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48

Table 13-6

Information requirements for heat pump space heaters and heat pump combination heaters

Model(s):

KEM-90 DRS4 KH

Air-to-water heat pump:

[yes]

Water-to-water heat pump:

[yes/no]

Brine-to-water heat pump:

[yes/no]

Low-temperature heat pump:

[yes/no]

Equipped with a supplementary heater:

[yes/no]

Heat pump combination heater:

[yes/no]

For low-temperature heat pumps, parameters shall be declared for low-temperature application. Otherwise,

parameters shall be declared for medium-temperature application. Parameters shall be declared for average

climate conditions.

Item

Symbol Value Unit

Item

Symbol Value Unit

Rated heat output

(3)

at Tdesignh = -10

(-11) °C

Prated

=Pdesignh 74.3 kW

Seasonal space heating 

energy efficiency

η

s

147.70

%

Seasonal coefficient of performance

SCOP

3.77

--

Active mode coef. of 

performance

SCOP

on

--

--

Net seasonal coef. of 

performance

SCOP

net

--

--

T

j

 = -7°C

Pdh

65.41 kW T

j

 = -7°C

COPd

2.45

--

T

j

 = +2°C

Pdh

43.01 kW T

j

 = +2°C

COPd

3.63

--

T

j

 = +7°C

Pdh

26.42 kW T

j

 = +7°C

COPd

5.08

--

T

j

 = +12°C

Pdh

28.54 kW T

j

 = +12°C

COPd

5.94

--

T

j

 = bivalent temperature

Pdh

65.41 kW T

j

 = bivalent temperature

COPd

2.45

--

T

j

 = operation limit temperature

Pdh

71.03 kW T

j

=operation limit temperature COPd

2.32

--

For air-to-water heat pumps:

Tj = – 15 °C (if TOL < – 20 °C)

Pdh

--

kW For air-to-water heat pumps:

T

j

=–15°C (if TOL<–20°C)

COPd

--

--

Bivalent temperature (m2°C)

Tbiv

-7

°C

For air-to-water HP :

Operation limit

temperature

(maximum-7°C)

TOL

-10

°C

Cycling interval capacity for heating

at T

= -7°C

Pcych

--

kW

Degradation coefficient

(4)

 at T= -7°C

Cdh

--

--

Heating water

operating limit temperature

WTOL

--

°C

Cycling interval capacity for heating

at T

=+2°C

Pcych

--

kW

Cycling interval efficiency

at T

j

 = +7°C

COPcyc

--

--

Degradation coefficient

(4)

 at T= +2°C

Cdh

--

--

Cycling interval capacity for heating

at T

j

 = +7°C

Pcych

--

kW Cycling interval capacity for

heating at T

j

 =+12°C

COPcyc

--

--

Degradation coefficient

(4)

 at T

j

 = +7°C

Cdh

--

--

Cycling interval efficiency

at T

j

 = +7°C

COPcyc

--

--

Cycling interval capacity for heating

at T

j

 =+12°C

Pcych

--

kW Cycling interval capacity for

heating at T

j

 =+12°C

COPcyc

--

--

Degradation coefficient

(4)

 at T

j

 = +12°C

Cdh

--

--

Supplementary heater (to be declared even if

not provided in the unit)

Power consumption in modes other than active mode

Off mode

P

OFF

0.090 kW

Rated heat output(3)

Psup

= sup(T

j

)

--

kW

Thermostat-off mode

P

TO

0.700 kW

Type of energy input

Standby mode

P

SB

0.090 kW

Outdoor heat exchanger

Crankcase heater mode

P

CK

0

kW For air-to-water HP: Rated air 

flow rate

Q

airsource

35000 m

3

/h

Other items

For water-to-water: Rated 

water flow rate

Q

watersource

--

m

3

/h

Capacity control

Fixed/Variable

Variable

Sound power level, indoors

L

WA

--

dB(A)

For brine-to-water: Rated 

brine flow rate

Q

brinesource

--

m

3

/h

Sound power level, outdoors

L

WA

83

dB(A)

Contact details

Name and address of the manufacturer or its authorised representative.

