Specifications Table for RYYQ-T

					RYYQ8T7Y1B	RYYQ18T7Y1B	RYYQ20T7Y1B	RYYQ30T7Y1B	RYYQ34T7Y1B	RYYQ40T7Y1B	RYYQ50T7Y1B	RYYQ52T7Y1B	RYYQ54T7Y1B	RYYQ10T7Y1B (Archived)	RYYQ12T7Y1B (Archived)	RYYQ14T7Y1B (Archived)	RYYQ16T7Y1B (Archived)	RYYQ22T7Y1B (Archived)	RYYQ24T7Y1B (Archived)	RYYQ26T7Y1B (Archived)	RYYQ28T7Y1B (Archived)	RYYQ32T7Y1B (Archived)	RYYQ36T7Y1B (Archived)	RYYQ38T7Y1B (Archived)	RYYQ42T7Y1B (Archived)	RYYQ44T7Y1B (Archived)	RYYQ46T7Y1B (Archived)	RYYQ48T7Y1B (Archived)
Sound pressure level	Cooling		Nom.	dBA		65.0 (5)	66.0 (5)	66.5 (5)	67.5 (5)	67.0 (5)	69.1 (5)	69.5 (5)	69.8 (5)	58.0 (5)	61.0 (5)	61.0 (5)	64.0 (5)	62.8 (5)	65.0 (5)	64.0 (5)	65.8 (5)	67.0 (5)	68.1 (5)	67.2 (5)	67.5 (5)	68.0 (5)	68.0 (5)	68.8 (5)
Capacity range	HP				8	18	20	30	34	40	50	52	54	10	12	14	16	22	24	26	28	32	36	38	42	44	46	48
Operation range	Cooling		Max.	°CDB		43.0	43.0							43.0	43.0	43.0	43.0
			Min.	°CDB		-5.0	-5.0							-5.0	-5.0	-5.0	-5.0
	Heating		Min.	°CWB		-20.0	-20.0							-20.0	-20.0	-20.0	-20.0
Maximum number of connectable indoor units					64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)	64 (3)
Space cooling	B Condition (30°C - 27/19)		Pdc	kW		37.1	38.3	61.8	70.3	82.4	103.4	107.4	111.4	20.6	24.7	29.5	33.2	45.3	49.7	54.2	57.8	66.3	71.5	75.5	86.9	91.0	95.8	99.5
	D Condition (20°C - 27/19)		Pdc	kW		10.6	10.9	17.7	20.1	23.6	29.6	30.7	31.8	6.9	7.1	8.4	9.5	13.0	14.3	15.5	16.6	18.9	20.4	21.6	24.8	26.0	27.4	28.4
	A Condition (35°C - 27/19)		Pdc	kW		50.4	52.0	83.9	95.4	111.9	140.4	145.8	151.2	28.0	33.5	40.0	45.0	61.5	67.4	73.5	78.5	90.0	97.0	102.4	118.0	123.5	130.0	135.0
	C Condition (25°C - 27/19)		Pdc	kW		23.9	24.6	39.7	45.2	53.0	66.5	69.1	71.6	13.3	15.9	18.9	21.3	29.1	31.9	34.8	37.2	42.6	46.0	48.5	55.9	58.5	61.6	63.9
Compressor	Type					Hermetically sealed scroll compressor	Hermetically sealed scroll compressor							Hermetically sealed scroll compressor	Hermetically sealed scroll compressor	Hermetically sealed scroll compressor	Hermetically sealed scroll compressor
Weight	Unit			kg		391	391							252	252	356	356
Refrigerant	Charge			TCO2Eq		24.4	24.6							12.5	13.2	21.5	21.7
	GWP					2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5	2,087.5
	Charge			kg		11.7	11.8							6.0	6.3	10.3	10.4
	Type					R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A	R-410A
System	Outdoor unit module 2							RYMQ18T	RYMQ18T	RYMQ12T	RYMQ16T	RYMQ18T	RYMQ18T					RYMQ12T	RYMQ16T	RYMQ14T	RYMQ16T	RYMQ16T	RYMQ20T	RYMQ10T	RYMQ16T	RYMQ16T	RYMQ16T	RYMQ16T
	Outdoor unit module 3									RYMQ18T	RYMQ18T	RYMQ18T	RYMQ18T											RYMQ20T	RYMQ16T	RYMQ16T	RYMQ16T	RYMQ16T
	Outdoor unit module 1							RYMQ12T	RYMQ16T	RYMQ10T	RYMQ16T	RYMQ16T	RYMQ18T					RYMQ10T	RYMQ8T	RYMQ12T	RYMQ12T	RYMQ16T	RYMQ16T	RYMQ8T	RYMQ10T	RYMQ12T	RYMQ14T	RYMQ16T
Indoor index connection	Min.					225.0	250.0	375.0	425.0	500.0	625.0	650.0	675.0	125.0	150.0	175.0	200.0	275.0	300.0	325.0	350.0	400.0	450.0	475.0	525.0	550.0	575.0	600.0
	Max.					585.0	650.0	975.0	1,105.0	1,300.0	1,625.0	1,690.0	1,755.0	325.0	390.0	455.0	520.0	715.0	780.0	845.0	910.0	1,040.0	1,170.0	1,235.0	1,365.0	1,430.0	1,495.0	1,560.0
Space heating (Average climate)	TOL		Pdh (declared heating cap)	kW		27.9	31.0	44.4	51.1	58.9	74.3	79.0	83.7	16.0	18.4	20.6	23.2	34.4	36.9	37.1	39.7	46.4	54.2	58.2	60.9	62.9	67.0	69.6
			Tol (temperature operating limit)	°C		-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10
	D Condition (12°C)		Pdh (declared heating cap)	kW		5.8	5.9	6.8	7.9	9.1	11.4	12.1	12.9	6.1	6.2	4.0	4.1	6.2	6.6	6.2	6.2	8.3	8.3	9.0	10.3	10.3	12.3	12.4
