| EWWD600VZSSA1 | EWWD700VZSSA1 | EWWD760VZSSA1 | EWWD890VZSSA1 | EWWDC10VZSSA1 | EWWDC12VZSSA2 | EWWDC13VZSSA2 | EWWDC14VZSSA2 | EWWDC16VZSSA2 | EWWDC17VZSSA2 | EWWDC19VZSSA2 | EWWDC21VZSSA2 | ||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Cooling capacity | Nom. | kW | 610 | 704 | 757 | 894 | 1,039 | 1,173 | 1,288 | 1,381 | 1,552 | 1,722 | 1,876 | 2,051 | |
| Capacity control | Method | Variable | Variable | Variable | Variable | Variable | Variable | Variable | Variable | Variable | Variable | Variable | Variable | ||
| Minimum capacity | % | 20 | 20 | 20 | 20 | 20 | 10 | 10 | 10 | 10 | 10 | 10 | 10 | ||
| Power input | Cooling | Nom. | kW | 110 | 132 | 142 | 162 | 196 | 231 | 252 | 276 | 315 | 339 | 380 | 404 |
| EER | 5.5 | 5.31 | 5.3 | 5.52 | 5.29 | 5.07 | 5.11 | 5 | 4.93 | 5.08 | 4.93 | 5.08 | |||
| ESEER | 7.62 | 7.5 | 7.63 | 7.54 | 7.52 | 7.86 | 7.81 | 7.9 | 7.46 | 7.99 | 7.49 | 7.95 | |||
| Dimensions | Unit | Depth | mm | 3,722 | 3,750 | 3,750 | 3,690 | 3,822 | 4,792 | 4,792 | 4,792 | 4,792 | 4,508 | 4,508 | 4,750 |
| Height | mm | 2,123 | 2,123 | 2,123 | 2,292 | 2,487 | 2,296 | 2,296 | 2,296 | 2,296 | 2,350 | 2,338 | 2,498 | ||
| Width | mm | 1,178 | 1,179 | 1,179 | 1,233 | 1,303 | 1,484 | 1,487 | 1,487 | 1,484 | 1,580 | 1,627 | 1,753 | ||
| Weight | Unit | kg | 2,892 | 2,928 | 2,941 | 3,451 | 4,237 | 5,570 | 5,790 | 5,820 | 6,220 | 6,890 | 7,260 | 8,260 | |
| Operation weight | kg | 2,977 | 3,033 | 3,053 | 3,611 | 4,488 | 5,980 | 6,220 | 6,290 | 6,690 | 7,480 | 7,830 | 9,070 | ||
| 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 | ||
| Water volume | l | 88 | 88 | 96 | 134 | 156 | 230 | 230 | 270 | 270 | 320 | 320 | 380 | ||
| Water heat exchanger - condenser | Type | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | Shell and tube | ||
| Compressor | Type | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | Driven vapour compressor | ||
| Quantity | 1 | 1 | 1 | 1 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | |||
| Sound power level | Cooling | Nom. | dBA | 101 | 105 | 105 | 105 | 107 | 106 | 106 | 107 | 107 | 108 | 108 | 110 |
| Sound pressure level | Cooling | Nom. | dBA | 82 | 86 | 86 | 86 | 88 | 87 | 87 | 88 | 88 | 89 | 89 | 90 |
| Refrigerant | Type | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | R-134a | ||
| Charge | kg | 100 | 110 | 110 | 170 | 180 | 250 | 260 | 290 | 290 | 320 | 320 | 350 | ||
| Circuits | Quantity | 1 | 1 | 1 | 1 | 1 | 2 | 2 | 2 | 2 | 2 | 2 | 2 | ||
| GWP | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | 1,430 | |||
| Power supply | Phase | 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 | ||
| Voltage | V | 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 | |||
| (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%. | ||||
| (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 | ||||
| (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 | ||||
| (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. | ||||
| (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. | ||||
| (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. | ||||