RXYQ8T7Y1B RXYQ10T7Y1B RXYQ12T7Y1B RXYQ14T7Y1B RXYQ16T7Y1B RXYQ18T7Y1B RXYQ20T7Y1B RXYQ22T7Y1B RXYQ24T7Y1B RXYQ26T7Y1B RXYQ28T7Y1B RXYQ30T7Y1B RXYQ32T7Y1B RXYQ34T7Y1B RXYQ36T7Y1B RXYQ38T7Y1B RXYQ40T7Y1B RXYQ42T7Y1B RXYQ44T7Y1B RXYQ46T7Y1B RXYQ48T7Y1B RXYQ50T7Y1B RXYQ52T7Y1B RXYQ54T7Y1B
Sound pressure level Cooling Nom. dBA 58 58.0 (5) 61.0 (5) 61.0 (5) 64.0 (5) 65.0 (5) 66.0 (5) 62.8 (5)   64.0 (5) 65.8 (5) 66.5 (5) 67.0 (5) 67.5 (5) 68.1 (5)   67.0 (5) 67.5 (5) 68.0 (5) 68.0 (5) 68.8 (5) 69.1 (5) 69.5 (5) 69.8 (5)
Capacity range HP 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54
Operation range Cooling Max. °CDB 43 43.0 43.0 43.0 43.0 43.0 43.0                                  
    Min. °CDB -5 -5.0 -5.0 -5.0 -5.0 -5.0 -5.0                                  
  Heating Max. °CWB 15.5 15.5 15.5 15.5 15.5 15.5 15.5                                  
    Min. °CWB -20 -20.0 -20.0 -20.0 -20.0 -20.0 -20.0                                  
Packing 3 Weight kg 0.50                                              
  Material Plastic                                              
Packing Weight kg 2.00                                              
  Material Carton                                              
Packing 2 Weight kg 17.00                                              
  Material Wood                                              
Compressor Crankcase heater W 33                                              
  Compressor-=-Compressor quantity Hermetically sealed scroll compressor                                              
  Compressor-=-Compressor model Inverter                                              
Weight Packed unit kg 205                                              
  Unit kg 187 194 194 305 305 314 314                                  
Refrigerant oil Charged volume l 1.0                                              
  Type Synthetic (ether) oil                                              
Refrigerant Charge TCO2Eq 12.3 12.5 13.2 21.5 21.7 24.4 24.6                                  
  Charge kg 5.9 6.0 6.3 10.3 10.4 11.7 11.8                                  
  Refrigerant-=-Refrigerant type 2,087.5                                              
Fan motor Output W 750                                              
  Fan motor-=-Fan motor quantity 1                                              
  Fan motor-=-Fan motor model Brushless DC motor                                              
Power input - 50Hz Cooling Nom. 35°CDB kW 5.21 (1)               18.2 (1)             29.2 (1)                
  Heating Nom. 6°CWB kW 4.75 (2)               15.85 (2)             25.1 (2)                
    Max. 6°CWB kW 5.51 (2)               18.31 (21)             29.2 (21)                
Indoor index connection Indoor index connection-=-Max 200               600             950                
Cooling capacity Nom. 35°CDB kW 22.4 (1)               67.4 (1)             106.3 (1)                
COP at nom. capacity 6°CWB kW/kW 4.72               4.25             4.2                
Heat exchanger Heat exchanger-=-Heat exchanger type Cross fin coil                                              
  Fin Treatment Anti-corrosion treatment                                              
Piping connections Liquid OD mm 9.52 9,52 12,7 12,7 12,7 15,9 15,9 15,9 15.9 19,1 19,1 19,1 19,1 19,1 19,1 19.1 19,1 19,1 19,1 19,1 19,1 19,1 19,1 19,1
    Type Braze connection                                              
  Gas OD mm 19.1 22.2 28.6 28.6 28.6 28.6 28.6 28.6 34.9 34.9 34.9 34.9 34.9 34.9 41.3 41.3 41.3 41.3 41.3 41.3 41.3 41.3 41.3 41.3
    Type Braze connection                                              
  Level difference OU - IU Outdoor unit in highest position m 90 (7)               90 (10)             90 (10)                
      Indoor unit in highest position m 90 (7)               90 (10)             90 (10)                
    IU - IU Max. m 30 (7)               30 (10)             30 (10)                
  Total piping length System Actual m 1,000 (7) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (10) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (10) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6) 1,000 (6)
  Piping length OU - IU Max. m 165 (7)               165 (10)             165 (10)                
    After branch Max. m 90 (7)               90 (10)             90 (10)                
  Piping connections-=-Piping connections heat insulation Both liquid and gas pipes               Liquid, gas and equalizing pipe             Liquid, gas and equalizing pipe                
Sound power level Cooling Nom. dBA 78 79.0 (4) 81.0 (4) 81.0 (4) 86.0 (4) 86.0 (4) 88.0 (4) 83.1 (4)   84.0 (4) 87.2 (4) 87.2 (4) 89.0 (4) 89.0 (4) 90.1 (4)   87.8 (4) 89.4 (4) 89.6 (4) 89.6 (4) 90.8 (4) 90.8 (4) 90.8 (4) 90.8 (4)
Safety devices Item 01 PC board fuse                                              
Dimensions Packed unit Width mm 1,000                                              
    Height mm 1,820                                              
    Depth mm 835                                              
  Unit Width mm 930 930 930 1,240 1,240 1,240 1,240                                  
    Depth mm 765 765 765 765 765 765 765                                  
    Height mm 1,685 1,685 1,685 1,685 1,685 1,685 1,685                                  
Casing Colour Painted galvanized steel plate                                              
Capacity control Capacity control-=-Capacity control method Inverter controlled                                              
EER at nom. capacity 35°CDB kW/kW 4.30 (1)               3.70 (1)             3.6 (1)                
PED Category Category II               Category II             Category II                
COP at max. capacity 6°CWB kW/kW 4.54               4.10             4.1                
Fan External static pressure Max. Pa 78 78 78 78 78 78 78                                  
  Air flow rate Cooling Nom. m³/min 162                                              
  Fan-=-Fan quantity 1                                              
  Fan-=-Fan discharge direction Propeller fan                                              
Heating capacity Max. 6°CWB kW 25.0 (2)               75.0 (21)             119.0 (21)                
  Nom. 6°CWB kW 22.4 (2)               67.4 (2)             106.3 (2)                
Maximum number of connectable indoor units 6.37               5.42             5.03                
Current - 50Hz Minimum Ssc value kVa 1,216 (0.000)               2,140 (0.000)             2,750 (0.000)                
  Minimum circuit amps (MCA) A 16.1               46.0             76.0                
  Full load amps (FLA) Total A 1.2                                              
  Total overcurrent amps (TOCA) A 17.3                                              
  Maximum fuse amps (MFA) A 20               63             100                