	B Condition (2°C)		Pdh (declared heating cap)	kW		15.0	16.7	23.9	27.5	31.7	40.0	42.5	45.1	8.6	9.9	11.1	12.5	18.5	19.8	20.0	21.4	25.0	29.2	31.3	32.8	33.8	36.1	37.4
	C Condition (7°C)		Pdh (declared heating cap)	kW		9.7	10.7	15.4	17.7	20.4	25.7	27.3	29.0	6.5	6.4	7.1	8.0	12.9	12.8	12.8	13.7	16.0	18.8	20.1	21.1	21.9	23.2	24.1
	A Condition (-7°C)		Pdh (declared heating cap)	kW		24.7	27.4	39.3	45.2	52.1	65.7	69.9	74.0	14.2	16.3	18.2	20.5	30.4	32.6	32.8	35.1	41.0	47.9	51.5	53.8	55.6	59.2	61.5
	TBivalent		Pdh (declared heating cap)	kW		27.9	31.0	44.4	51.1	58.9	74.3	79.0	83.7	16.0	18.4	20.6	23.2	34.4	36.9	37.1	39.7	46.4	54.2	58.2	60.9	62.9	67.0	69.6
			Tbiv (bivalent temperature)	°C		-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10	-10
Piping connections	Liquid		OD	mm		15.9	15.9	19.1	19.1	19.1	19.1	19.1	19.1	9.52	12.7	12.7	12.7	15.9	15.9	19.1	19.1	19.1	19.1	19.1	19.1	19.1	19.1	19.1
			Type			Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection
	Total piping length	System	Actual	m		1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)	1,000 (6)
	Gas		OD	mm		28.6	28.6	34.9	34.9	41.3	41.3	41.3	41.3	22.2	28.6	28.6	28.6	28.6	34.9	34.9	34.9	34.9	41.3	41.3	41.3	41.3	41.3	41.3
			Type			Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection	Braze connection
Dimensions	Unit		Width	mm		1,240	1,240							930	930	1,240	1,240
			Depth	mm		765	765							765	765	765	765
			Height	mm		1,685	1,685							1,685	1,685	1,685	1,685
Continuous heating						Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes	Yes
Fan	External static pressure		Max.	Pa		78	78							78	78	78	78
Power supply	Phase					3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~	3N~
	Name					Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1	Y1
	Frequency			Hz		50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50	50
	Voltage			V		380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415	380-415
Piping connections	Heat insulation				Both liquid and gas pipes
Cooling capacity	Nom.		35°CDB	kW	22.4 (1)
			Eurovent	kW	22.4 (28)
Heating capacity	Nom.		6°CWB	kW	22.4 (2)
			Eurovent	kW	22.40 (29)
EER at nom. capacity	35°CDB			KW/KW	4.30 (1)
COP at nom. capacity	6°CWB			KW/KW	4.72 (2)
	Eurovent			KW/KW	5.01 (29)
Indoor index connection	Min.				100
	Nom.				200
	Max.				260
Dimensions	Unit		Height	mm	1685
			Width	mm	930
			Depth	mm	765
Weight	Unit			kg	243
Fan	Air flow rate	Cooling	Nom.	m³/min	162
	External static pressure		Max.	Pa	78
Compressor	Type				Hermetically sealed scroll compressor
Operation range	Cooling		Min.	°CDB	-5
			Max.	°CDB	43
	Heating		Min.	°CWB	-20
			Max.	°CWB	15.5
Sound power level	Cooling		Nom.	dBA	78
Sound pressure level	Cooling		Nom.	dBA	58
Refrigerant	Type				R-410A
	GWP				2087.5
	Charge			tCO2Eq	12.3
	Charge			kg	5.9
Piping connections	Liquid		Type		Braze connection
			OD	mm	9.52
	Gas		Type		Braze connection
			OD	mm	19.1
	Total piping length	System	Actual	m	1000 (7)
	Level difference	OU - IU	Outdoor unit in highest position	m	90 (7)
			Indoor unit in highest position	m	90 (7)
		IU - IU	Max.	m	30 (7)
Standard Accessories	Connection pipes				Connection pipes	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1
	Installation and operation manual				Installation and operation manual
Power supply	Name				Y1
	Phase				3N~
	Frequency			Hz	50
	Voltage			V	380-415
Notes					(1) - Nominal cooling capacities are based on: indoor temperature: 27°CDB, 19°CWB, outdoor temperature: 35°CDB, equivalent refrigerant piping: 5m, level difference: 0m. Data for standard efficiency series	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m	(1) - Cooling: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB; equivalent piping length: 7.5m; level difference: 0m