(1) For heat pump space heaters and heat pump combination heaters, the rated heat output Prated is equal to 

the design load for heating Pdesignh, and the rated heat output of a supplementary heater Psup is equal to the 

supplementary capacity for heating sup(Tj).
(2) If Cdh is not determined by measurement then the default degradation coefficient is Cdh = 0,9.

16127100A07310  MD20U-033A-EN(SL)

Summary of Contents for KEM-90

Page 1: ...ery much for purchasing our air conditioner Before using your air conditioner please read this manual carefully and keep it for future reference KEM 90 DRS4 KH OWNER S INSTALLATION MANUAL DC Inverter...

Page 2: ...of arrangement space of the unit 07 6 3 Space requirements for parallel installation of multiple Modular units 08 6 4 Installation foundation 08 6 5 Installation of damping devices 09 7 CONNECTION DR...

Page 3: ...parts 35 11 7 First startup after shutdown 36 11 8 Refrigeration system 36 11 9 Disassembling compressor 36 11 10 Auxiliary electric heater 36 11 11 System antifreezing 36 11 12 Replacement of safety...

Page 4: ...35 40 45 50 55 0 5 10 15 20 25 30 G KEM 30 DRS4 1 KH KEM 60 DRS4 1 KH KEM 90 DRS4 KH KEM 30 DRS4 1 KH KEM 60 DRS4 1 KH Fig 1 1 1 Cooling operating range Outlet water temperature C COOLING HEATING Outl...

Page 5: ...ous situation which if not avoided may result in minor or moderate injury It is also used to alert against unsafe practices Explanation of symbols displayed on the indoor unit or outdoor unit WARNING...

Page 6: ...ls electric shocks or fire After completing the installation work check to make sure that there is no refrigerant leakage Never directly touch any leaking refrigerant as it could cause severe frostbit...

Page 7: ...ans in accordance with national wiring regulation and this circuit diagram An all pole disconnection device which has at least 3mm seperation distance in all pole and a residualcurrent device RCD with...

Page 8: ...coil and copper pipes 4 If the unit is within the reach of unauthorized personnel take protective measures for safety considerations such as installing a fence These measures can prevent man caused or...

Page 9: ...view Top view B E D F A C Fig 6 2 Outline dimensional of KEM 60 DRS4 1 Front view Left view Top view A D C F E B Fig 6 3 Outline dimensional of KEM 90 DRS4 KH Table 6 1 Model KEM 30 DRS4 1 KH KEM 60 D...

Page 10: ...the unit and sunk fence or Persian blinds should also meet the requirement 3 If the unit needs to operate in winter and the installation site may be covered by snow the unit should be located higher t...

Page 11: ...such that condensate may freeze Inlet and outlet pipe side Drainage channel Electric control box side Anchor bolt Fig 6 7 Top view of schematic diagram of installation dimension of KEM 30 DRS4 1 KH un...

Page 12: ...y snow 1 Measures to prevent build up of snow The base height should be as least the same as the predicted snow depth in the local area Base height Outdoor unit Fig 6 12 Snow prevention base height 2...

Page 13: ...Pressure gauge Flexible joint Gate valve Automatic discharge valve Y shaped filter Thermometer Circulating pump Check valve Fig 7 1 Connection drawing of pipeline system NOTE The ratio of the two way...

Page 14: ...0 DRS4 1 8 2 Opening the uint By means of a detachable service panel the maintenance personnel can easily access the interior components of the unit Door 1 Door 2 Door 3 Door 4 Fig 8 4 Doors of KEM 30...

Page 15: ...ve access to the compartment of water pipes water side heat exchanger acculator and liquid vapor separator Door 2 3 4 give access to the hydraulic compartment and electrical parts Door 1 2 3 give acce...

Page 16: ...ly period after the power supply is connected and they are not detected while the unit is in operation 2 CN12 Quick return oil solenoid valve 3 CN5 EVA HEAT Water side heat exchanger heaters connectio...