Voltage range Min. % -10               -10             -10                
  Max. % 10               10             10                
Power supply Frequency Hz 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50 50
  Voltage V 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415 380-415
  Phase 3N~               3N~             3N~                
Wiring connections - 50Hz For connection with indoor Quantity F1,F2               F1,F2             F1,F2                
  For power supply Quantity 5G               5G             5G                
Current Nominal running current (RLA) - 50Hz Cooling A 7.2 (9)               25.2 (4)             44.3 (4)                
Notes Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 5m (horizontal); level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19.0°CWB; outdoor temp. 35°CDB; equivalent piping length: 5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19.0°CWB; outdoor temp. 35°CDB; equivalent piping length: 5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m
  heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 5m; level difference: 0m (nominal) Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 5m; level difference: 0m (nominal) Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 5m; level difference: 0m (nominal) Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m
  Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%) Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)
  For more details on operation range see TW drawing Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates.
  Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.
  Maximum allowable voltage range variation between phases is 2%. Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Select wire size based on the value of MCA. The MCA can be regarded as the maximum running current. Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Select wire size based on the value of MCA. The MCA can be regarded as the maximum running current. Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual Refer to refrigerant pipe selection or installation manual
  Refer to refrigerant pipe selection or installation manual RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB
  For more details on standard accessories refer to Installation/operation manual MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current.
  RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value Maximum allowable voltage range variation between phases is 2%. In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value Maximum allowable voltage range variation between phases is 2%. In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value
  MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. Refer to refrigerant pipe selection or installation manual MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. Refer to refrigerant pipe selection or installation manual MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current. MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.
  Select wire size based on the value of MCA. The MCA can be regarded as the maximum running current. MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). In accordance with EN/IEC 61000-3-11, respectively EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply with Zsys ≤ Zmax, respectively Ssc ≥ minimum Ssc value. MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). In accordance with EN/IEC 61000-3-11, respectively EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply with Zsys ≤ Zmax, respectively Ssc ≥ minimum Ssc value. MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).
  MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. European/International Technical Standard setting the limits for voltage changes, voltage fluctuations and flicker in public low-voltage supply systems for equipment with rated current ≤ 75A. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. European/International Technical Standard setting the limits for voltage changes, voltage fluctuations and flicker in public low-voltage supply systems for equipment with rated current ≤ 75A. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set. TOCA means the total value of each OC set.
  TOCA means the total value of each OC set. FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan European/International Technical Standard setting the limits for harmonic currents produced by equipment connected to public low-voltage systems with input current >16A and <= 75A per phase FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan European/International Technical Standard setting the limits for harmonic currents produced by equipment connected to public low-voltage systems with input current >16A and <= 75A per phase FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan FLA means the nominal running current of the fan
  FLA means the nominal running current of the fan Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Short-circuit power Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Short-circuit power Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%.
  In accordance with EN/IEC 61000-3-11, respectively EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply with Zsys ≤ Zmax, respectively Ssc ≥ minimum Ssc value. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. system impedance Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. system impedance Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.
  European/International Technical Standard setting the limits for voltage changes, voltage fluctuations and flicker in public low-voltage supply systems for equipment with rated current ≤ 75A. The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) Multi combination (22~54HP) data is corresponding with the standard multi combination as mentioned on 3D079534 The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) Multi combination (22~54HP) data is corresponding with the standard multi combination as mentioned on 3D079534 The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature ) The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )
  European/International Technical Standard setting the limits for harmonic currents produced by equipment connected to public low-voltage systems with input current >16A and <= 75A per phase The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality
  Contains fluorinated greenhouse gases Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. The AUTOMATIC SEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation functionality ( variable refrigerant temperature control operation) Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. The AUTOMATIC SEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation functionality ( variable refrigerant temperature control operation) Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room.
