Specifications Table for RWEYQ-T9

RWEYQ8T9Y1B RWEYQ10T9Y1B RWEYQ12T9Y1B RWEYQ14T9Y1B RWEYQ16T9Y1B RWEYQ18T9Y1B RWEYQ20T9Y1B RWEYQ24T9Y1B RWEYQ26T9Y1B RWEYQ28T9Y1B RWEYQ22T9Y1B RWEYQ30T9Y1B RWEYQ32T9Y1B RWEYQ34T9Y1B RWEYQ36T9Y1B RWEYQ38T9Y1B RWEYQ40T9Y1B RWEYQ42T9Y1b RWEYQ42T9Y1B
System Outdoor unit module 1         RWEYQ8T RWEYQ8T RWEYQ10T RWEYQ12T RWEYQ12T RWEYQ14T RWEYQ10T RWEYQ10T RWEYQ10T RWEYQ10T RWEYQ12T RWEYQ12T RWEYQ12T   RWEYQ14T
  Outdoor unit module 2         RWEYQ8T RWEYQ10T RWEYQ10T RWEYQ12T RWEYQ14T RWEYQ14T RWEYQ12T RWEYQ10T RWEYQ10T RWEYQ12T RWEYQ12T RWEYQ12T RWEYQ14T   RWEYQ14T
  Outdoor unit module 3                       RWEYQ10T RWEYQ12T RWEYQ12T RWEYQ12T RWEYQ14T RWEYQ14T   RWEYQ14T
Cooling capacity Nom. 30°C inlet water temp. ID27/19 AHRI Nom. Waterflow Btu/h 73,000 (4) 92,000 (4) 110,000 (4) 131,000 (5)                              
      Nom. Waterflow kW 21.30 (4) 27.00 (4) 32.10 (4) 38.40 (5)                              
    30°C inlet water temp. ID27/19 ISO Nom. Waterflow Btu/h 73,430 (2) 92,080 (2) 109,480 (2) 131,510 (3)                              
      Nom. Waterflow kW 21.51 (2) 26.99 (2) 32.09 (2) 38.54 (3)                              
Power input - 50Hz Cooling Nom. 30°C inlet water temp. ID27/19 AHRI kW 4.52 (4) 5.59 (4) 7.59 (4) 9.01 (5)                              
      30°C inlet water temp. ID27/19 ISO kW 4.45 (2) 5.47 (2) 7.45 (2) 8.96 (3)                              
EER at nom. capacity 30°C inlet water temp. ID27/19 AHRI Nom. Waterflow Btu/h/W 16.10 (4) 16.50 (4) 14.50 (4) 14.50 (5)                              
    Nom. Waterflow kW/kW 4.71 (4) 4.83 (4) 4.23 (4) 4.26 (5)                              
  30°C inlet water temp. ID27/19 ISO Nom. Waterflow Btu/h/W 16.49 (2) 16.83 (2) 14.71 (2) 14.69 (3)                              
    Nom. Waterflow kW/kW 4.83 (2) 4.93 (2) 4.31 (2) 4.30 (3)                              
Capacity range HP 8 10 12 14 16 18 20 24 26 28 22 30 32 34 36 38 40 42 42
Maximum number of connectable indoor units 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (3) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 (7) 64 64 (7)
Indoor index connection Min.   100.0 125.0 150.0 175.0 200.0 225.0 250.0 300.0 325.0 350.0 275.0 375.0 400.0 425.0 450.0 475.0 500.0 445 525.0
  Nom.                                   890  
  Max.   300.0 375.0 450.0 525.0 600.0 675.0 750.0 900.0 975.0 1,050.0 825.0 1,125.0 1,200.0 1,275.0 1,350.0 1,425.0 1,500.0 1,335 1,575.0
Dimensions Unit Height mm 980 980 980 980                              
    Width mm 767 767 767 767                              
    Depth mm 560 560 560 560                              
Weight Unit kg 195 195 197 197                              
Compressor Type   Hermetically sealed scroll inverter compressor Hermetically sealed scroll inverter compressor Hermetically sealed scroll inverter compressor Hermetically sealed scroll inverter compressor                           Hermetically sealed scroll inverter compressor  
Sound power level Cooling Nom. dBA 65.0 (9) 71.0 (9) 72.0 (9) 74.0 (9) 68.0 (9) 72.0 (9) 74.0 (9) 75.0 (9) 76.0 (9) 77.0 (9) 75.0 (5) 76.0 (9) 76.0 (9) 76.0 (9) 77.0 (9) 78.0 (9) 78.0 (9) 79 (3) 79.0 (9)
Sound pressure level Cooling Nom. dBA 48.0 (10) 50.0 (10) 56.0 (10) 58.0 (10) 51.0 (10) 52.0 (10) 53.0 (10) 59.0 (10) 60.0 (10) 61.0 (10) 57.0 (6) 55.0 (10) 58.0 (10) 60.0 (10) 61.0 (10) 62.0 (10) 62.0 (10) 63 (3) 63.0 (10)
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
  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 20,875.0 2,087.5
  Charge TCO2Eq 16.5 16.5 20.0 20.0                              
  Charge kg 7.9 7.9 9.6 9.6                              
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 Braze connection
    OD mm 9,52 9,52 12,7 12,7 12,7 15,9 15,9 15,9 19,1 19,1 15,9 19,1 19,1 19,1 19,1 19,1 19,1   19,1
  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 Braze connection
    OD mm 19.1 (11) 22.2 (11) 28.6 (11) 28.6 (11) 28.6 (11) 28.6 (11) 28.6 (11) 34.9 (11) 34.9 (11) 34.9 (11) 28.6 (7) 34.9 (11) 34.9 (11) 34.9 (11) 41.3 (11) 41.3 (11) 41.3 (11)   41.3 (11)
  HP/LP gas OD mm 15.9 (12.000), 19.1 (13.000) 19.1 (12.000), 22.2 (13.000) 19.1 (12.000), 28.6 (13.000) 22.2 (12.000), 28.6 (13.000) 22.2 (12.000), 28.6 (13.000) 22.2 (12.000), 28.6 (13.000) 28.6 (12.000), 28.6 (13.000) 28.6 (12.000), 34.9 (13.000) 28.6 (12.000), 34.9 (13.000) 28.6 (12.000), 34.9 (13.000) 28.6 (8.000), 28.6 (9.000) 28.6 (12.000), 34.9 (13.000) 28.6 (12.000), 34.9 (13.000) 28.6 (12.000), 34.9 (13.000) 28.6 (12.000), 41.3 (13.000) 41.3 (13.000), 34.9 (12.000) 41.3 (13.000), 34.9 (12.000)   41.3 (13.000), 34.9 (12.000)
  Total piping length System Actual m 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (10) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 500 (14) 165 500 (14)
  Level difference OU - IU Outdoor unit in highest position m                                   50  
      Indoor unit in highest position m                                   40  
    IU - IU Max. m                                   30 (7)  
Standard Accessories Installation manual 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1   1
  Operation manual 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1   1
  Connection pipes 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1   1
  Water supply piping with strainer 1 1 1 1 1 1 1 1 1 1 1 1 1 1 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
  Phase   3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~ 3N~
  Frequency Hz 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
Notes Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m. Indoor temperature : 27°CDB, 19°CWB; outdoor temperature : 35°CDB, 24°CWB Cooling: indoor temp. 27°CDB, 19°CWB; Inlet water temperature: 30°C; equivalent refrigerant piping: 7.5m; level difference: 0m.
  Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Indoor temperature : 20°CDB, 15°CWB; outdoor temperature : 7°CDB, 6°CWB. Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998
  Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 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%) Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998 Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Cooling T3: Indoor temp 29°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,5m Level difference piping 0m Power input indoors included According to teststandard ISO 13256: 1998
  Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 In case of heat pump system, gas pipe is not used Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 7,6m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010
  Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Sound power level is an absolute value that a sound source generates. Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010 In case of heat recovery system Cooling T1: Indoor temp 27°CDB/19°CWB Water inlet temp 30°C Nom. waterflow Equivalent piping length 15,5m Level difference piping 0m Power input indoors included According to teststandard AHRI 1230: 2010
  Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings. Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 7.5m; level difference: 0m In case of heat pump system Heating: indoor temp. 20°CDB; inlet water temperature: 20°C; equivalent piping length: 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%) In case of heat pump system, gas pipe is not used 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%) In case only VRV indoor units are connected 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%)
  Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. In case of heat recovery system Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. Water flow rate for performance testing according to standard rating conditions of EN 14511-2. 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 Water flow rate for performance testing according to standard rating conditions of EN 14511-2.
  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. Sound power level is an absolute value that a sound source generates. Sound power level is an absolute value that a sound source generates. In case of heat pump system 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 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. 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. Refer to refrigerant pipe selection or installation 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. 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.
  In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used In case of heat pump system, gas pipe is not used   In case of heat pump system, gas pipe is not used
  In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system MSC means the maximum current during start up of the compressor. VRV IV uses only inverter compressors. Starting current is always ≤ max. running current. In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system In case of heat recovery system   In case of heat recovery system
  In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system 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 case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system In case of heat pump system   In case of heat pump system
  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 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. 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; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C 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; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C   RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; inlet water temp. 30°C
  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. 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. TOCA means the total value of each OC set. 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.
  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 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
  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. 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. Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits. 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.
  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). MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker). Sound values are measured in a semi-anechoic room. 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. 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. 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 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.
  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%. Maximum allowable voltage range variation between phases is 2%. Maximum allowable voltage range variation between phases is 2%. 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 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%.
  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. 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. Ssc: Short-circuit power 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.
  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. Sound values are measured in a semi-anechoic room. Sound values are measured in a semi-anechoic room. For detailed contents of standard accessories, see installation/operation manual 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.
  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 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 Multi combination (10~54HP) data is corresponding with the standard multi combination 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
  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 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   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
  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 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   Ssc: Short-circuit power
  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
  Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination   Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination Multi combination (10~54HP) data is corresponding with the standard multi combination   Multi combination (10~54HP) data is corresponding with the standard multi combination