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COGENERATION

COMBINED HEAT AND POWER (CHP)

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¿CÓMO FUNCIONA NUESTRO MODELO DE CONTRATO DE COMPRA DE ENERGÍA?

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

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Beneficios clave para el inversionista

1

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

2

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

3

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Rendimientos superiores del 200%

Beneficios clave para el consumidor

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

1

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

2

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

3

Inversión del consumidor de US$0

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Cómo gana un inversionista.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Cómo gana un consumidor.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Grupo Energos:

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Inversionista:

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

Consumidor:

Combined heat and power (CHP) is the simultaneous cogeneration of electricity and heat. Cogeneration is a highly efficient form of energy conversion and using gas engines it can achieve primary energy savings of approximately 40% compared to the separate purchase of electricity from the electricity grid and gas for use in a boiler.

 

If the fuel for the gas engine is renewable such as biogas, hydrogen, syngas or biomethane, CHP can be a highly sustainable source of electricity and heat.

 

Combined heat and power plants are typically embedded close to the end user and therefore help reduce transportation and distribution losses, improving the overall performance of the electricity transmission and distribution network.

 

District energy schemes use combined heat and power plants to generate both electricity and heat for a group of residential or commercial buildings. For power users where security of supply is an important factor for their selection of power production equipment and gas is abundant, gas-based cogeneration systems are ideally suited as captive power plants (i.e. power plants located at site of use).

 

Being a localised source of power generation, it can help improve a site’s resilience in the event of a power grid failure with the addition of island mode operation features.

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10 AÑOS DE BUEN SERVICIO Y COMPROMISO NOS AVALAN

ESTUDIO - INSTALACIÓN - MANTENIMIENTO - GESTIÓN

STUDY CASE

COGENERATION

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Qantas has built Australia's largest commercial cogeneration (cooling, heating and electricity) project. It uses natural gas to produce more efficient and low CO2 energy to supply its corporate building, its maintenance base for aircraft and the air terminal for domestic flights.

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Energos Group is the authorized distributor and service provider for TEDOM gas engines in Mexico.

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An Energy District, in addition to generating electricity, can produce steam, hot water, or cold water, which is pumped through a network of insulated pipes to provide heating, cooling, or hot water to nearby buildings.

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A few years ago we would have liked to have better options in energy services. For this reason, at Energos we combine finance and engineering to create a wide range of solutions tailored to you and reduce your energy costs.

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¿Sabías que?

Los Distritos de Energía pueden reducir el consumo de energía para calefacción y refrigeración de edificios 

hasta en un 50% y mejorar

la calidad del aire.

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