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ERV DC Series

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ERV DC Series

24-Hour, Efficient Ventilation for Large Spaces

24-hour continuous ventilation enables the constant circulation of fresh air. Energy Recovery Ventilator is efficient and energy-saving. Suitable for large spaces.
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Features

Energy Efficient Energy Recovery During Ventilation

Panasonic’s ERV system recovers approximately 75% of energy released during circulation, reducing air conditioning loads, as well as energy usage.
Panasonic’s ERV system recovers approximately 75% of energy released during circulation, reducing air conditioning loads, as well as energy usage.
Utilising counter flow heat exchange elements, energy released during the exhaust process of air conditioning is recovered and used alongside the supply of fresh air into commercial and residential locations. Reducing energy usage and thermal energy lost in other ventilation cycles.
Utilising counter flow heat exchange elements, energy released during the exhaust process of air conditioning is recovered and used alongside the supply of fresh air into commercial and residential locations. Reducing energy usage and thermal energy lost in other ventilation cycles.

Energy efficient DC motor

Our ERV systems utilise DC (Direct Current) motors to reduce power consumption of energy during use. Panasonic’s DC motors have a lower temperature rise than traditional AC (Alternating Current) motors, allowing for longer run times.
Energy efficient DC motor

Energy Saving by Reducing Air Conditioner Load

Panasonic ERV systems allows for the reduction of thermal energy when paired with air conditioning systems. Allowing for up to 66% reduction of workload allowing for energy saving and energy efficient operation.
(Example: FY-E15DZ1)
Energy Saving by Reducing Air Conditioner Load

The Filter Removes Dust, Pollen, and Other Harmful Particles, Allowing Only Clean Air to Enter The Room.

Did you know that we spend nearly 90% of our time indoors, inhaling around 18 kilograms of air every single day? This makes it crucial to prioritize clean and high-quality indoor air quality to create a healthier, more comfortable living environment.
Did you know that we spend nearly 90% of our time indoors, inhaling around 18 kilograms of air every single day? This makes it crucial to prioritize clean and high-quality indoor air quality to create a healthier, more comfortable living environment.
Merv16/F7 standard filter designed to remove dust, pollen and other harmful particle’s, allowing only clean and purified air into the home.
Merv16/F7 standard filter designed to remove dust, pollen and other harmful particle’s, allowing only clean and purified air into the home.

Unified Control with Commercial Air Conditioners

Panasonic’s ERV system can be interconnected with most traditional air conditioning systems* allowing for energy efficient operations as well as automated systems to prevent energy loss during and after use.
*Method of connection depends on the model used
Unified Control with Commercial Air Conditioners

Highly Secure Fuse

Experience peace of mind with our advanced thermal safety fuse, designed to prevent accidents even during unexpected current surges of power.
Highly Secure Fuse

Adjustable Airflow as Required

Optimise your airflow management by choosing between HIGH or LOW settings to precisely align with your environment's specific needs.
*1-4 among High and 1-4 among Low can be selected at the time of construction according to the building’s ventilation requirements.
Adjustable Airflow as Required

Specs

FV-35ZY1

Photo of FV-35ZY1

FV-50ZY1

Photo of FV-50ZY1

FV-65ZY1

Photo of FV-65ZY1

FV-1KZY1

Photo of FV-1KZY1

FV-1HZY1

Photo of FV-1HZY1

FV-2KZY1

Photo of FV-2KZY1

All maintenance can be performed through a single inspection hole

Straight air supply/exhaust system used for easier installation

FV-35ZY1 FV-50ZY1 FV-65ZY1 FV-1KZY1 FV-1HZY1 FV-2KZY1
Air Volume (CMH) High 350 500 650 1000 1500 2000
Low 210 300 390 600 900 1200
Static Pressure (Pa) High 140 130 150 150 130 130
Low 50.5 47 54 54 48 48
Temperature exchange efficiency (%) High Cooling 71 65 64 65 63 65
Heating 83 81 82 82 83 82
Low Cooling 76 74 68 73 73 73
Heating 84 82 84 85 85 85
Enthalpy exchange efficiency (%) High Cooling 67 62.5 62.5 63 63.5 63
Heating 75 73 66 74 73 74
Low Cooling 69 68 72 69 68 69
Heating 76 76 75 76 75 76
Power Consumption (W) High 141 180 420 550 940 1100
Low 58 76 180 235 430 490
Noise Level (dB[A]) High 39 43 45 46 49 51
Low 33 32 34 36 41.5 43.5
Applicable Duct Diameter (mm) φ150 φ200 φ200 φ250 φ250 φ250
Weight (kg) 37 40 48 64 116 139
Note Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).
Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).
Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).
Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).
Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).
Note1: The value in Specification table are representative characteristics value at 220V, 50Hz.
Note2: The input power and exchange efficiency are the values measured under the standard air volume.
Note3: The above specification are the values measured under the factory set.
Note4: The power indicated on the name plate is the maximum value under the static pressure of 0Pa.
Note5: The noise is measured 1.5m directly below the center of the energy recovery ventilator. The noise value of the product is measured in a full anechoic chamber. Under actual conditions, due the impact of ambient sound, the noise value will be greater than the target value. The noise rises by about 1 dB(A) under reverse installation.
Note6: The air volume in normal ventilation mode is basically the same as the air volume in energy recovery mode.
Note7: The energy recovery efficiency test should be performed according to the method specified in Appendix 4 of JIS B 8628 (2003). The test environmental conditions should be subject to the winter and summer conditions specified in Table1 and Table2 of JIS B 8628 (2017). Other test methods should be subject to JIS B 8628 (2003).

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