Page 17: ...emperature sensor T3A T3B pipe temperature sensor of the condenser T5 wtater tank temperature sensor T6A Refrigerant inlet temperature of EVI plate heat exchanger T6B Refrigerant outlet temperature of...

Page 18: ...ctory default Low temperature cooling valid for S12 3 ON 41 CN7 TEMP SW Target water temperature switching port 42 ENC2 POWER DIP switch for capacity selection KEM 30 DRS4 1 KH defaults 0 KEM 60 DRS4...

Page 19: ...peration 2 CN12 Quick return oil solenoid valve 3 CN80 Injection solenoid valve of compressor system B 4 CN47 Injection solenoid valve of compressor system A 5 CN5 Water side heat exchanger heaters co...

Page 20: ...n in port WizPro200RS programming device 28 IC10 EEPROM chip 29 CN1 temperature sensors input port T4 outdoor ambient temperature sensor T3A T3B pipe temperature sensor of the condenser T5 wtater tank...

Page 21: ...V 46 ENC4 NET_ADDRESS DIP switch 0 F of outdoor unit network address is enabled which represent address 0 15 47 S12 Dip switch S12 1 Valid for S12 1 ON factory default S12 2 Single water pump controll...

Page 22: ...y Please carefully read the labels on the electric cabinet The user s attempt to repair the controller is prohibited since improper repair may cause electric shock damages to the controller and so on...

Page 23: ...d Power wiring must be entrusted to professionals with electrician qualification Fig 8 10 4 Electrical wiring precaution d 8 4 5 Power supply specification Table 8 4 Item Model Outdoor power supply Po...

Page 24: ...arrester Grounding wire Building Fuses Fuses Grounding 1 Grounding 2 Grounding 3 Uint Lightning arrester Grounding wire Surge current Grounding 1 Grounding 2 Grounding 3 Fig 8 11 Requirements of powe...

Page 25: ...eater and ac light of the state of compressor is as follows HEAT1 HEAT2 COM COMP STATE PUMP Blue Black Brown 8 4 9 Wiring of ON OFF weak electric port The remote function of ON OFF must be set by DIP...

Page 26: ...2V Main control board is provided 0 electric control box TEMP SWITCH port 0 electric control box TEMP SWITCH port First target water temperature Second target water temperature Fig 8 17 Wiring of TEMP...

Page 27: ...MODULE COMMUNICATION WITH NEXT MODULE COMMUNICATION WITH NEXT MODULE POWER 380 415V 3N 50Hz RVV 300 500 5X10mm 2 The length of wire s h o u l d b e s h o r t e r than 500m The Wiring Terminal X Y and...

Page 28: ...he length of wire s h o u l d b e s h o r t e r than 500m The Wiring Terminal X Y and E on the back of Wire Controller are correspondin of the Terminal X Y and E of Wiring Board in Main Module MAIN CO...

Page 29: ...r t e r than 500m The Wiring Terminal X Y and E on the back of Wire Controller are correspondin of the Terminal X Y and E of Wiring Board in Main Module Power Transformer OUTPUT 8 5 V MAIN CONTROL WI...

Page 30: ...ed units should be provided with mixing water temperature sensor WARNING For the water pipeline network including filters and heat exchangers dreg or dirt may seriously damages the heat exchangers and...

Page 31: ...Hoop connection DN50 KEM 90 DRS4 KH Hoop connection DN50 Fig 8 23 connection mode of KEM 30 DRS4 1 KH Fig 8 24 connection mode of KEM 60 DRS4 1 KH Fig 8 25 connection mode of KEM 90 DRS4 KH pipe 8 5 3...

Page 32: ...pump h1 Main unit water resistance h2 Pump water resistance h3 Water resistance of the longest water loop distance includes pipe resistance different valve s resistance flexible pipe resistance pipe e...

Page 33: ...ition and move the total euent temperature sensor at No 0 address to the position Pump Pump Fig 8 28 Installation of multi module no more than 16 modules 2 Table of diameter parameters of main inlet a...