					(2) - Nominal heating capacities are based on: indoor temperature: 20°CDB, outdoor temperature: 7°CDB, 6°CWB, equivalent refrigerant piping: 5m, level difference: 0m. Data for standard efficiency series	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m	(2) - Heating: indoor temp. 20°CDB; outdoor temp. 7°CDB, 6°CWB; equivalent refrigerant piping: 7.5m; level difference: 0m
					(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)	(3) - Actual number of connectable indoor units depends on the indoor unit type (VRV indoor, Hydrobox, RA indoor, etc.) and the connection ratio restriction for the system (50% <= CR <= 130%)
					(4) - For more details on operation range see TW drawing	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.	(4) - Sound power level is an absolute value that a sound source generates.
					(5) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(5) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.
					(6) - Maximum allowable voltage range variation between phases is 2%.	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual	(6) - Refer to refrigerant pipe selection or installation manual
					(7) - Refer to refrigerant pipe selection or installation manual	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(7) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB
					(8) - For more details on standard accessories refer to Installation/operation manual	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(8) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.
					(9) - RLA is based on following conditions: indoor temp. 27°CDB, 19°CWB; outdoor temp. 35°CDB	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value	(9) - In accordance with EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply wih Ssc ≥ minimum Ssc value
					(10) - MSC means the maximum current during start up of the compressor. This unit uses only inverter compressors. Starting current is always ≤ max. running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.	(10) - MCA must be used to select the correct field wiring size. The MCA can be regarded as the maximum running current.
					(11) - Select wire size based on the value of MCA. The MCA can be regarded as the maximum running current.	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(11) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).
					(12) - MFA is used to select the circuit breaker and the ground fault circuit interrupter (earth leakage circuit breaker).	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.	(12) - TOCA means the total value of each OC set.
					(13) - TOCA means the total value of each OC set.	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan	(13) - FLA means the nominal running current of the fan
					(14) - FLA means the nominal running current of the fan	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.	(14) - Maximum allowable voltage range variation between phases is 2%.
					(15) - In accordance with EN/IEC 61000-3-11, respectively EN/IEC 61000-3-12, it may be necessary to consult the distribution network operator to ensure that the equipment is connected only to a supply with Zsys ≤ Zmax, respectively Ssc ≥ minimum Ssc value.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.	(15) - Voltage range: units are suitable for use on electrical systems where voltage supplied to unit terminal is not below or above listed range limits.
