background image

MEES19K180

PURY-H

P-

T(

S)NU-

A, Y(S)

NU-A

 105

12. PIPING DESIGN

Hyper Heating Inverter R2-Series

Piping "A"size selection rule

(mm [in.])

Outdoor Model

Pipe(High pressure)

Pipe(Low pressure)

HP72T/YNU

ø15.88 [5/8"]

ø19.05 [3/4"]

HP96T/YNU

ø19.05 [3/4"]

ø22.20 [7/8"]

HP120T/YNU

ø19.05 [3/4"]

ø28.58 [1-1/8"]

Piping "B", "C", "D", "E" size seleciton rule

(mm [in.])

P55-P72 

ø9.52 [3/8"]

ø19.05 [3/4"]

P73-P96

ø9.52 [3/8"]

ø22.20 [7/8"]

Piping "F", "G", "J", "K" size selection rule

(mm [in.])

Total down-stream Indoor capacity

Pipe(Liquid)

Pipe(HP Gas)

Pipe(LP Gas)

P72 or less

ø9.52 [3/8"]

ø15.88 [5/8"]

ø19.05 [3/4"]

P181 to P234

ø15.88 [5/8"]

ø28.58 [1-1/8"]

ø28.58 [1-1/8"]

P235 to P288

ø19.05 [3/4"]

ø28.58 [1-1/8"]

ø34.93 [1-3/8"]

P289 to P360

ø19.05 [3/4"]

ø28.58 [1-1/8"]

ø41.28 [1-5/8"]

P361 or above

ø19.05 [3/4"]

ø34.93 [1-3/8"]

ø41.28 [1-5/8"]

HP: High pressure, LP: Low pressure

Piping "a", "b", "c", "d", "e", "f", "g", "i", "j", "k", "m", "n" size selection rule

(mm [in.])

Indoor Unit size

Pipe(Liquid)

Pipe(Gas)

P04-P18

ø6.35 [1/4"]

ø12.70 [1/2"]

P24-P54

ø9.52 [3/8"]

ø15.88 [5/8"]

P72

ø9.52 [3/8"]

ø19.05 [3/4"]

P96

ø9.52 [3/8"]

ø22.20 [7/8"]

Total down-stream Indoor capacity

Pipe(Liquid)

Pipe(Gas)

P54 or less

ø9.52 [3/8"]

ø15.88 [5/8"]

P73 to P108

ø9.52 [3/8"]

ø19.05 [3/4"]

ø22.20 [7/8"]

P109 to P126

ø12.70 [1/2"]

ø19.05 [3/4"]

ø28.58 [1-1/8"]

P127 to P144

ø12.70 [1/2"]

ø22.20 [7/8"]

ø28.58 [1-1/8"]

P145 to P180

ø15.88 [5/8"]

ø22.20 [7/8"]

ø28.58 [1-1/8"]

Fig. 2

Fig. 3

Selection criteria for joints_A

P73-P96

CMY-Y102LS-G2

Total down-stream Indoor capacity

Joint

-P72

CMY-Y102SS-G2

Selection criteria for joints_B

P121-P216 CMY-R202S-G

Total down-stream Indoor capacity

Joint

-P120

CMY-R201S-G

*9. When the piping length or the vertical separation exceeds the limit specified in Fig. 2, connect 
      a sub BC to the system.
     The restriction for a system with a sub BC connection is shown in Fig. 3. 
     When a given system configuration falls within the shaded area in Fig. 3, increase the size of 
      the high-pressure pipe and the liquid pipe between the main BC and sub BC by one size. 
      The maximum liquid branch pipe diameter is ø19.05. If a given system already has a ø19.05-pipe
      between the main BC and sub BC, there is no need to increase the pipe size.
      When using P12, P15, P18, P36, or P48 model of indoor units, increase the size of the liquid 
      branch pipe between the sub BC and indoor unit by one size. 
      When using indoor models P54 or larger, the restrictions shown in Fig. 2 cannot be exceeded.

IU

Fig. 2

Fig. 2

Fig. 3

Main

BC

Fig. 2

Fig. 3

IU

IU

SUB

BC

SUB

BC

Piping length and height between IU and BC controller

Height difference between Main BC controller

and farthest indoor unit (ft)

P

ipe length between Main BC

controller and indoor unit (ft)

0

50

100

150

200

250

0

5

10

15

20

25

30

35

40

45

Height difference between Main BC controller

and farthest indoor unit (ft)

P

ipe length between Main BC controller

Sub BC controller

, and indoor unit (ft)

0

50

100

150

250

200

300

0

5

10

15

20

25

30

35

40

45

*9

0000005744.BOOK  105 ページ  2020年2月25日 火曜日 午後5時19分

Summary of Contents for CITY MULTI PURY-HP120TNU-A

Page 1: ...AIR CONDITIONING SYSTEMS MODEL PURY HP72 240T S NU A PURY HP72 240Y S NU A ...

Page 2: ...U A 120K PURY HP120TNU A 72K PURY HP72TNU A Type BTU h Model Name 192K PURY HP192YSNU A 240K PURY HP240YSNU A 144K PURY HP144YSNU A Type BTU h Model Name 192K PURY HP192TSNU A 240K PURY HP240TSNU A 144K PURY HP144TSNU A Type BTU h Model Name Hyper Heating Inverter R2 Series 208 230V Hyper Heating Inverter R2 Series 460V body1 fm 1 ページ 2020年2月25日 火曜日 午後4時28分 ...

Page 3: ...e ET control 70 9 OPTIONAL PARTS 71 9 1 JOINT and REDUCER 71 9 2 OUTDOOR TWINNING KIT 75 9 3 JOINT KIT CMY R160 J1 FOR BC CONTROLLER 76 10 ELECTRICAL WORK 77 10 1 General cautions 77 10 2 Power supply for Outdoor unit 78 10 3 Power cable specifications 79 10 4 Power supply examples 80 11 M NET CONTROL 82 11 1 Transmission cable length limitation 82 11 2 Transmission cable specifications 83 11 3 Sy...

Page 4: ...rnal finish Pre coated galvanized steel sheet MUNSELL 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 17 lbs 10 oz 8 0 kg Control I...

Page 5: ...ized steel sheet MUNSELL 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 23 lbs 12 oz 10 8 kg Control Indoor LEV and BC controller ...

Page 6: ...lvanized steel sheet MUNSELL 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 23 lbs 12 oz 10 8 kg Control Indoor LEV and BC control...

Page 7: ...L 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat protection Over c...

Page 8: ...1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat protection Over current ...

Page 9: ... 5Y 8 1 MUNSELL 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat pro...

Page 10: ...8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 17 lbs 10 oz 8 0 kg Control Indoor LEV and BC controller Net weight lbs kg 644 292 Hea...

Page 11: ...1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 23 lbs 12 oz 10 8 kg Control Indoor LEV and BC controller Net weight lbs kg 697 316 Heat...

Page 12: ... 5Y 8 1 External dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Fan motor Refrigerant Type x original charge R410A x 23 lbs 12 oz 10 8 kg Control Indoor LEV and BC controller Net weight lbs kg 697 31...

Page 13: ... W x D in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat protection Over current protection Fan motor Ref...

Page 14: ...in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat protection Over current protection Fan motor Refrigeran...

