Specifications Table for EWWH-VZXS

EWWH335VZXSA1 EWWH365VZXSA1 EWWH450VZXSA1 EWWH525VZXSA1 EWWH580VZXSA1 EWWH670VZXSA1 EWWH800VZXSA1 EWWH875VZXSA2 EWWH950VZXSA2 EWWHC11VZXSA2 EWWHC12VZXSA2 EWWHC13VZXSA2 EWWHC14VZXSA2 EWWHC15VZXSA2
Cooling capacity Nom. kW 329 365 448 521 579 665 788 877 952 1,029 1,169 1,288 1,422 1,540
Capacity control Method   Variable Variable Variable Variable Variable Variable Variable Variable Variable Variable Variable Variable Variable Variable
  Minimum capacity % 20 20 20 20 20 20 20 10 10 10 10 10 10 10
Power input Cooling Nom. kW 60.5 66.6 81 96 109 121 147 168 185 198 224 248 276 298
EER 5.44 5.48 5.53 5.42 5.29 5.49 5.37 5.23 5.16 5.19 5.22 5.19 5.16 5.16
ESEER 7.14 7.56 8.32 8.32 8.34 8.46 8.55 8.26 8.26 8.5 8.54 8.81 8.61 8.72
Dimensions Unit Depth mm 3,722 3,722 3,750 3,690 3,690 3,822 3,822 4,792 4,792 4,508 4,508 4,750 4,874 4,874
    Height mm 2,135 2,135 2,123 2,235 2,235 2,487 2,487 2,296 2,296 2,301 2,350 2,500 2,469 2,493
    Width mm 1,178 1,178 1,179 1,189 1,189 1,303 1,303 1,484 1,639 1,579 1,580 1,610 1,704 1,769
Weight Unit kg 2,968 2,911 3,102 3,470 3,451 4,257 4,552 5,860 6,240 6,520 6,920 7,530 7,790 8,670
  Operation weight kg 3,098 3,006 3,274 3,648 3,611 4,518 4,860 6,370 6,760 7,130 7,530 8,300 8,560 9,630
Water heat exchanger - evaporator Type   Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube Flooded shell and tube
  Water volume l 70 88 136 134 134 168 199 270 270 320 320 380 480 480
Compressor Type   Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression Driven vapour compression
  Quantity   1 1 1 1 1 1 1 2 2 2 2 2 2 2
Sound power level Cooling Nom. dBA 97 99 101 105 105 105 107 106 106 107 107 108 109 110
Sound pressure level Cooling Nom. dBA 78 80 82 86 86 86 88 87 87 88 88 89 89 90
Refrigerant Type   R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze) R-1234(ze)
  Charge kg 95 95 100 110 170 170 180 250 260 290 290 320 320 350
  Circuits Quantity   1 1 1 1 1 1 1 2 2 2 2 2 2 2
  GWP   7 7 7 7 7 7 7 7 7 7 7 7 7 7
Power supply Phase   3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~ 3~
  Frequency Hz 50 50 50 50 50 50 50 50 50 50 50 50 50 50
  Voltage V 400 400 400 400 400 400 400 400 400 400 400 400 400 400
Notes (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0 (1) - All the performances (Cooling capacity, unit power input in cooling and EER) are based on the following conditions: evaporator 12.0/7.0°C; condenser 30/35.0°C, unit at full load operation, operating fluid: water, fouling factor = 0
  (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744 (2) - Sound level data are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; entering condenser water temp. 30°C; leaving condenser water temp. 35°C; full load operation; standard: ISO3744
  (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (3) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%.
  (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C (4) - Nominal running current in cooling mode is referred to the following conditions: evaporator 12°C/7°C; condenser 30°C/35°C
  (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope (5) - Maximum running current is based on max compressor absorbed current in its envelope
  (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage. (6) - Maximum unit current for wires sizing is based on minimum allowed voltage.
  (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1 (7) - Maximum current for wires sizing: compressor full load ampere x 1.1
  (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options. (8) - All data refers to the standard unit without options.
  (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data. (9) - All data are subject to change without notice. Please refer to the unit nameplate data.
  (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (10) - For more details on the operating limits please refer to the Chiller Selection Software (CSS).
  (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (11) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels.
  (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced. (12) - In case of inverter driven units, no inrush current at start up is experienced.