					(16) - European/International Technical Standard setting the limits for voltage changes, voltage fluctuations and flicker in public low-voltage supply systems for equipment with rated current ≤ 75A.	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )	(16) - The AUTOMATIC ESEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation funcitonality ( variable refrigerant temperature )
					(17) - European/International Technical Standard setting the limits for harmonic currents produced by equipment connected to public low-voltage systems with input current >16A and <= 75Aper phase	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality	(17) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality
					(18) - Short-circuit power	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.	(18) - Sound values are measured in a semi-anechoic room.
					(19) - system impedance	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA	(19) - Soundpressure system [dBA] = 10*log[10^(A/10)+10^(B/10)+10^(C/10)] , with Unit A = A dBA, Unit B = B dBA, Unit C = C dBA
					(20) - Multi combination (22~54HP) data is corresponding with the standard multi combination as mentioned on 3D079534	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase	(20) - EN/IEC 61000-3-12: European/international technical standard setting the limits for harmonic currents produced by equipment connected to public low-voltage system with input current > 16A and ≤ 75A per phase
					(21) - Sound power level is an absolute value that a sound source generates.	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power	(21) - Ssc: Short-circuit power
					(22) - Sound pressure level is a relative value, depending on the distance and acoustic environment. For more details, please refer to the sound level drawings.	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual	(22) - For detailed contents of standard accessories, see installation/operation manual
					(23) - Sound values are measured in a semi-anechoic room.	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination	(23) - Multi combination (22~54HP) data is corresponding with the standard multi combination
					(24) - The STANDARD ESEER value corresponds with normal VRV4 Heat Pump operation, not taking into account advanced energy saving operation functionality
					(25) - The AUTOMATIC SEER value corresponds with normal VRV4 Heat Pump operation, taking into account advanced energy saving operation functionality ( variable refrigerant temperature control operation)
					(26) - Nominal cooling capacities are based on: indoor temperature: 27°CDB, 19°CWB, outdoor temperature: 35°CDB, equivalent refrigerant piping: 5m, level difference: 0m. Data for high efficiency series, Eurovent certified
					(27) - Nominal heating capacities are based on: indoor temperature: 20°CDB, outdoor temperature: 7°CDB, 6°CWB, equivalent refrigerant piping: 5m, level difference: 0m. Data for high efficiency series, Eurovent certified
					(28) - Contains fluorinated greenhouse gases
Standard Accessories	Installation manual					1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1
	Operation manual					1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1	1
Operation range	Heating		Max.	°CWB		15.5	15.5							15.5	15.5	15.5	15.5
