Specifications Table for EWYD-BZSL

EWYD250BZSL EWYD270BZSL EWYD290BZSL EWYD320BZSL EWYD330BZSL EWYD360BZSL EWYD370BZSL EWYD400BZSL EWYD430BZSL EWYD450BZSL EWYD490BZSL EWYD510BZSL EWYD570BZSL
Cooling capacity Nom. kW 247 (1) 265 (1) 290 (1) 315 (1) 330 (1) 353 (1) 370 (1) 401 (1) 423 (1) 446 (1) 490 (1) 507 (1) 565 (1)
Heating capacity Nom. kW 271 (2) 298 (2) 325 (2) 334 (2) 350 (2) 380 (2) 412 (2) 445 (2) 465 (2) 477 (2) 533 (2) 561 (2) 618 (2)
Capacity control Method   Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless Stepless
  Minimum capacity % 13.0 13.0 13.0 13.0 13.0 13.0 13.0 13.0 13.0 9.0 9.0 9.0 9.0
Power input Cooling Nom. kW 89.5 (1) 99.5 (1) 110 (1) 115 (1) 123 (1) 134 (1) 144 (1) 151 (1) 163 (1) 158 (1) 177 (1) 186 (1) 216 (1)
  Heating Nom. kW 91.4 (2) 100 (2) 108 (2) 118 (2) 126 (2) 133 (2) 143 (2) 157 (2) 167 (2) 165 (2) 178 (2) 186 (2) 208 (2)
EER 2.76 (1) 2.66 (1) 2.62 (1) 2.75 (1) 2.68 (1) 2.64 (1) 2.57 (1) 2.66 (1) 2.59 (1) 2.83 (1) 2.77 (1) 2.73 (1) 2.61 (1)
COP 2.96 (2) 2.97 (2) 3.00 (2) 2.82 (2) 2.78 (2) 2.85 (2) 2.88 (2) 2.83 (2) 2.79 (2) 2.88 (2) 2.99 (2) 3.01 (2) 2.97 (2)
ESEER 4.06 4.04 4.03 4.17 4.09 4.04 4.01 4.06 4.02 4.18 4.16 4.10 3.98
Dimensions Unit Depth mm 3,547 3,547 3,547 4,428 4,428 4,428 4,428 5,329 5,329 6,659 6,659 6,659 6,659
    Height mm 2,335 2,335 2,335 2,335 2,335 2,335 2,335 2,335 2,335 2,280 2,280 2,280 2,280
    Width mm 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254 2,254
Weight Operation weight kg 3,888 3,933 3,978 4,343 4,343 4,408 4,478 4,858 4,858 5,765 6,234 6,474 6,463
  Unit kg 3,750 3,795 3,840 4,210 4,210 4,280 4,350 4,730 4,730 5,525 6,005 6,245 6,245
Water heat exchanger Type   Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube Single pass shell & tube
  Water volume l 138 138 138 133 133 128 128 128 128 240 229 229 218
Air heat exchanger Type   High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler High efficiency fin and tube type with integral subcooler
Fan Air flow rate Cooling Nom. l/s 24,432 24,264 24,095 32,576 32,576 32,628 32,127 40,720 40,720 48,863 48,415 47,732 48,191
  Speed rpm 700 700 700 700 700 700 700 700 700 700 700 700 700
Compressor Quantity   2 2 2 2 2 2 2 2 2 3 3 3 3
  Type   Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor Single screw compressor
Sound power level Cooling Nom. dBA 94 94 94 95 95 95 95 95 95 97 97 97 97
Sound pressure level Cooling Nom. dBA 76 (4) 76 (4) 76 (4) 76 (4) 76 (4) 76 (4) 76 (4) 76 (4) 76 (4) 77 (4) 77 (4) 77 (4) 77 (4)
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 R-134a
  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 1,430
  Circuits Quantity   2 2 2 2 2 2 2 2 2 3 3 3 3
Charge Per circuit kg 43.0 44.0 43.0 46.0 46.5 46.5 47.0 50.0 50.0 47.0 47.0 47.0 49.0
  Per circuit TCO2Eq 61.5 62.9 61.5 65.8 66.5 66.5 67.2 71.5 71.5 67.2 67.2 67.2 70.1
Power supply Phase   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
  Voltage V 400 400 400 400 400 400 400 400 400 400 400 400 400
Compressor Starting method   VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven VFD driven
Notes (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation. (1) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation.
  (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation. (2) - Heating: air exchanger 7.0 - 90%°C; water exchanger 50.0/45.0, unit at full load operation.
  (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825. (3) - SCOP is based on the following conditions: Tbivalent +2°C, Tdesign -10°C, Average ambient conditions, Ref. EN14825.
  (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744 (4) - Sound pressure levels are measured at entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C; full load operation; Standard: ISO3744
  (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%. (5) - Allowed voltage tolerance ± 10%. Voltage unbalance between phases must be within ± 3%.
  (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced. (6) - Maximum starting current: starting current of biggest compressor + current of the other compressors at maximum load + fans current at maximum load. In case of inverter driven units, no inrush current at start up is experienced.
  (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current. (7) - Cooling: entering evaporator water temp. 12°C; leaving evaporator water temp. 7°C; ambient air temp. 35°C. Compressor + fans current.
  (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage. (8) - Maximum unit current for wires sizing is based on minimum allowed voltage.
  (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current (9) - Maximum running current is based on max compressor absorbed current in its envelope and max fans absorbed current
  (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1 (10) - Maximum current for wires sizing: (compressors full load ampere + fans current) x 1.1
  (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water (11) - Fluid: Water
  (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS). (12) - For more details on the operating limits please refer to the Chiller Selection Software (CSS).
  (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels. (13) - Equipment contains fluorinated greenhouse gases. Actual refrigerant charge depends on the final unit construction, details can be found on the unit labels.