Page 15: ... dimension H x W x D in 71 5 8 x 49 1 4 x 29 3 8 71 5 8 x 49 1 4 x 29 3 8 mm 1 818 x 1 250 x 745 1 818 x 1 250 x 745 Protection High pressure protection High pressure sensor High pressure switch at 4 15 MPa 601 psi High pressure sensor High pressure switch at 4 15 MPa 601 psi devices Inverter circuit COMP FAN Over heat protection Over current protection Over heat protection Over current protection...

Page 16: ...hole Top view Front view Left side view Rear view Refrigerant service valve Low pressure Refrigerant service valve High pressure Note 1 Please refer to the next page for information regarding necessary spacing around the unit and foundation work 2 At brazing of pipes wrap the refrigerant service valve with wet cloth and keep the temperature of refrigerant service valve under 120 C 248 F For transm...

Page 17: ...Use four fixing plates as shown in the right figure field supply required when using post installed anchor bolts Fig B 5 To prevent small animals and water and snow from entering the unit and damaging its parts close the gap around the edges of through holes for pipes and wires with filler plates field supply required 6 When the pipes or cables are routed at the bottom of the unit make sure that t...

Page 18: ...ding the straight pipe that is supplied with the Twinning pipe 4 Only use the Twinning pipe by Mitsubishi optional parts Twinning pipe connection size ø28 58 1 1 8 ø22 2 7 8 ø28 58 1 1 8 PURY HP144TSNU A PURY HP72TNU A PURY HP72TNU A PURY HP192TSNU A PURY HP96TNU A PURY HP240TSNU A ø34 93 1 3 8 Low pressure d or f High pressure c or e Unit model Twinning pipe Outdoor unit HP72 ø15 88 5 8 HP96 HP12...

Page 19: ...ew Front view Left side view Rear view Refrigerant service valve Low pressure Refrigerant service valve High pressure Note 1 Please refer to the next page for information regarding necessary spacing around the unit and foundation work 2 At brazing of pipes wrap the refrigerant service valve with wet cloth and keep the temperature of refrigerant service valve under 120 C 248 F For transmission cabl...

Page 20: ...als and water and snow from entering the unit and damaging its parts close the gap around the edges of through holes for pipes and wires with filler plates field supply required 6 When the pipes or cables are routed at the bottom of the unit make sure that the through hole at the base of the unit does not get blocked with the installation base 7 Refer to the Installation Manual when installing uni...

Page 21: ...ding the straight pipe that is supplied with the Twinning pipe 4 Only use the Twinning pipe by Mitsubishi optional parts Twinning pipe connection size ø28 58 1 1 8 ø22 2 7 8 ø28 58 1 1 8 PURY HP144YSNU A PURY HP72YNU A PURY HP72YNU A PURY HP192YSNU A PURY HP96YNU A PURY HP240YSNU A ø34 93 1 3 8 Low pressure d or f High pressure c or e Unit model Twinning pipe Outdoor unit HP72 ø15 88 5 8 HP96 HP12...

Page 22: ... 4 501 19 3 4 501 19 3 4 482 19 484 19 1 16 484 19 1 16 349 13 3 4 350 13 13 16 350 13 13 16 339 13 3 8 340 13 7 16 340 13 7 16 685 27 703 27 11 16 703 27 11 16 683 26 15 16 700 27 9 16 700 27 9 16 PURY HP72TNU A PURY HP96TNU A PURY HP120TNU A PURY HP72YNU A PURY HP96YNU A PURY HP120YNU A 681 26 13 16 745 29 3 8 1818 71 5 8 1515 59 11 16 80 3 3 16 1060 41 3 4 0000005744 BOOK 20 ページ 2020年2月25日 火曜日 ...

Page 23: ...3 Magnetic relay inverter main circuit Z22 24 25 Function setting connector 1 4 7 1 3 1 3 1 LED2 Normal operation Lit Error Blink LED3 SW6 10 is OFF and LED101 SW4 1 10 are OFF In operation Lit In stop Unlit SW6 10 is ON Function setting by SW4 enable Lit disable Unlit Normal operation Lit IC Error Unlit 10 Difference of appliance Model name Appliance LEV1 LEV9 8 Difference of appliance Model name...

Page 24: ...oard 3 1 2 1 2 3 3 1 2 1 2 3 CN202 CN201 red 63LS 63HS1 1 2 CNPOW yellow 1 3 CN3K yellow 1 3 CN3S red 3 1 3 CN3D 1 3 CN3N blue 4 1 CN41 2 3 4 1 CN40 2 3 TP1TP2 TB3 TB7 M1 M2 M1 M2 S Indoor Outdoor transmission cable Central control transmission cable 4 CNAC 3 1 2 2 2 ON OFF X10 X07 X09 5 5 1 1 CN506 red 21S4b Power failure detection circuit CN507 black 3 6 SV9 SV2 X05 X06 3 5 1 6 CN505 SV1a 21S4a ...

Page 25: ...ow 60Hz Sound level of PURY HP120T Y NU A 63 125 250 500 1k 2k 4k 8k dB A Standard Cooling 60Hz 67 0 59 5 58 5 55 5 49 5 45 0 40 5 37 0 56 5 Low noise mode 60Hz 53 5 49 5 42 5 42 0 36 0 29 0 27 5 33 0 43 0 When Low noise mode is set the A C system s capacity is limited The system could return to normal operation from Low noise mode automatically in the case that the operation condition is severe 1...

Page 26: ...URY HP240T Y SNU A 63 125 250 500 1k 2k 4k 8k dB A Standard Cooling 60Hz 70 0 62 5 61 5 58 5 52 5 48 0 43 5 40 0 59 5 Low noise mode 60Hz 56 5 52 5 45 5 45 0 39 0 32 0 30 5 35 5 46 0 When Low noise mode is set the A C system s capacity is limited The system could return to normal operation from Low noise mode automatically in the case that the operation condition is severe 10 20 30 40 50 60 70 80 ...

Page 27: ... Sound level of PURY HP120T Y NU A 63 125 250 500 1k 2k 4k 8k dB A Standard Heating 60Hz 67 0 63 5 59 5 56 5 51 0 47 5 44 5 44 0 58 0 Low noise mode 60Hz 54 0 49 5 42 5 39 5 35 5 31 0 30 5 37 0 43 0 When Low noise mode is set the A C system s capacity is limited The system could return to normal operation from Low noise mode automatically in the case that the operation condition is severe 10 20 30...

Page 28: ...URY HP240T Y SNU A 63 125 250 500 1k 2k 4k 8k dB A Standard Heating 60Hz 70 0 66 0 62 5 59 5 54 0 50 0 47 0 47 0 61 0 Low noise mode 60Hz 57 0 52 5 45 5 42 5 38 5 34 0 33 5 40 0 46 0 When Low noise mode is set the A C system s capacity is limited The system could return to normal operation from Low noise mode automatically in the case that the operation condition is severe 10 20 30 40 50 60 70 80 ...

Page 29: ...n Direct installation on the concrete floor Power source 3 phase 3 wire 208 V 230 V 60 Hz For TNU Series 3 phase 3 wire 460 V 60 Hz For YNU Series Operation condition JIS condition cooling heating Measurement device Vibration level meter for vibration pollution VM 1220C JIS compliant product 20cm 10cm Concrete Service panel side Measurement point Vibration level Model Vibration level dB PURY HP72T...