Space cooling	B Condition (30°C - 27/19)		EERd			3.7	3.6	3.9	3.8	4.0	3.9	3.8	3.7	4.4	4.2	4.3	4.0	4.3	4.0	4.2	4.0	4.0	3.8	3.9	4.1	4.0	4.0	4.0
	D Condition (20°C - 27/19)		EERd			11.8	11.7	10.3	10.9	9.8	10.6	11.2	11.8	8.9	8.7	9.5	10.0	7.6	9.5	9.1	9.4	10.0	10.9	10.0	9.5	9.6	9.9	10.0
	A Condition (35°C - 27/19)		EERd			2.1	1.9	2.2	2.1	2.3	2.1	2.1	2.1	2.7	2.6	2.6	2.1	2.6	2.2	2.6	2.3	2.1	2.0	2.2	2.3	2.2	2.3	2.1
	C Condition (25°C - 27/19)		EERd			6.7	6.6	6.7	6.8	6.7	6.8	6.8	6.7	6.7	6.6	7.0	6.8	6.6	6.7	6.8	6.7	6.8	6.7	6.6	6.8	6.8	6.9	6.8
SCOP						3.6	3.7	3.5	3.6	3.7	3.6	3.6	3.6	3.8	3.8	3.5	3.5	3.8	3.7	3.7	3.6	3.5	3.7	3.7	3.7	3.7	3.5	3.5
Cooling capacity	Prated,c			kW		50.4 (1)	52.0 (1)	83.9 (1)	95.4 (1)	111.9 (1)	140.4 (1)	145.8 (1)	151.2 (1)	28.0 (1)	33.5 (1)	40.0 (1)	45.0 (1)	61.5 (1)	67.4 (1)	73.5 (1)	78.5 (1)	90.0 (1)	97.0 (1)	102.4 (1)	118.0 (1)	123.5 (1)	130.0 (1)	135.0 (1)
Recommended combination						3 x FXMQ50P7VEB + 5 x FXMQ63P7VEB	2 x FXMQ50P7VEB + 6 x FXMQ63P7VEB	9 x FXMQ50P7VEB + 5 x FXMQ63P7VEB	3 x FXMQ50P7VEB + 9 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	9 x FXMQ50P7VEB + 9 x FXMQ63P7VEB	3 x FXMQ50P7VEB + 13 x FXMQ63P7VEB + 4 x FXMQ80P7VEB	6 x FXMQ50P7VEB + 14 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	9 x FXMQ50P7VEB + 15 x FXMQ63P7VEB	4 x FXMQ63P7VEB	6 x FXMQ50P7VEB	1 x FXMQ50P7VEB + 5 x FXMQ63P7VEB	4 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	6 x FXMQ50P7VEB + 4 x FXMQ63P7VEB	4 x FXMQ50P7VEB + 4 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	7 x FXMQ50P7VEB + 5 x FXMQ63P7VEB	6 x FXMQ50P7VEB + 4 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	8 x FXMQ63P7VEB + 4 x FXMQ80P7VEB	2 x FXMQ50P7VEB + 10 x FXMQ63P7VEB + 2 x FXMQ80P7VEB	6 x FXMQ50P7VEB + 10 x FXMQ63P7VEB	12 x FXMQ63P7VEB + 4 x FXMQ80P7VEB	6 x FXMQ50P7VEB + 8 x FXMQ63P7VEB + 4 x FXMQ80P7VEB	1 x FXMQ50P7VEB + 13 x FXMQ63P7VEB + 4 x FXMQ80P7VEB	12 x FXMQ63P7VEB + 6 x FXMQ80P7VEB
Space heating (Average climate)	TOL		COPd (declared COP)			1.8	2.0	1.9	1.8	2.0	1.8	1.8	1.8	2.0	2.1	1.9	1.7	2.1	1.8	2.0	1.9	1.7	1.9	2.1	1.8	1.8	1.8	1.7
	D Condition (12°C)		COPd (declared COP)			7.0	7.0	7.0	6.9	6.7	5.6	7.0	7.1	7.7	8.0	3.9	4.1	8.0	8.4	8.0	8.0	4.1	6.9	6.7	5.7	5.8	4.0	4.1
	B Condition (2°C)		COPd (declared COP)			3.5	3.6	3.4	3.4	3.3	3.4	3.4	3.5	3.2	3.2	3.3	3.3	3.2	3.2	3.3	3.3	3.3	3.5	3.4	3.3	3.3	3.3	3.3
	C Condition (7°C)		COPd (declared COP)			4.4	4.5	4.3	4.9	5.5	5.1	4.7	4.4	6.7	7.0	5.6	5.6	6.9	6.0	5.5	5.4	5.6	4.9	5.4	6.0	6.0	5.6	5.6
	A Condition (-7°C)		COPd (declared COP)			2.5	2.5	2.4	2.3	2.4	2.3	2.4	2.5	2.3	2.3	2.2	2.2	2.3	2.2	2.2	2.2	2.2	2.3	2.4	2.2	2.2	2.2	2.2
	TBivalent		COPd (declared COP)			1.8	2.0	1.9	1.8	2.0	1.8	1.8	1.8	2.0	2.1	1.9	1.7	2.1	1.8	2.0	1.9	1.7	1.9	2.1	1.8	1.8	1.8	1.7
SEER						5.5	5.3	5.5	5.5	5.5	5.5	5.5	5.5	5.6	5.5	5.7	5.5	5.4	5.5	5.6	5.5	5.5	5.4	5.4	5.5	5.5	5.6	5.5
Sound power level	Cooling		Nom.	dBA		86.0 (4)	88.0 (4)	87.2 (4)	89.0 (4)	87.8 (4)	90.8 (4)	90.8 (4)	90.8 (4)	79.0 (4)	81.0 (4)	81.0 (4)	86.0 (4)	83.1 (4)	86.6 (4)	84.0 (4)	87.2 (4)	89.0 (4)	90.1 (4)	88.9 (4)	89.4 (4)	89.6 (4)	89.6 (4)	90.8 (4)
Heating capacity	Prated,h			kW		27.9	31.0	44.4	51.1	58.9	74.3	79.0	83.7	16.0	18.4	20.6	23.2	34.4	36.9	37.1	39.7	46.4	54.2	58.2	60.9	62.9	67.0	69.6