Page 34: ...Tw unit 0 Fig 8 30 Installation of multiple water pump 9 STRAT UP AND CONFIGRUATION 9 1 Initial start up at low outdoor ambient temperatures During initial start up and when water temperature is low i...

Page 35: ...a fault code If a fault occurs remove the fault first and start the unit according to the operating method in the unit control instruction after determining that there is no fault existing in the unit...

Page 36: ...rror recovery 14 EE 1EE EVI plate heat exchanger refrigerant temperature T6A sensor error Recovered upon error recovery 2EE EVI plate heat exchanger refrigerant temperature T6B sensor error 15 EF Unit...

Page 37: ...utes 42 F6 1F6 A system buss voltage error PTC Recovered upon error recovery 2F6 B system buss voltage error PTC 43 Fb Pressure sensor error Recovered upon error recovery 44 Fd Suction temperatrue sen...

Page 38: ...ent air conditioner errors which bring inconvenience to your life and work 2 Maintenance of main parts Close attention should be paid to the discharge and suction pressure during the running process F...

Page 39: ...d water circulate and start up unit and make the low pressure control switch short circuit if necessary Slowly inject refrigerant into the system and check suction and discharge pressure CAUTION Conne...

Page 40: ...por separator safety valve Fig 11 1 Replacement of safety valve WARNING The air outlet of safty valve must be connected to the appropriate pipe which can direct the leaking refrigerant to the appropri...

Page 41: ...ng the period that the work is carried out The ventilation should safely disperse any released refrigerant and preferably expel it externally into the atmosphere 8 Checks to the refrigeration equipmen...

Page 42: ...ment shall be set at a percentage of the LFL of the refrigerant and shall be calibrated to the refrigerant employed and the appropriate percentage of gas 25 maximum is confirmed Leak detection fluids...

Page 43: ...oning it is recommended good practice that all refrigerants are removed safely When tranferring refrigerant into cylinders ensure that only appropriate refrigerant recovery cylinders are employed Ensu...

Page 44: ...ressure 5 Check running current 6 Whether unit has been through refrigerant leakage test 7 Whether there is noise on all the panels of unit 8 Check whether the main power source connection is correct...

Page 45: ...ure switch freeze proof device water flow volume controller Overcurrent device power phase sequence device etc Refrigerant Type R32 Chargeing volume kg 7 9 14 0 16 0 Water pipe system Waterflow volume...

Page 46: ...9 Tj 25 C Pdc 12 79 kW Tj 25 C EERd 4 98 Tj 20 C Pdc 5 87 kW Tj 20 C EERd 5 72 Degradation co efficient for chillers Cdc 0 90 Power consumption in modes other than active mode Off mode POFF 0 020 kW C...

Page 47: ...25 43 kW Tj 25 C EERd 4 48 Tj 20 C Pdc 11 30 kW Tj 20 C EERd 4 83 Degradation co efficient for chillers Cdc 0 9 Power consumption in modes other than active mode Off mode POFF 0 035 kW Crankcase heate...

Page 48: ...37 36 kW Tj 25 C EERd 5 10 Tj 20 C Pdc 26 05 kW Tj 20 C EERd 5 91 Degradation co efficient for chillers Cdc 0 9 Power consumption in modes other than active mode Off mode POFF 0 090 kW Crankcase heat...

Page 49: ...er operating limit temperature WTOL C Cycling interval capacity for heating at Tj 2 C Pcych kW Cycling interval efficiency at Tj 7 C COPcyc Degradation coefficient 4 at T 2 C Cdh Cycling interval capa...

Page 50: ...on coefficient 4 at T 7 C Cdh Heating water operating limit temperature WTOL C Cycling interval capacity for heating at Tj 2 C Pcych kW Cycling interval efficiency at Tj 7 C COPcyc Degradation coeffic...

Page 51: ...4 at T 7 C Cdh Heating water operating limit temperature WTOL C Cycling interval capacity for heating at Tj 2 C Pcych kW Cycling interval efficiency at Tj 7 C COPcyc Degradation coefficient 4 at T 2...

Page 52: ......

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