Page 30: ...door units Installation of the low ambient kit is recommended to operate in cooling and cooling main mode in conditions under 50 F 10 C 30 25 20 15 5 0 20 15 10 5 0 5 10 15 20 25 30 35 40 45 50 4 5 14 23 32 41 50 59 68 77 86 95 104 113 122 4 5 14 23 32 41 50 59 68 77 86 95 104 113 122 Indoor temperature Outdoor temperature 40 25 20 15 10 0 86 77 68 59 41 32 10 50 104 35 95 30 86 77 68 59 50 32 5 4...

Page 31: ...r R2 Series 8 CAPACITY TABLES Section 8 1 Shows an example of how to select the indoor and outdoor units according to the required heating cooling load Section 8 2 through 8 6 Show the actual correction data of indoor and outdoor units 0000005744 BOOK 29 ページ 2020年2月25日 火曜日 午後5時19分 ...

Page 32: ...select smaller outdoor unit Does it fulfill the load of each room Outdoor Unit Input Rated Outdoor Unit Input cave Determine the load L and the Indoor Outdoor Temperature n Total Number of Indoor Units k Indoor Unit Number Yes No No No No Yes No No Yes Yes Capacity Determination Input Calculation Average Indoor temp power input Coef cave Average Indoor temp power input Coef cave cave ck Mk Mk n k ...

Page 33: ... indoor Fig 4 Correction of refrigerant piping length The purpose of this flow chart is to select the indoor and outdoor units For other purposes this flow chart is intended only for reference Average Indoor temp power input Coef cave cave ck Mk Mk n k 1 n k 1 Outdoor Unit Input Rated Outdoor Unit Input cave Model Size Ratio Fig 3 x x x is the approximate correction function when greater than 100 ...

Page 34: ...6 Refer to Fig 1 CTi Σ Indoor Unit Rating Indoor Design Temperature Correction 10 6 1 02 10 6 0 96 20 9 kW 5 Outdoor Unit Correction Calculation Outdoor Design Dry Bulb Temperature Correction 37ºC 0 99 Refer to Fig 2 Piping Length Correction 30 m 0 95 Refer to Fig 3 Total Outdoor Unit Capacity CTo Total Indoor Units Capacity CTi CTo Outdoor Rating Outdoor Design Temperature Correction Piping Lengt...

Page 35: ...Design Temperature Correction Piping Length Correction Defrost Correction 23 4 0 98 0 98 0 84 18 8 kW 6 Determination of Maximum System Capacity CTx Comparison of Capacity between Total Indoor Units Capacity CTi and Total Outdoor Unit Capacity CTo CTi 18 7 CTo 18 8 thus select CTi CTx CTi 18 7 kW 7 Comparison with Essential Load Against the essential load 18 2kW the maximum system capacity is 18 7...

Page 36: ...oefficient Coefficient of the outdoor unit for indoor unit 1 Outdoor temp 37 CD B Indoor temp 20 CW B Maximum System Capacity CTx Total Outdoor unit Capacity CTo so use the following formula PIo Outdoor unit Cooling Rated Power Input Correction Coefficient of Indoor temperature 4 55 1 06 4 82 kW 1 03 Coefficient of the outdoor unit for indoor unit 2 Outdoor temp 37 CD B Indoor temp 17 8 CW B 1 09 ...

Page 37: ...cient Coefficient of the outdoor unit for indoor unit 1 Outdoor temp 2 CW B Indoor temp 25 CD B Maximum System Capacity CTx Total Indoor unit Capacity CTi so use the following formula PIo Outdoor unit Heating Rated Power Input Correction Coefficient of Indoor temperature CTi CTo 5 48 0 8 0 94 4 12 kW 0 80 Coefficient of the outdoor unit for indoor unit 2 Outdoor temp 2 CW B Indoor temp 25 CD B 0 8...

Page 38: ...000 1 02 36 000 0 96 71 200 BTU h 5 Outdoor Unit Correction Calculation Outdoor Design Dry Bulb Temperature Correction 99ºF 0 99 Refer to Fig 2 Piping Length Correction 100 ft 0 95 Refer to Fig 3 Total Outdoor Unit Capacity CTo Total Indoor Units Capacity CTi CTo Outdoor Rating Outdoor Design Temperature Correction Piping Length Correction 72 000 0 99 0 95 67 700 BTU h 6 Determination of Maximum S...

Page 39: ...ination of Maximum System Capacity CTx Comparison of Capacity between Total Indoor Units Capacity CTi and Total Outdoor Unit Capacity CTo CTi 64 000 CTo 67 000 thus select CTi CTx CTi 64 000 BTU h 7 Comparison with Essential Load Against the essential load 62 000BTU h the maximum system capacity is 64 000BTU h Proper outdoor units have been selected 8 Calculation of Maximum Indoor Unit Capacity of...

Page 40: ...coefficient Coefficient of the outdoor unit for indoor unit 1 Outdoor temp 99 FD B Indoor temp 68 FW B Maximum System Capacity CTx Total Outdoor unit Capacity CTo so use the following formula PIo Outdoor unit Cooling Rated Power Input Correction Coefficient of Indoor temperature 4 55 1 06 4 82 kW 1 03 Coefficient of the outdoor unit for indoor unit 2 Outdoor temp 99 FD B Indoor temp 64 FW B 1 09 3...

Page 41: ...nt Coefficient of the outdoor unit for indoor unit 1 Outdoor temp 35 6 FW B Indoor temp 77 FD B Maximum System Capacity CTx Total Indoor unit Capacity CTi so use the following formula PIo Outdoor unit Heating Rated Power Input Correction Coefficient of Indoor temperature CTi CTo 5 48 0 8 0 92 4 03 kW 0 80 Coefficient of the outdoor unit for indoor unit 2 Outdoor temp 35 6 FW B Indoor temp 77 FD B ...

Page 42: ...YNU PURY 72 000 21 1 5 22 69 000 20 2 4 74 4 91 Non Ducted Ducted Input Input Indoor unit temperature correction Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor ...

Page 43: ...door unit temperature correction To be used to correct outdoor unit only Outdoor unit capacity is NOT affected by the indoor temperature Outdoor unit power input is affected by the indoor and outdoor temperatures Please consult the sales office for details Ratio of power input 30 22 25 13 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 Indoor Temperature CW B FW B Outdoor Temperature 1 8 2 0 2 2 2 4 2 ...

Page 44: ... Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B ...

Page 45: ...t is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 2 1 1 Indoor Temperature CD B FD B Ratio of heating capacity Ratio of power input 30 22 25 13 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 Indoor Temperature CW B FW B Outdoor Temperature 1 8 2 0 2 2 2 4 2...

Page 46: ...n Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B...

Page 47: ...ut is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 2 1 1 Indoor Temperature CD B FD B Ratio of heating capacity 1 1 0 9 0 8 0 7 0 6 0 5 0 4 0 3 1 0 1 2 Ratio of heating capacity Ratio of power input 30 22 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 30 22...

Page 48: ...tion Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 C...

Page 49: ...nput is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 2 1 1 Indoor Temperature CD B FD B Ratio of heating capacity Ratio of power input 30 22 25 13 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 Indoor Temperature CW B FW B Outdoor Temperature 1 8 2 0 2 2 2 ...

