-180°C) can also be used in absorption chillers for cooling. A plant producing electricity, heat and cold is sometimes called trigeneration or more generally: polygeneration plant.

Cogeneration is a thermodynamically efficient use of fuel. In separate production of electricity some energy must be rejected as waste heat, but in cogeneration this thermal energy is put to good use.

Overview

Masnedø CHP power station in Denmark. This station burns straw as fuel. The plant heats adjacent greenhouses.

Thermal power plants (including those that use fissile elements or burn coal, petroleum, or natural gas), and heat engines in general, do not convert all of their available energy into electricity. In most heat engines, a bit more than half is wasted as excess heat (see: Second law of thermodynamics). By capturing the excess heat, CHP uses heat that would be wasted in a conventional power plant, potentially reaching an efficiency of up to 89%, compared with 55%[3] for the best conventional plants. This means that less fuel needs to be consumed to produce the same amount of useful energy. Also, less pollution is produced for a given economic benefit.

Some tri-cycle plants have utilized a combined cycle in which several thermodynamic cycles produced electricity, and then a heating system was used as a condenser of the power plant's bottoming cycle. For example, the RU-25 MHD generator in Moscow heated a boiler for a conventional steam powerplant, whose condensate was then used for space heat. A more modern system might use a gas turbine powered by natural gas, whose exhaust powers a steam plant, whose condensate provides heat. Tri-cycle plants can have thermal efficiencies above 80%.

An exact match between the heat and electricity needs rarely exists. A CHP plant can either meet the need for heat (heat driven operation) or be run as a power plant with some use of its waste heat.

CHP is most efficient when the heat can be used on site or very close to it. Overall efficiency is reduced when the heat must be transported over longer distances. This requires heavily insulated pipes, which are expensive and inefficient; whereas electricity can be transmitted along a comparatively simple wire, and over much longer distances for the same energy loss.

A car engine becomes a CHP plant in winter, when the reject heat is useful for warming the interior of the vehicle. This example illustrates the point that deployment of CHP depends on heat uses in the vicinity of the heat engine.

Cogeneration plants are commonly found in district heating systems of big towns, hospitals, prisons, oil refineries, paper mills, wastewater treatment plants, thermal enhanced oil recovery wells and industrial plants with large heating needs.

Thermally enhanced oil recovery (TEOR) plants often produce a substantial amount of excess electricity. After generating electricity, these plants pump leftover steam into heavy oil wells so that the oil will flow more easily, increasing production. TEOR cogeneration plants in Kern County, California produce so much electricity that it cannot all be used locally and is transmitted to Los Angeles[citation needed].

Types of plants

Topping cycle plants produce electricity first, then the exhausted steam is used for heating. Flames naturally produce heat suitable for a boiler. The hot water from condensed steam is well-suited for space and water heating.

Bottoming cycle plants produce high heats for an industrial process, then a waste heat recovery boiler feeds an electrical plant. Bottoming cycle plants are only used when the industrial process requires very high temperatures, such as furnaces for glass and metal manufacturing, so they are rarer.

Large cogeneration systems provide heating water and power for an industrial site or an entire town. Common CHP plant types are:

Gas turbine CHP plants using the waste heat in the flue gas of gas turbines
Combined cycle power plants adapted for CHP
Steam turbine CHP plants that use the heating system as the steam condenser for the steam turbine.
Molten-carbonate fuel cells have a hot exhaust, very suitable for heating.

Smaller cogeneration units may use a reciprocating engine or Stirling engine. The heat is removed from the exhaust and the radiator. These systems are popular in small sizes because small gas and diesel engines are less expensive than small gas- or oil-fired steam-electric plants.

Some cogeneration plants are fired by biomass [4], or industrial and municipal waste (see incineration).

MicroCHP

"Micro cogeneration" is a so called distributed energy resource (DER). the installation is usually less than 5 kWe in a house or small business[1]. Instead of burning fuel to merely heat space or water, some of the energy is converted to electricity in addition to heat. This electricity can be used within the home or business, or (if permitted by the grid management) sold back into the electric power grid.

MiniCHP

"Mini cogeneration" is a so called distributed energy resource (DER). the installation is usually more than 5 kWe and less than 500 kWe in a building or medium sized business [2].

Current (2007) Micro- andMiniCHP installations use five different technologies: microturbines, internal combustion engines, stirling engines, closed cycle steam engines and fuel cells.