| SEHVX20BAW | SEHVX32BAW | SEHVX40BAW | SEHVX64BAW | ||||
|---|---|---|---|---|---|---|---|
| Refrigerant charge | Per circuit | TCO2Eq | 0.0 | 0.0 | 0.0 | 0.0 | |
| Weight | Unit | kg | 97.0 | 105 | 137 | 153 | |
| Water heat exchanger | Water volume | l | 3 | 5 | 6 | 9 | |
| Type | Brazed plate | Brazed plate | Brazed plate | Brazed plate | |||
| Sound power level | Cooling | Nom. | dBA | 78 | |||
| Dimensions | Unit | Width | mm | 766 | 766 | 766 | 766 |
| Depth | mm | 396 | 396 | 396 | 396 | ||
| Height | mm | 1,573 | 1,573 | 1,573 | 1,573 | ||
| Water circuit | Total water volume | l | 4.2 (8) | 5.8 (8) | 7.9 (8) | 11.0 (8) | |
| Piping | inch | 1-1/4" | 1-1/4" | 1-1/2" | 1-1/2" | ||
| Piping connections diameter | inch | 1-1/4" (female) | 1-1/4" (female) | 2" (female) | 2" (female) | ||
| Power supply | Phase | 3N~ | 3N~ | 3N~ | 3N~ | ||
| Name | W1 | W1 | W1 | W1 | |||
| Frequency | Hz | 50 | 50 | 50 | 50 | ||
| Voltage | V | 400 | 400 | 400 | 400 | ||
| Notes | (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C | (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C | (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C | (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C | |||
| (2) - Condition: Ta DB/WB 7°C/6°C - LWC 45°C (Dt=5°C) | (2) - Condition: Ta DB/WB 7°C/6°C - LWC 45°C (Dt=5°C) | (2) - Condition: Ta DB/WB 7°C/6°C - LWC 45°C (Dt=5°C) | (2) - Condition: Ta DB/WB 7°C/6°C - LWC 45°C (Dt=5°C) | ||||
| (3) - Condition: Ta 35°C - LWE 7°C ( DT = 5°C) | (3) - Condition: Ta 35°C - LWE 7°C ( DT = 5°C) | (3) - Condition: Ta 35°C - LWE 7°C ( DT = 5°C) | (3) - Condition: Ta 35°C - LWE 7°C ( DT = 5°C) | ||||
| (4) - Water can be used above 5°C. Between 0°C and 5°C a 30% glycol solution (propylene or ethylene) has to be used. Between 0°C and -10°C a 40% glycol solution (propylene or ethylene) has to be used (see installation manual and information related to OPZL opti | (4) - Water can be used above 5°C. Between 0°C and 5°C a 30% glycol solution (propylene or ethylene) has to be used. Between 0°C and -10°C a 40% glycol solution (propylene or ethylene) has to be used (see installation manual and information related to OPZL opti | (4) - Water can be used above 5°C. Between 0°C and 5°C a 30% glycol solution (propylene or ethylene) has to be used. Between 0°C and -10°C a 40% glycol solution (propylene or ethylene) has to be used (see installation manual and information related to OPZL opti | (4) - Water can be used above 5°C. Between 0°C and 5°C a 30% glycol solution (propylene or ethylene) has to be used. Between 0°C and -10°C a 40% glycol solution (propylene or ethylene) has to be used (see installation manual and information related to OPZL opti | ||||
| (5) - Excluding water volume in the unit. In most applications this minimum water volume will have a satisfying result. In critical processes or in rooms with a high heat load though, extra water volume might be required. Refer to operation range for more info. | (5) - Excluding water volume in the unit. In most applications this minimum water volume will have a satisfying result. In critical processes or in rooms with a high heat load though, extra water volume might be required. Refer to operation range for more info. | (5) - Excluding water volume in the unit. In most applications this minimum water volume will have a satisfying result. In critical processes or in rooms with a high heat load though, extra water volume might be required. Refer to operation range for more info. | (5) - Excluding water volume in the unit. In most applications this minimum water volume will have a satisfying result. In critical processes or in rooms with a high heat load though, extra water volume might be required. Refer to operation range for more info. | ||||
| (6) - Excluding the water volume in the unit. This volume will guarantee suficient defrost energy for all applications, however, this volume can be multiplied by 0,66 if the heating sepoint is ≥ 45° C (eg. Fan coils) | (6) - Excluding the water volume in the unit. This volume will guarantee suficient defrost energy for all applications, however, this volume can be multiplied by 0,66 if the heating sepoint is ≥ 45° C (eg. Fan coils) | (6) - Excluding the water volume in the unit. This volume will guarantee suficient defrost energy for all applications, however, this volume can be multiplied by 0,66 if the heating sepoint is ≥ 45° C (eg. Fan coils) | (6) - Excluding the water volume in the unit. This volume will guarantee suficient defrost energy for all applications, however, this volume can be multiplied by 0,66 if the heating sepoint is ≥ 45° C (eg. Fan coils) | ||||
| (7) - This is PD between inlet & outlet connections of unit. It includes the water side heat exchanger pressure drop. | (7) - This is PD between inlet & outlet connections of unit. It includes the water side heat exchanger pressure drop. | (7) - This is PD between inlet & outlet connections of unit. It includes the water side heat exchanger pressure drop. | (7) - This is PD between inlet & outlet connections of unit. It includes the water side heat exchanger pressure drop. | ||||
| (8) - Including piping + PHE; excluding expansion vessel | (8) - Including piping + PHE; excluding expansion vessel | (8) - Including piping + PHE; excluding expansion vessel | (8) - Including piping + PHE; excluding expansion vessel | ||||