Page 50: ...ection Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B To be used to correct indoor unit capacity only 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B 61 FW B 15 0 CW B 59 FW B Indoor Temperature Ratio of cooling capacity 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72...

Page 51: ...nput is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 2 1 1 Indoor Temperature CD B FD B Ratio of heating capacity Ratio of power input 30 22 25 13 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 Indoor Temperature CW B FW B Outdoor Temperature 27 0 CD B 81 F...

Page 52: ...tion Ratio of cooling capacity Ratio of power input Indoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B 61 FW B 15 0 CW B 59 FW B CD B FD B Indoor Temperature Ratio of cooling capacity 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Outdoor Temperature To be used to corr...

Page 53: ...nput is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 2 1 1 Indoor Temperature CD B FD B Ratio of heating capacity Ratio of heating capacity Ratio of power input 30 22 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 30 22 25 13 25 13 20 4 15 5 10 14 5 23 0 32...

Page 54: ...ing capacity BTU h kW kW BTU h kW kW HP72TNU YNU PURY 72 000 21 1 5 22 69 000 20 2 4 74 4 91 Non Ducted Ducted Input Input Indoor unit temperature correction Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Ratio of cooling capacity CD B FD B Ratio of power input In...

Page 55: ...unit temperature correction To be used to correct outdoor unit only Outdoor unit capacity is NOT affected by the indoor temperature Outdoor unit power input is affected by the indoor and outdoor temperatures Please consult the sales office for details CW B FW B Indoor Temperature CW B FW B 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0 9 1 1 Ratio of heating capacity Ratio of power input 30 22 20 4 15 5 10 14 ...

Page 56: ... Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B ...

Page 57: ... is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 1 Indoor Temperature CD B FD B Ratio of heating capacity 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0 9 1 1 Ratio of heating capacity Ratio of power input 30 22 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 30 22 25 13...

Page 58: ...n Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B...

Page 59: ...t is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 1 Indoor Temperature CD B FD B Ratio of heating capacity CW B FW B Indoor Temperature CW B FW B 27 0 CD B 81 FD B 25 0 CD B 77 FD B 21 1 CD B 70 FD B 15 0 CD B 59 FD B 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0 9...

Page 60: ...tion Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B Indoor Temperature Ratio of cooling capacity To be used to correct indoor unit capacity only 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 C...

Page 61: ...put is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 1 Indoor Temperature CD B FD B Ratio of heating capacity CW B FW B Indoor Temperature CW B FW B 27 0 CD B 81 FD B 25 0 CD B 77 FD B 21 1 CD B 70 FD B 15 0 CD B 59 FD B 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0...

Page 62: ...ection Ratio of cooling capacity CD B FD B Ratio of power input Indoor Temperature Outdoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B To be used to correct indoor unit capacity only 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B 61 FW B 15 0 CW B 59 FW B Indoor Temperature Ratio of cooling capacity 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72...

Page 63: ... FW B Indoor Temperature CW B FW B 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0 9 1 1 Ratio of heating capacity Ratio of power input 30 22 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 30 22 25 13 25 13 20 4 15 5 10 14 5 23 0 32 5 41 10 50 15 59 Outdoor Temperature Outdoor Temperature 0 9 1 0 1 1 1 2 0 8 0 7 0 6 0 4 0 5 Outdoor unit temperature correction To be used to correct outdoor unit only Outdoor unit cap...

Page 64: ...tion Ratio of cooling capacity Ratio of power input Indoor Temperature Outdoor Temperature 23 9 CW B 75 FW B 22 2 CW B 72 FW B 20 0 CW B 68 FW B 17 8 CW B 64 FW B 19 4 CW B 67 FW B 16 1 CW B 61 FW B 15 0 CW B 59 FW B CD B FD B Indoor Temperature Ratio of cooling capacity 15 16 17 18 19 20 21 22 23 24 CW B 59 61 63 64 66 68 70 72 73 75 FW B 0 8 0 9 1 0 1 1 1 2 Outdoor Temperature To be used to corr...

Page 65: ...put is affected by the indoor and outdoor temperatures Please consult the sales office for details 15 16 17 18 19 20 21 22 23 27 26 25 24 59 61 63 64 66 68 70 72 73 81 79 77 75 0 6 0 7 0 8 0 9 1 0 1 1 Indoor Temperature CD B FD B Ratio of heating capacity CW B FW B Indoor Temperature CW B FW B 27 0 CD B 81 FD B 25 0 CD B 77 FD B 21 1 CD B 70 FD B 15 0 CD B 59 FD B 1 0 0 8 0 7 0 6 0 5 0 2 0 3 0 4 0...

Page 66: ...ing capacity Rated cooling capacity BTU h kW kW BTU h kW kW HP72TNU YNU PURY 72 000 21 1 5 22 69 000 20 2 4 74 4 91 Non Ducted Ducted Input Input Nominal Heating capacity Rated Heating capacity BTU h kW kW BTU h kW kW HP72TNU YNU PURY 80 000 23 4 5 66 76 000 22 3 5 12 5 36 Non Ducted Ducted Input Input Nominal cooling capacity Rated cooling capacity BTU h kW kW BTU h kW kW HP96TNU YNU PURY 96 000 ...

Page 67: ...minal Heating capacity Rated Heating capacity BTU h kW kW BTU h kW kW HP120TNU YNU PURY 135 000 39 6 10 07 129 000 37 8 9 01 9 63 Non Ducted Ducted Input Input Nominal cooling capacity Rated cooling capacity BTU h kW kW BTU h kW kW HP144TSNU YSNU PURY 144 000 42 2 11 92 138 000 40 4 10 73 11 34 Non Ducted Ducted Input Input Nominal Heating capacity Rated Heating capacity BTU h kW kW BTU h kW kW HP...

Page 68: ...000 60 4 15 04 15 49 Non Ducted Ducted Input Input Total capacity of indoor units Ratio of capacity Ratio of power input PURY HP240TSNU YSNU A 100 200 300 250 150 400 350 1 2 1 0 0 8 0 6 0 4 1 0 0 8 0 6 0 4 1 2 Nominal cooling capacity Rated cooling capacity BTU h kW kW BTU h kW kW HP240TSNU YSNU PURY 240 000 70 3 20 08 228 000 66 8 18 72 18 45 Non Ducted Ducted Input Input Nominal Heating capacit...

Page 69: ... 0 80 0 95 0 85 0 75 0 65 0 70 Cooling capacity correction factor PURY HP192TSNU YSNU Total capacity of indoor unit 96 144 192 288 0 100 200 300 400 500 600 ft Piping equivalent length 1 0 90 0 80 0 95 0 85 0 75 0 65 0 70 Cooling capacity correction factor 0 31 61 92 122 153 183 m PURY HP96TNU YNU Total capacity of indoor unit 48 72 96 144 0 100 200 300 400 500 600 ft Piping equivalent length 1 0 ...

Page 70: ...city correction factor 0 85 0 90 0 95 1 00 ft Piping equivalent length 15 0 31 46 61 76 92 107 122 137 153 168 183 m PURY HP144 192TSNU YSNU 0 80 50 0 100 150 200 250 300 350 400 450 500 550 600 Heating capacity correction factor 0 85 0 90 0 95 1 00 ft Piping equivalent length 15 0 31 46 61 76 92 107 122 137 153 168 183 m PURY HP96 120TNU YNU 0 80 50 0 100 150 200 250 300 350 400 450 500 550 600 H...