  Short-circuit power Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Sound values are theoretical values based on sound results of individual installed units. Possible deviations due to variety of installation patterns are not taken into account. Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Sound values are theoretical values based on sound results of individual installed units. Possible deviations due to variety of installation patterns are not taken into account. Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA
  system impedance EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase
  Multi combination (22~54HP) data is corresponding with the standard multi combination as mentioned on 3D079534 Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 5m; level difference: 0m (maximum) Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 5m; level difference: 0m (maximum) Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power Ssc: Short-circuit power
  Sound power level is an absolute value that a sound source generates. For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual   For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual   For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual For detailed contents of standard accessories, see installation/operation manual
  Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination   Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination   Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination Multi combination (22~54HP) data is corresponding with the standard multi combination
  Sound values are measured in a semi-anechoic room.                                              
  The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality                                              
  The AUTOMATIC SEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation functionality ( variable refrigerant temperature control operation)                                              
Power supply intake Both indoor and outdoor unit               Both indoor and outdoor unit             Both indoor and outdoor unit                
ESEER - Automatic   7.20 6.96 6.83 6.50 6.38 5.67 7.07   6.89 6.69 6.60 6.50 6.44 6.02   6.74 6.65 6.62 6.60 6.50 6.46 6.42 6.38
ESEER - Standard   5.67 5.50 5.31 5.05 4.97 4.42 5.58   5.39 5.23 5.17 5.05 5.01 4.68   5.29 5.19 5.17 5.13 5.05 5.02 4.99 4.97
Maximum number of connectable indoor units   64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3)   64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3)   64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3) 64 (3)
Indoor index connection Min.     125.0 150.0 175.0 200.0 225.0 250.0 275.0   325.0 350.0 375.0 400.0 425.0 450.0   500.0 525.0 550.0 575.0 600.0 625.0 650.0 675.0
  Max.     325.0 390.0 455.0 520.0 585.0 650.0 715.0   845.0 910.0 975.0 1,040.0 1,105.0 1,170.0   1,300.0 1,365.0 1,430.0 1,495.0 1,560.0 1,625.0 1,690.0 1,755.0
Compressor Compressor-=-Type     Hermetically sealed scroll compressor Hermetically sealed scroll compressor Hermetically sealed scroll compressor Hermetically sealed scroll compressor Hermetically sealed scroll compressor Hermetically sealed scroll compressor                                  
Refrigerant Type     R-410A R-410A R-410A R-410A R-410A R-410A R-410A   R-410A R-410A R-410A R-410A R-410A R-410A   R-410A R-410A R-410A R-410A R-410A R-410A R-410A R-410A
  GWP     2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5   2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5   2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5 2,087.5
Piping connections Liquid Type     Braze connection Braze connection Braze connection Braze connection Braze connection Braze connection       Braze connection Braze connection Braze connection Braze connection Braze connection   Braze connection   Braze connection Braze connection Braze connection Braze connection Braze connection Braze connection
  Gas Type     Braze connection Braze connection Braze connection Braze connection Braze connection Braze connection       Braze connection Braze connection Braze connection Braze connection Braze connection   Braze connection   Braze connection Braze connection Braze connection Braze connection Braze connection Braze connection
Standard Accessories Item   1 1 1 1 1 1 1   1 1 1 1 1 1   1 1 1 1 1 1 1 1
  Item   1 1 1 1                                      
  Item   1 1 1 1                                      
Power supply Name     Y1 Y1 Y1 Y1 Y1 Y1 Y1   Y1 Y1 Y1 Y1 Y1 Y1   Y1 Y1 Y1 Y1 Y1 Y1 Y1 Y1
  Phase     3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~   3N~ 3N~ 3N~ 3N~ 3N~ 3N~   3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~
Standard Accessories Item           1 1 1   1 1 1 1 1 1   1 1 1 1 1 1 1 1
  Item           1 1 1   1 1 1 1 1 1   1 1 1 1 1 1 1 1
System Outdoor unit module 1                 RXYQ10T   RXYQ12T RXYQ12T RXYQ12T RXYQ16T RXYQ16T RXYQ16T   RXYQ10T RXYQ10T RXYQ12T RXYQ14T RXYQ16T RXYQ16T RXYQ16T RXYQ18T
  Outdoor unit module 2                 RXYQ12T   RXYQ14T RXYQ16T RXYQ18T RXYQ16T RXYQ18T RXYQ20T   RXYQ12T RXYQ16T RXYQ16T RXYQ16T RXYQ16T RXYQ16T RXYQ18T RXYQ18T
                    RXYQ16T             RXYQ20T                
  Outdoor unit module 3                                   RXYQ18T RXYQ16T RXYQ16T RXYQ16T RXYQ16T RXYQ18T RXYQ18T RXYQ18T