Benutzeranleitung / Produktwartung H2iSD-1 des Produzenten Mitsubishi Electronics
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2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-1 2010 H2i ® Y-SERIES SYSTEM DESIGN CITY MUL TI ® H2I ® Y -SERIES HYPER-HEA TING INVERTER SYSTEM DESIGN 1. ELECTRICAL WORK ...............................................................
H2iSD-2 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 1. ELECTRICAL WORK OK NO F ollow ordinance of your governmental organization for technical standard related to electrical equipment, wiring regulations, and guidance of each electric power compan y.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-3 2010 H2i ® Y-SERIES SYSTEM DESIGN 1. ELECTRICAL WORK 1-2. Power Supply for Indoor and Outdoor Units 1-2-1. Electrical Characteristics of the Indoor Units Symbols: MCA : Min.Circuit Amps (=1.
H2iSD-4 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 1. ELECTRICAL WORK Symbols: MCA : Min.Circuit Amps (=1.25xFLA) FLA : Full Load Amps IFM :Indoor Fan Motor Model Indoor Unit IFM Hz V olts V oltage range MCA(A) FLA(A) PCFY -P15NKMU-E 60Hz 208 / 230V 188 to 253V 0.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-5 2010 H2i ® Y-SERIES SYSTEM DESIGN 1. ELECTRICAL WORK PUHY -HP-T(S)JMU Symbols: MC A : Min.
H2iSD-6 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-1. T ransmission Cable Length Limitations Long transmission cable causes voltage down, therefore, the length limitation should be obeyed to secure proper transmission.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-7 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-2. T ransmission Cable Specications T ype of cable Cable size Remarks Sheathed .
H2iSD-8 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-3. System Conguration Restrictions Fo r each Outdoor unit, the maximum connecta bl e quantity of Indoor unit is specified at its Specifications ta bl e.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-9 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL The power to System controller (excluding LMAP03-U) is supplied via M-NET transmission line.
H2iSD-10 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 1-phase 208-230V AC power supply is needed. The power supply unit P AC-SC51KUA is not necessary when connecting only the LMAP03U. Ye t, make sure to change the power supply changeover connector CN41 to CN40 on the LM adapter .
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-1 1 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4. Address Setting Branch No. setting Unit address No. setting Rotary switch In order to constitute CITY MUL TI in a complete system, switch operation for setting the unit address No.
H2iSD-12 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-2. Rule of setting address Unit Indoor unit ME, LOSSNA Y Remote controller (Mai.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-13 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-1. MA remote controller , Single-refrigerant-system, No System Controller Original switch setting of the outdoors, indoors, controllers and LMAP at shipment is as follows.
H2iSD-14 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2. Address should be set to Indoor units and central controller. 3. For a system having more than 16 indoor unit, confirm the need of Booster at 2-3 "System configuration restrictions".
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-15 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-3. MA remote controller , Multi-refrigerant-system, System Controller at TB7 .
H2iSD-16 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-4. ME remote controller , Single-refrigerant-system, No system controller 2-4-3-5. ME remote controller , Single-refrigerant-system, System controller , LOSSNA Y 2.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-17 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-6. ME remote controller , Multi-refrigerant-system, System Controller at TB 7side, LOSSNA Y, Booster for M-NET wiring 2.
H2iSD-18 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-7. ME remote controller , Multi-refrigerant-system, No Power supply unit NOTE.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-19 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-9. TG-2000A + AG-150A/GB-50A AG-150A can control max. 50 indoor units. AG-150A can control max. 150 indoor units via expansion controllers (P AC-YG50ECA).
H2iSD-20 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3-10. LMAP LMAP(01) 24VDC ( L ON W ORKS adapter) PC L ON W ORKS card L ON W ORKS card L ON W ORKS card For other equipments (Lighting, security, elevator etc.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-21 2010 H2i ® Y-SERIES SYSTEM DESIGN 2. M-NET CONTROL 2-4-3- 11 . BM ADAPTER BM ADAPTER(01) HUB For other equipments (Lighting, security , elevator etc.) BM ADAPTER can transmit for max. 50 indoor units in single-refrigerant-system or multi-refrigerant-system.
H2iSD-22 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 3-1. R410A Piping Material 3. PIPING DESIGN Refrigerant pipe for CITY MUL TI shall be made of phosphor us deo xidized copper , and has two types . A . Ty pe-O : Soft copper pipe (annealed copper pipe), can be easily bent with human's hand.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-23 2010 H2i ® Y-SERIES SYSTEM DESIGN 3. PIPING DESIGN 3-2. Piping Design Ta ble3-2-1-6. R410A Joint selection rule To tal down-stream Ind.
H2iSD-24 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 3. PIPING DESIGN T able3-2-2-4. R410A Joint selection rule To tal down-stream Indoor capacity Joint .
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-25 2010 H2i ® Y-SERIES SYSTEM DESIGN 3. PIPING DESIGN 3-3. Refrigerant Charge Calculation (1) Calculation of additional refrigerant charge Calculate the amount of additional charge based on the length of the piping extension and the size of the refrigerant line.
H2iSD-26 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 1. Do not install in an area where the unit could be subjected to direct heat. 2. Av oid installing the unit in a location where the operating sound could be an annoyance.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-27 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 1000 [39-3/8] 240 [9-15/32] 45° 50 [1-31/32] <C> (Unit : mm [in.]) <B> 500 [19-11/16] H h h H 100* [3-15/16] 450* [17-23/32] 50* [1-31/32] 50* [1-31/32] <A> (1) If the distance is 300 mm [11-13/16 in.
H2iSD-28 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION In case of collective installation and continuous installation : : Wall height (H) (Unit : mm [in.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-29 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-3. Piping Direction 4-3-1. Lifting method · When lifting the unit with ropes, run the ropes under the unit and use the lifting hole.
H2iSD-30 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-3-2. Installation 30mm [1-3/16in] Install the unit in such a way that the corner of the angle bracket at the base of the unit shown in the figure is securely supported.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-31 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-3-5. Refrigerant pipe routing 4-3-4.
H2iSD-32 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-3-6. Tw inning on the outdoor unit side Reducer ± 15° The tilt angle of the reducer should be within ±15° with the horizontal plane.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-33 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION Field piping Field piping Tw inning kit The length of the straight pipe must be 500 mm [19 in. ] or longer See the fo llo wing dr aw ing for connecting the pipes between the outdoor units.
H2iSD-34 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-4. Weather Countermeasures • Snow hood Countermeasure to wind Outlet Inlet Referring to the figure shown below, take appropriate measures which will suit the actual situation of the place for installati on.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-35 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION 4-5. Low Ambient Kit Application Guidelines General Unit Placement and Clearances • Outdoor units should be located in an area protected from prevailing winds.
H2iSD-36 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 4. OUTDOOR INST ALLA TION Safety strap Prov ided by others Important! For al l roof t op installat ions, saf ety stra ps must be attac hed be tween t he hood(s ) and t he uni t mounti ng str ucture.
2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) H2iSD-37 2010 H2i ® Y-SERIES SYSTEM DESIGN 5. ST ANDARD AND SEACOAST (BS) PROTECTION TREA TMENT Component Base Material Standard Models Seacoas.
H2iSD-38 2010 Hyper-heating Y -SERIES SYSTEM DESIGN (Sept. 2010) 2010 H2i ® Y-SERIES SYSTEM DESIGN 6. CAUTIONS R410A refrigerant is harmless and incombustible. R410A is heavier than the indoor air in density . Leakage of the refrigerant in a room has possibility to lead to a hypoxia situation.
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