Page 71: ...1 64 x number of bent on the piping ft Equivalent length Actual piping length to the farthest indoor unit 0 50 x number of bent on the piping m 4 PURY HP144TSNU YSNU Equivalent length Actual piping length to the farthest indoor unit 1 64 x number of bent on the piping ft Equivalent length Actual piping length to the farthest indoor unit 0 50 x number of bent on the piping m 5 PURY HP192TSNU YSNU E...

Page 72: ...5 0 95 PURY HP96TNU A 1 00 0 95 0 84 0 83 0 83 0 87 0 90 0 93 0 93 0 95 0 95 PURY HP120TNU A 1 00 0 93 0 85 0 83 0 84 0 86 0 90 0 90 0 92 0 95 0 95 PURY HP144TSNU A 1 00 0 98 0 89 0 86 0 88 0 90 0 91 0 92 0 92 0 95 0 95 PURY HP192TSNU A 1 00 0 98 0 89 0 86 0 88 0 90 0 91 0 92 0 92 0 95 0 95 PURY HP240TSNU A 1 00 0 94 0 84 0 86 0 87 0 88 0 90 0 90 0 92 0 95 0 95 PURY HP72YNU A 1 00 0 95 0 84 0 83 0...

Page 73: ...ameter in CMY Y102LS G2 Reducer Accessory Reducer Accessory 2 Pcs 2 Pcs 2 Pcs Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter 1 5 8 1 11 16 2 3 16 ø7 8 ø1 ø3 4 ø3 4 ø1 2 ø3 4 ø1 ø1 ø3 4 ø5 8 ø7 8 2 Pcs Outside diameter Outside diameter 1 9 16 3 1 1 2 1 3 16 2 3 16 1 13 16 ø1 ø1 1 8 ø3 4 ø1 ø5 8 ø1 ø3 8 ø1 2 ø1 2 1 5 8 13 16 ø1 ...

Page 74: ... ø1 ø1 ø1 1 8 ø3 4 ø1 ø7 8 ø1 ø7 8 ø3 4 ø5 8 ø1 2 ø5 8 ø1 2 ø3 8 ø5 8 ø5 8 ø3 8 ø1 2 ø5 8 For High pressure For Low pressure For Liquid line Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Cover 3 Pcs in CMY R203S G For High pressure For Low pressure For Liquid...

Page 75: ...meter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter 1 1 16 2 5 8 1 3 16 3 9 16 1 13 16 1 5 8 1 11 16 1 3 16 2 3 4 2 3 16 1 1 2 2 3 4 1 3 16 3 9 16 2 3 4 1 13 16 2 3 16 1 13 16 1 5 8 1 11 16 2 3 16 2 3 16 1 5 8 1 13 16 15 16 3 Pcs 2 Pcs 2 Pcs 2 Pcs 2 Pcs 2 Pcs...

Page 76: ...er Outside diameter Outside diameter Outside diameter Outside diameter 2 Pcs 2 Pcs 2 Pcs ø1 1 8 ø1 3 8 ø1 1 8 ø7 8 ø7 8 ø3 4 ø5 8 ø3 4 ø1 1 2 ø1 5 8 ø1 1 2 ø1 3 8 in CMY R304S G1 Note Pipe diameter is indicated by inside diameter 3 3 16 3 3 16 3 3 16 3 3 16 3 3 16 1 31 32 2 3 4 Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter Outside diameter 2 ...

Page 77: ... 1 2 588 23 3 16 505 19 15 16 160 6 5 16 62 32 2 3 8 60 2 1 2 62 Unit mm in CMY R200NCBK Deformed pipe Accessory ø25 4 ø1 Outside diameter Twinning pipe ø28 58 ø1 3 16 ø28 58 ø1 3 16 Outside diameter Local brazing ø22 2 ø7 8 ø22 2 ø7 8 Pipe cover Dot dashed ø25 4 ø1 Outside diameter Note 2 High pressure twinning pipe Low pressure twinning pipe ø19 05 ø3 4 ø19 05 ø3 4 ø22 2 ø7 8 ø28 58 ø1 3 16 ø22 ...

Page 78: ...e done Details is available at the Installation Manual Joint kit CMY R160 J1 for BC controller is used to combine 2 ports of the BC controller at a PURY PQRY system so as to enable down stream Indoor capacity above P54 as shown in Fig 1 ø15 88 5 8 ø9 52 3 8 ø19 05 3 4 ø9 52 3 8 ø15 88 5 8 ø9 52 3 8 226 8 29 32 226 8 29 32 60 2 3 8 60 2 3 8 Instruction This sheet Please prepare the following items ...

Page 79: ...ometimes removed at the time of service work Never connect 100V 208 230 460V power source to terminal block of transmission cable If connected electrical parts will be damaged When extending the transmission line make sure to extend the shield cable as well wiring so that it is not influenced by electric noise from power source wiring Do not insert transmission cable and power Use 2 core shield ca...

Page 80: ...U A 38 35 60 50 4 0 15 0 46 0 46 PURY HP72TNU A 38 35 60 50 4 0 15 0 46 0 46 PURY HP192TSNU A PURY HP96TNU A 44 40 70 60 5 6 15 0 46 0 46 PURY HP96TNU A 44 40 70 60 5 6 15 0 46 0 46 PURY HP240TSNU A PURY HP120TNU A 47 44 70 60 7 8 15 0 46 0 46 PURY HP120TNU A 47 44 70 60 7 8 15 0 46 0 46 PURY HP Y S NU Model name Combination Outdoor Units Compressor Fan Hz Volts Voltage range MCA A MOP A Output kW...

Page 81: ...or less 4 Specific wiring requirements should adhere to the wiring regulations of the region 5 Power supply cords of parts of appliances for outdoor use shall not be lighter than polychloroprene sheathed flexible cord design 245 IEC57 For example use wiring such as YZW 6 A switch with at least 3 mm 1 8 in contact separation in each pole shall be provided by the Air Conditioner installer 7 For deta...

Page 82: ...ntroller should not be grouped together When a PAR CT01MAU or PAR 40MAAU is connected to a group no other MA remote controllers can be connected to the same group 6 To wire PAC YT53CRAU use a wire with a diameter of 0 3mm2 AWG 22 8 If using 1 or 2 main sub MA remote controller to control more than 1 Indoor unit use MA transmission cable to connect all the TB15 terminals of the Indoor units It is c...

Page 83: ...means shield wire 5 MA R C transmission cable 0 3 1 25mm2 must be less than 200m in length while ME R C transmission cable 0 3 1 25mm2 must be less than 10m in length But transmission cable to the ME R C can be extend using a M NET cable 1 25mm2 when the length is counted in the M Net length 6 To wire PAC YT53CRAU use a wire with a diameter of 0 3mm2 AWG 22 8 If using 1 or 2 main sub MA remote con...

Page 84: ... length from ME to Indoor e1 e2 e3 e4 10m 32ft 1 0 3 1 25 mm2 AWG22 16 1 24VDC to AG 150A A n 50m 164ft 0 75 2 0 mm2 AWG18 14 1 If the length from ME to Indoor exceed 10m use 1 25 mm2 AWG16 shielded cable but the total length should be counted into Max length via Outdoor M2 TB7 TB3 IC 52 M1M2 1 2 S TB5 TB15 1 2 TB15 1 2 TB15 1 2 TB15 1 2 TB15 1 2 TB 15 1 2 TB15 MA 01 IC M1M2S TB5 02 IC M1M2S TB5 0...

