Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

An Air Source Heat Pump (ASHP) is an energy-efficient system that transfers heat from the outside air to either heat or cool indoor spaces. It operates on the principle of thermodynamics, using electricity to power a refrigerant cycle that absorbs heat from the air (even in cold temperatures) and transfers it into a building. Key Components Outdoor Unit: Contains a fan, evaporator coil, and compressor to absorb heat from the air. Indoor Unit: Distributes the heat into the building, often through ductwork or a fan coil. Refrigerant: Circulates between the outdoor and indoor units to transfer heat. Expansion Valve: Regulates refrigerant pressure for efficient operation. How It Works Heating Mode: The refrigerant absorbs heat from the outdoor air. The compressor increases the temperature and pressure of the refrigerant. Heat is released indoors via the condenser coil. Cooling Mode (Reversible Heat Pumps): The cycle is reversed, absorbing heat from inside the building and releasing it outdoors. Advantages Energy Efficiency: Provides more energy output compared to the electricity it consumes, often achieving efficiencies of 300% or higher. Lower Carbon Footprint: Reduces reliance on fossil fuels when powered by renewable electricity. Versatility: Can be used for heating, cooling, and sometimes water heating. Year-Round Operation: Works in a wide range of climates, though efficiency may decrease in extremely cold temperatures. Disadvantages Initial Cost: Higher upfront installation costs compared to traditional heating systems. Performance in Cold Climates: May require a supplemental heating source in extreme cold. Space Requirements: Needs an outdoor unit with good airflow. Applications Residential, commercial, and industrial heating and cooling. Often integrated with solar panels for further energy savings. ASHPs are a popular choice for eco-friendly heating and cooling, especially as part of efforts to reduce carbon emissions and reliance on fossil fuels.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

An Air Source Heat Pump (ASHP) is an energy-efficient system that transfers heat from the outside air to either heat or cool indoor spaces. It operates on the principle of thermodynamics, using electricity to power a refrigerant cycle that absorbs heat from the air (even in cold temperatures) and transfers it into a building. Key Components Outdoor Unit: Contains a fan, evaporator coil, and compressor to absorb heat from the air. Indoor Unit: Distributes the heat into the building, often through ductwork or a fan coil. Refrigerant: Circulates between the outdoor and indoor units to transfer heat. Expansion Valve: Regulates refrigerant pressure for efficient operation. How It Works Heating Mode: The refrigerant absorbs heat from the outdoor air. The compressor increases the temperature and pressure of the refrigerant. Heat is released indoors via the condenser coil. Cooling Mode (Reversible Heat Pumps): The cycle is reversed, absorbing heat from inside the building and releasing it outdoors. Advantages Energy Efficiency: Provides more energy output compared to the electricity it consumes, often achieving efficiencies of 300% or higher. Lower Carbon Footprint: Reduces reliance on fossil fuels when powered by renewable electricity. Versatility: Can be used for heating, cooling, and sometimes water heating. Year-Round Operation: Works in a wide range of climates, though efficiency may decrease in extremely cold temperatures. Disadvantages Initial Cost: Higher upfront installation costs compared to traditional heating systems. Performance in Cold Climates: May require a supplemental heating source in extreme cold. Space Requirements: Needs an outdoor unit with good airflow. Applications Residential, commercial, and industrial heating and cooling. Often integrated with solar panels for further energy savings. ASHPs are a popular choice for eco-friendly heating and cooling, especially as part of efforts to reduce carbon emissions and reliance on fossil fuels.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.

An Air Source Heat Pump (ASHP) is an energy-efficient system that transfers heat from the outside air to either heat or cool indoor spaces. It operates on the principle of thermodynamics, using electricity to power a refrigerant cycle that absorbs heat from the air (even in cold temperatures) and transfers it into a building. Key Components Outdoor Unit: Contains a fan, evaporator coil, and compressor to absorb heat from the air. Indoor Unit: Distributes the heat into the building, often through ductwork or a fan coil. Refrigerant: Circulates between the outdoor and indoor units to transfer heat. Expansion Valve: Regulates refrigerant pressure for efficient operation. How It Works Heating Mode: The refrigerant absorbs heat from the outdoor air. The compressor increases the temperature and pressure of the refrigerant. Heat is released indoors via the condenser coil. Cooling Mode (Reversible Heat Pumps): The cycle is reversed, absorbing heat from inside the building and releasing it outdoors. Advantages Energy Efficiency: Provides more energy output compared to the electricity it consumes, often achieving efficiencies of 300% or higher. Lower Carbon Footprint: Reduces reliance on fossil fuels when powered by renewable electricity. Versatility: Can be used for heating, cooling, and sometimes water heating. Year-Round Operation: Works in a wide range of climates, though efficiency may decrease in extremely cold temperatures. Disadvantages Initial Cost: Higher upfront installation costs compared to traditional heating systems. Performance in Cold Climates: May require a supplemental heating source in extreme cold. Space Requirements: Needs an outdoor unit with good airflow. Applications Residential, commercial, and industrial heating and cooling. Often integrated with solar panels for further energy savings. ASHPs are a popular choice for eco-friendly heating and cooling, especially as part of efforts to reduce carbon emissions and reliance on fossil fuels.

Ambient air is drawn in by the fan and passed over the evaporator. The evaporator cools the air, i.e. it extracts the heat it contains. In the evaporator, the heat removed is transferred to the working fluid (refrigerant). With the aid of an electrically driven compressor, the absorbed heat is “pumped” to a higher temperature level through an increase in pressure and given off to the heating water via the condenser (heat exchanger). In so doing, the electrical energy is used to raise the heat of the environment to a higher temperature level. Due to the fact that the heat energy extracted from the air is transferred to the heating water, this type of appliance is referred to as an air source heat pump. The air source heat pump consists of the following main components: Evaporator, fan and expansion valve as well as the low-noise compressor, the condenser and the electric control unit consisting of branded equipment for controlling and safety devices for protection of Compressor, pump etc. against any variations in voltage, current. Also consists of trip devices, if any parameters not available for smooth running of Heat Pump. The Heat Pump is connected to a Hot Water Storage Tank which is made of 4 mm M.S. Sheet, is insulated with rock wool, for maximum temperature sustenance.. Once the temperature in Tank reaches 55°C the machine automatically shuts down and again re-starts when the temperature reduces to 52°C. There is 24 x 7 uninterrupted Hot Water for the whole year, unconditional to any seasons or weather, unlike solar heaters which are completely dependent on Weather conditions.