Specifications Table for EWYD-BZSL

					EWYD250BZSL	EWYD270BZSL	EWYD290BZSL	EWYD320BZSL	EWYD330BZSL	EWYD360BZSL	EWYD370BZSL	EWYD400BZSL	EWYD430BZSL	EWYD450BZSL	EWYD510BZSLB3	EWYD490BZSL	EWYD530BZSLB3	EWYD510BZSL	EWYD570BZSLB3	EWYD570BZSL
Cooling capacity	Nom.			kW											503		519		569
Capacity control	Method														Variable		Variable		Variable
	Minimum capacity			%											9		9		9
Power input	Cooling		Nom.	kW											178		185		217
EER					2.76	2.66	2.62	2.75	2.68	2.64	2.57	2.66	2.59	2.83	2.82	2.77	2.8	2.73	2.62	2.61
IPLV					4.90	4.96	4.91	5.17	5.08	5.12	5.06	5.22	5.13	5.07	5.03	5.03	4.99	4.99	4.89	4.90
SEER															4.56		4.6		4.55
Dimensions	Unit		Depth	mm											6,659		6,659		6,659
			Height	mm											2,280		2,280		2,280
			Width	mm											2,254		2,254		2,254
Weight	Operation weight			kg											6,234		6,474		6,463
	Unit			kg											6,005		6,245		6,245
Casing	Colour														Ivory white		Ivory white		Ivory white
	Material														Galvanized and painted steel sheet		Galvanized and painted steel sheet		Galvanized and painted steel sheet
Air heat exchanger	Type														High efficiency fin and tube type		High efficiency fin and tube type		High efficiency fin and tube type
Fan	Quantity														12		12		12
	Type														Direct propeller		Direct propeller		Direct propeller
Fan motor	Drive														Direct on line		Direct on line		Direct on line
Compressor	Quantity														3		3		3
	Type														Single screw compressor		Single screw compressor		Single screw compressor
	Starting method														Inverter driven		Inverter driven		Inverter driven
Sound power level	Cooling		Nom.	dBA											97		97		97
Sound pressure level	Cooling		Nom.	dBA											77.2		77.2		77.2
Refrigerant	Type														R-134a		R-134a		R-134a
	GWP														1,430.0		1,430.0		1,430.0
	Charge			kg											141		141		147
	Circuits		Quantity												3		3		3
Piping connections	Evaporator water inlet/outlet (OD)														219.1mm		219.1mm		219.1mm
Power supply	Phase														3~		3~		3~
	Frequency			Hz											50		50		50
	Voltage			V											400		400		400
	Voltage range		Min.	%											-10		-10		-10
			Max.	%											10		10		10
Unit	Starting current		Max	A											0		0		0
	Running current	Cooling	Nom.	A											291		305		305
			Max	A											410		447		447
	Max unit current for wires sizing			A											451		492		492
Cooling capacity	Nom.			kW	247	265	290	315	330	353	370	401	423	446		490		507		565
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	99.5	110	115	123	134	144	151	163	158		177		186		216
Dimensions	Unit		Depth	mm	3547	3547	3547	4428	4428	4428	4428	5329	5329	6659		6659		6659		6659
			Height	mm	2335	2335	2335	2335	2335	2335	2335	2335	2335	2280		2280		2280		2280
			Width	mm	2254	2254	2254	2254	2254	2254	2254	2254	2254	2254		2254		2254		2254
Weight	Operation weight			kg	3888	3933	3978	4343	4343	4408	4478	4858	4858	5765		6234		6474		6463
	Unit			kg	3750	3795	3840	4210	4210	4280	4350	4730	4730	5525		6005		6245		6245
Casing	Colour				Ivory white	Ivory white	Ivory white	Ivory white	Ivory white	Ivory white	Ivory white	Ivory white	Ivory white	Ivory white		Ivory white		Ivory white		Ivory white
	Material				Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet	Galvanized and painted steel sheet		Galvanized and painted steel sheet		Galvanized and painted steel sheet		Galvanized and painted steel sheet
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	Quantity				6	6	6	8	8	8	8	10	10	12		12		12		12
	Type				Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller	Direct propeller		Direct propeller		Direct propeller		Direct propeller
	Air flow rate	Cooling	Nom.	l/s	24432	24264	24095	32576	32576	32628	32127	40720	40720	48863		48415		47732		48191
Fan motor	Drive				DOL	DOL	DOL	DOL	DOL	DOL	DOL	DOL	DOL	DOL		DOL		DOL		DOL
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
	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
Operation range	Air side	Cooling	Min.	°CDB	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10		-10		-10		-10
			Max.	°CDB	45	45	45	45	45	45	45	45	45	45		45		45		45
	Water side	Evaporator	Min.	°CDB	-8	-8	-8	-8	-8	-8	-8	-8	-8	-8		-8		-8		-8
			Max.	°CDB	15	15	15	15	15	15	15	15	15	15		15		15		15
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	76	76	76	76	76	76	76	76	77		77		77		77
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				1430	1430	1430	1430	1430	1430	1430	1430	1430	1430		1430		1430		1430
	Circuits		Quantity		2	2	2	2	2	2	2	2	2	3		3		3		3
Piping connections	Evaporator water inlet/outlet (OD)				139.7mm	139.7mm	139.7mm	139.7mm	139.7mm	139.7mm	139.7mm	139.7mm	139.7mm	219.1mm		219.1mm		219.1mm		219.1mm
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
	Voltage range		Min.	%	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10		-10		-10		-10
			Max.	%	10	10	10	10	10	10	10	10	10	10		10		10		10
Unit	Starting current		Max	A	0	0	0	0	0	0	0	0	0	0		288		311		305
	Running current	Cooling	Nom.	A	147	161	177	187	201	217	230	244	261	258		263		275		319
			Max	A	216	216	216	261	298	298	298	334	362	336		381		415		406
	Max unit current for wires sizing			A	238	238	238	287	328	328	328	367	398	370		381		415		406
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.