Page 85: ...PVC insulated PVC sheathed shielded control cable CPEVS PE insulated PVC sheathed shielded communication cable 1 To wire PAR CT01MAU PAR 40MAAU and PAC YT53CRAU use a wire with a diameter of 0 3 mm2 AWG22 CVV PVC insulated PVC sheathed control cable Max length 200m 656ft Li MA Remote controller cables When 10m 32ft is exceeded use cables with the same specification as transmission cables More than...

Page 86: ... and the number of connected units for M NET In order to ensure proper communication among Outdoor Heat source unit Indoor unit Lossnay and Controllers the trans mission power situation for the M NET should be observed In some cases Transmission booster should be used Taking the power consumption of Indoor unit as 1 the equivalent power consumption or supply of others are listed at Table 1 and Tab...

Page 87: ...re indoor units listed in Table 3 is connected subtract 3 from the equivalent power supply Category Model The equivalent power supply Transmission Booster PAC SF46EPA G 25 1 Power supply unit PAC SC51KUA 5 Expansion controller PAC YG50ECA 6 BM ADAPTER BAC HD150 6 System controller AE 200A AE 50A 0 75 EW 50A 1 5 LM AP 0 Outdoor Heat source unit TB3 and TB7 total TB7 only TB3 only Outdoor unit other...

Page 88: ...ET transmission lines Indoor Outdoor Heat source transmission lines Fig 11 3 3 C When using PAC SC51KUA to supply transmission power the power supply connector CN41 on the Outdoor Heat source units should be kept as it is It is also a factory setting 1 PAC SC51KUA supports maximum 1 AG 150A A or 1 EB 50GU A unit due to the limited power 24VDC at its TB3 However 1 PAC SC51KUA supplies transmission ...

Page 89: ...d The power supply unit PAC SC51KUA is not necessary The expansion controller supplies power through TB3 which equals 6 indoor units refer to Table 2 11 3 6 Power supply to BM ADAPTER 1 phase 100 240VAC power supply is needed The power supply unit PAC SC51KUA is not necessary when only BM ADAPTER is connected Yet make sure to move the power jumper from CN41 to CN40 on the BM ADAPTER 11 3 7 Power s...

Page 90: ...d the other as the sub remote controller No units with identical unit address shall exist in one whole air conditioner system If set erroneously the system can not operate 012 3 4 5 6 7 8 9 A B C D E F 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 The factory setting is Main Setting the dip switches There are switches on the back of the top case Remote controller Main Sub and other function settings are...

Page 91: ...ollowing order 1 Indoor unit to be connected to the BC controller Main 2 Indoor unit to be connected to the BC controller No 1 Sub 3 Indoor unit to be connected to the BC controller No 2 Sub Set the address so that 1 2 3 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 PAC YG60MCA 01 50 P...

Page 92: ...ission power supply from TB7 of one of outdoor units is risking that the outdoor unit failure may let down the whole central control system 11 4 3 1 MA remote controller Single refrigerant system No System Controller 1 Outdoor units OC and OS in one refrigerant circuit system are automatically detected OC and OS are ranked in descending order of capacity If units are the same capacity they are ran...

Page 93: ... are the same capacity they are ranked in ascending order of their address Indoor unit MA R C MA R C Main Sub MA R C 1 For Wireless R C and Signal receiver unit SRU channel 1 2 and 3 are selectable and should be set to same channel SC can be connected to TB3 side or TB7 side Should SC connected to TB7 side change Jumper from CN41 to CN40 at the Outdoor unit module so as to supply power to the SC U...

Page 94: ... Outdoor units OC and OS in one refrigerant circuit system are automatically detected OC and OS are ranked in descending order of capacity If units are the same capacity they are ranked in ascending order of their address 2 System controller should connect to TB7 at Outdoor and use power supply unit together in Multi Refrigerant System For AE 200A AE 50A and EW 50A the power supply unit PAC SC51KU...

Page 95: ... should be set with a branch number 11 4 3 5 ME remote controller Single refrigerant system System controller Lossnay 2 Address should be set to Indoor units Lossnay central controller ME remote controllers 3 For a system having more than 32 indoor unit confirm the need of Booster at 11 3 System configuration restrictions NOTE ME R C ME R C Indoor unit ME R C 104 105 155 01 04 05 TB5 TB5 TB5 ME R ...

Page 96: ...and EW 50A the power supply unit PAC SC51KUA is unused 01 02 03 30 TB5 BC controller Main 53 TB02 BC controller Sub 80 TB02 BC controller TB02 TB5 TB5 TB2 Transmission Booster PAC SF46EPA G TB5 TB3 ME R C ME R C Indoor unit ME R C 144 145 195 130 41 93 44 45 TB5 TB5 TB5 ME R C 141 ME R C 101 ME R C 102 Group 2 Group 1 Group 21 Group 31 Group 33 Group 34 TB3 TB7 TB7 TB7 TB7 TB7 TB3 52 51 OC OS TB3 ...

Page 97: ...roller 53 TB02 BC controller 57 TB02 TB7 TB3 56 CN41 CN40 OFF DipSW5 1 TB3 TB7 TB7 TB3 52 51 CN41 CN40 CN41 CN40 OFF DipSW5 1 OFF DipSW5 1 OC OC OS NOTE It is necessary to change the connecter to CN40 on the outdoor unit control board only one outdoor unit when the group is set between other refrigerant systems Up to three System controllers can be connected to TB3 side SC 201 11 4 3 9 ME remote c...

Page 98: ...n Booster PAC SF46EPA G TB5 ME R C 101 102 130 180 TB3 Group 2 Group 1 Group 21 TB7 TB7 TB7 TB3 TB3 52 51 OC OS TB3 91 OC CN41 CN40 CN41 CN40 CN41 CN40 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ME R C ME R C Indoor unit ME R C ME R C 142 144 145 195 41 42 43 44 45 TB5 TB5 TB5 TB5 TB5 Group 32 Group 31 Group 33 Group 34 ME R C 141 PURY PURY PURY PURY Two outdoor units One outdoor unit 1 TG 2000A Ver 6 5 ...

Page 99: ...TB3 52 51 OC OS1 TB3 51 OC CN41 CN40 CN41 CN40 CN41 CN40 CN41 CN40 CN41 CN40 CN41 CN40 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 Indoor unit ME R C ME R C ME R C 01 02 03 30 TB5 TB5 TB5 TB2 Transmission Booster PAC SF46EPA G TB5 ME R C 101 102 130 180 TB3 Group 2 Group 1 Group 21 TB3 TB3 TB7 TB7 TB7 TB7 TB7 TB7 TB3 53 52 51 OC OS1 OS2 TB3 TB3 92 91 OC OS1 TB3 96 OC CN...

Page 100: ...TB7 TB3 TB3 52 51 OC OS TB3 51 OC CN41 CN40 CN41 CN40 CN41 CN40 OFF DipSW5 1 OFF DipSW5 1 OFF DipSW5 1 Indoor unit ME R C ME R C 01 02 03 30 TB5 BC controller Main 53 TB02 BC controller Sub 80 BC controller Sub 94 TB02 TB02 BC controller Main 93 TB02 TB5 TB5 TB2 Transmission Booster PAC SF46EPA G TB5 ME R C 101 102 130 TB3 Group 2 Group 1 Group 21 TB3 TB7 TB7 TB7 TB7 TB7 TB3 52 51 OC OS TB3 TB3 92...

Page 101: ...N41 CN40 CN41 CN40 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 Indoor unit ME R C ME R C ME R C 01 02 03 30 TB5 TB5 TB5 TB2 Transmission Booster PAC SF46EPA G TB5 ME R C 101 102 130 180 TB3 Group 2 Group 1 Group 21 TB3 TB3 TB7 TB7 TB7 TB7 TB7 TB3 52 51 OC OS TB3 92 91 OC OS TB3 96 OC CN41 CN40 CN41 CN40 CN41 CN40 CN41 CN40 CN41 CN40 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ON DipSW5 1 ME R C ME R C...

Page 102: ... S NU A 100 12 PIPING DESIGN Hyper Heating Inverter R2 Series 12 PIPING DESIGN Section 12 2 Explains the piping design including piping length limitation and piping size selection rule 0000005744 BOOK 100 ページ 2020年2月25日 火曜日 午後5時19分 ...

Page 103: ...on the Japanese standards and provided only as a reference Use pipes that meet the local standards Size mm Size inch Radial thickness mm Pipe type ø6 35 ø1 4 0 8 Type O ø9 52 ø3 8 0 8 Type O ø12 7 ø1 2 0 8 Type O ø15 88 ø5 8 1 0 Type O ø19 05 ø3 4 1 2 Type O ø19 05 ø3 4 1 0 Type 1 2H or H ø22 2 ø7 8 1 0 Type 1 2H or H ø25 4 ø1 1 0 Type 1 2H or H ø28 58 ø1 1 8 1 0 Type 1 2H or H ø31 75 ø1 1 4 1 1 T...

Page 104: ... horizontally and C must be installed upward higher than the horizontal plane of A and B 2 Branches on the outdoor heat source unit side Inclination of the twinning pipes The inclination of the twinning pipes must be 15 or less against the horizontal plane Excessive inclination of the branched pipes may damage the unit Minimum length of the straight section of the pipe before the branched pipes Al...

Page 105: ... in the same group to make them run stop in the same mode all together For other options enable the thermo setting on the remote controller or set the common thermostat optional to run stop the units in the same mode based on a representative temperature Note7 Indoor capactiy is described as its model size For example PEFY P24NMAU E3 its capacity is P24 Note8 Total down stream Indoor capacity is t...

Page 106: ...odel size For example PEFY P24NMAU E3 its capacity is P24 Note9 Total down stream Indoor capacity is the summary of the model size of Indoors down stream For example PEFY P24NMAU E3 PEFY P06NMAU E3 Total Indoor capacity P24 P06 P30 Note10 To connect the BC controller to the main pipe use the reducer CMY R301S G CMY R302S G1 or CMY R304S G1 Note11 To connect the sub BC controller to the main BC con...

Page 107: ...Y102LS G2 Total down stream Indoor capacity Joint P72 CMY Y102SS G2 Selection criteria for joints_B P121 P216 CMY R202S G Total down stream Indoor capacity Joint P120 CMY R201S G 9 When the piping length or the vertical separation exceeds the limit specified in Fig 2 connect a sub BC to the system The restriction for a system with a sub BC connection is shown in Fig 3 When a given system configura...

Page 108: ...oor capacity P24 P06 P30 Note10 To connect the BC controller to the main pipe use the reducer CMY R301S G CMY R302S G1 or CMY R304S G1 Note11 To connect the sub BC controller to the main BC controller use the reducer CMY R303S G1 CMY R305S G1 or CMY R306S G Note12 Install the pipes correctly referring to the section titled Procedures for installing the branched pipes Note13 Up to 11 sub BC control...

Page 109: ...ø28 58 1 1 8 Selection criteria for joints_A P73 P96 CMY Y102LS G2 Total down stream Indoor capacity Joint P72 CMY Y102SS G2 Selection criteria for joints_B P361 CMY R205S G Total down stream Indoor capacity Joint CMY R204S G P217 P240 P241 P360 P121 P216 CMY R203S G CMY R202S G P120 CMY R201S G Piping length and height between IU and BC controller Fig 2 Fig 3 9 When the piping length or the verti...

Page 110: ...PURY HP240TSNU A PURY HP240YSNU A 200 300 400 500 600 700 800 900 1000 10 20 30 40 50 60 70 80 90 100 110 Distance between outdoor unit and BC controller m Total extended pipe length m PURY HP192TSNU A PURY HP192YSNU A 200 300 400 500 600 700 800 900 1000 10 20 30 40 50 60 70 80 90 100 110 Distance between outdoor unit and BC controller m Total extended pipe length m 200 300 400 500 600 700 800 90...

Page 111: ...ler ft Total extended pipe length ft Distance between outdoor unit and BC controller ft Total extended pipe length ft Distance between outdoor unit and BC controller ft Total extended pipe length ft Distance between outdoor unit and BC controller ft Total extended pipe length ft 0 500 1000 1500 2000 30 90 150 210 270 330 0 500 1000 1500 2500 2000 30 90 150 210 270 330 0 500 1000 1500 2000 2500 300...

Page 112: ...2 system Formula When the piping length from the outdoor unit to the farthest indoor unit is 30 5 m 100 ft or shorter Amount of additional charge kg High pressure pipe ø28 58 total length 0 36 kg m High pressure pipe ø22 2 total length 0 23 kg m High pressure pipe ø19 05 total length 0 16 kg m High puressure pipe ø15 88 total length 0 11 kg m Liquid pipe ø19 05 total length 0 29 kg m Liquid pipe ø...

Page 113: ...it to the farthest indoor unit is 30 5 m 100 ft or shorter Liquid pipe ø19 05 total length 0 26 kg m Liquid pipe ø3 4 total length 3 13 oz ft Total capacity of outdoor units 72 96 120 144 192 240 53 53 106 89 142 177 Table B Amount oz BC controller Amount kg unit G1 GA1 type 0 HA1 type 2 0 GB1 HB1 type 1 0 Total capacity of outdoor units Amount To be added for G1 GA1 HA1 type BC controller HP72 3 ...

Page 114: ...or Outdoor Main BC controller CMB P108NU JA1 Sub BC controller CMB P104NU KB1 4 A ø7 8 131ft 1 18 a ø1 4 B ø3 8 32ft 2 96 b ø3 8 C 3 06 c ø1 4 ø1 2 65ft 4 06 d ø1 4 D 5 48 e ø3 8 ø3 8 16ft 6 36 7 30 HP240 The total length of each liquid line as follows ø7 8 A 131 ft ø3 4 G H 12 ft ø1 2 C 65 ft ø3 8 B D E F b e f g 160 ft ø1 4 a c d h 96 ft Calculation example Additional refrigerant charge 131 2 26...

Page 115: ...bs 12 oz 23 lbs 12 oz 35 lbs 5 oz Charged on site 56 lbs 4 oz 67 lbs 11 oz 80 lbs 15 oz 93 lbs 12 oz T otal for system 73 lbs 14 oz 91 lbs 8 oz 104 lbs 12 oz 128 lbs 16 oz Factory charged 8 0kg 10 8kg 10 8kg 16 0kg Charged on site 25 5kg 30 7kg 36 7kg 42 5kg T otal for system 33 5kg 41 5kg 47 5kg 58 5kg 47 lbs 10 oz 115 lbs 9 oz 163 lbs 3 oz 47 lbs 10 oz 150 lbs 13 oz 198 lbs 7 oz HP192 T YSNU HP2...

Page 116: ...er Compatibility PURY HP T Y S NU G1 type Compatible PURY HP T Y S NU J1 type Compatible Outdoor Heat source unit BC controller Compatibility Main Sub PURY HP T Y S NU JA1 KA1 type GB1 HB1 type GB1 HB1 type Compatible JA1 KA1 type KB1 type GB1 HB1 type Not compatible JA1 KA1 type GB1 HB1 type Compatible GA1 HA1 type KB1 type KB1 type Compatible GA1 HA1 type KB1 type GB1 HB1 type Not compatible GA1...

Page 117: ...door heat source unit may generate noise 3 Avoid sites that may encounter strong winds 4 Ensure the installation site can bear the weight of the unit 5 Condensation should be moved away from the unit particularly in heating mode 6 Provide enough space for installation and service as shown in section 13 2 Spacing 7 Avoid sites where acidic solutions or chemical sprays such as sulfur sprays are used...

Page 118: ...ight Unit height Unit height Unit height Unit height 240 9 1 2 45 50 2 1000 39 3 8 Air outlet guide not supplied L1 L2 L3 mm in Height limit Front Right Left Rear Same height or lower than the overall height of the unit Required minimum distance mm in L1 Front L2 Rear L3 Right Left When the distance behind the unit L2 needs to be small 450 17 3 4 300 11 13 16 450 17 3 4 When the distance to the ri...

Page 119: ...nt and rear of the block of units When there is a wall on either the right or left side of the block of units When there are walls in the front and rear of the block of units When there are two walls in an L shape 2 Face to face installation 3 Combination of face to face and side by side installations Unit height Unit height Unit height Unit height Unit height Unit height Unit height A A A A A Req...

Page 120: ...an 40 degrees 13 3 1 Lifting method Products weighing more than 20 kg 45 LBS should not be carried alone Do not carry the product by the PPbands To avoid the risk of injury do not touch the heat exchanger fins Plastic bags may pose a risk of choking hazard to children Tear plastic bags into pieces before disposing of them When lifting and transporting outdoor units with ropes run the ropes through...

Page 121: ...er of the angle bracket at the base of the unit shown in the figure below is securely supported Install the anchor bolt in such a way that the top end of the anchor bolt do not stick out more than 30 mm 1 3 16 in This unit is not designed to be anchored with post installation type anchor bolts although by adding fixing brackets anchoring with such type of anchor bolts becomes possible Take into co...

Page 122: ...34 Knockout hole 1 3 8 Bottom through hole Bottom through hole Bottom through hole B D C The gaps around the edges of through holes for pipes and wires on the unit allow water or mice to enter the unit and damage its parts Close these gaps with filler plates This unit allows two types of pipe routing Bottom piping Front piping To prevent small animals water and snow from entering the unit and dama...

Page 123: ...istance is more than 0 1 m 3 15 16 in the oil accumulates in Unit 1 when Unit 2 is in operation and Unit 1 is stopped H H 4 The vertical separation between units H must be 0 1 m 3 15 16 in or below In the figure on the right because the distance is more than 0 1 m 3 15 16 in the oil accumulates in Unit 2 when Unit 1 is in operation and Unit 2 is stopped H H Make sure that the inclination tolerance...

Page 124: ...unit 2 Outdoor unit 1 See the following drawing for connecting the pipes between the outdoor units In case of 2units combination 13 3 7 Twinning on the outdoor unit side On site piping On site piping Twining Kit The pipe section before the twinning pipe must have at least 500 mm 19 11 16 in of straight section 0000005744 BOOK 122 ページ 2020年2月25日 火曜日 午後5時19分 ...

Page 125: ...measure to snow and wind In cold and or snowy areas sufficient countermeasures to wind and snow damages should be taken for operating unit in normal and good condition in winter time Surround the units with snow nets or fences to protect them from snow Even in the other areas full consideration is required for installation of unit in order to prevent abnormal operations caused by wind or snow When...

Page 126: ...124 MEES19K180 Hyper Heating Inverter R2 Series 0000005744 BOOK 124 ページ 2020年2月25日 火曜日 午後5時19分 ...

Page 127: ...TALLATION INFORMATION 1 Installation information Ua 1 2 1 1 General precautions Ua 1 2 1 2 Precautions for Indoor unit and BC controller Ua 1 3 1 3 Precautions for Outdoor unit Heat source unit Ua 1 4 1 4 Precautions for Control related items Ua 1 5 ...

Page 128: ... minutes Heating mode will automatically resume upon completion of defrost process Air conditioner with a heat pump requires time to warm up the whole room after the heating operation begins because the system circulates warm air in order to warm up the whole room The sound levels were obtained in an anechoic room The sound levels during actual operation are usually higher than the simulated value...

Page 129: ...hermometers The clock on the remote controller may be displayed with a time lag of approximately one minute every month The temperature using a built in temperature sensor on the remote controller may differ from the actual room tempera ture due to the effect of the wall temperature Use a built in thermostat on the remote controller or a separately sold thermostat when indoor units installed on or...

Page 130: ...ry A cooling tower and heat source water circuit should be a closed circuit that water is not exposed to the atmosphere When a tank is installed to ensure that the circuit has enough water minimize the contact with outside air so that the oxygen from being dissolved in the water should be 1 mg L or less Install a strainer 50 mesh or more recommended on the water pipe inlet on the heat source unit ...

Page 131: ...re prevention or security This function should never be used in the way that would put people s lives at risk Provide any methods or circuit that allow ON OFF operation using an ex ternal switch in case of failure 1 4 2 Installation environment The surge protection for the transmission line may be required in areas where lightning strikes frequently occur A receiver for a wireless remote controlle...

Page 132: ...Ua 1 6 MEES16K099 ...

Page 133: ...ON FOR REFRIGERANT LEAKAGE MEES16K100 I CAUTION FOR REFRIGERANT LEAKAGE 1 Caution for refrigerant leakage Ub 1 2 1 1 Refrigerant property Ub 1 2 1 2 Confirm the Critical concentration and take countermeasure Ub 1 2 ...

Page 134: ...r unit Opening Sensor for refrigerant leakage Oxygen sensor or refrigerant sensor At 0 3m height from the floor Fresh air supply fan Indoor space Floor Fig 1 4 Fresh air supply and refrigerant shut off upon sensor action Note 1 Countermeasure 3 should be done in a proper way in which the fresh air supply shall be on whenever the leakage happens Note 2 In principle MITSUBISHI ELECTRIC requires prop...

Page 135: ... Doing so may cause the unit or pipes to burst or result in explosion or fire during use repair or at the time of disposal of the unit It may also be in violation of applicable laws MITSUBISHI ELECTRIC CORPORATION cannot be held responsible for malfunctions or accidents resulting from the use of the wrong type of refrigerant Our air conditioning equipment and heat pumps contain a fluorinated green...

Reviews: