Friedrich CP18N30, CP24N30, CP14N10 User Manual

Service & P arts Manual
2007

Compact Programmable

Models
CP14N10

CP18N30
CP24N30

CP-14-18-24-Svc-Prts-07 (3-07)

Table of Contents

Performance Data ........................................................................................................................................................................ 3

Outer Component Identifi cation ................................................................................................................................................... 4

Installation Dimensions ................................................................................................................................................................5

Wiring Diagrams ...........................................................................................................................................................................6

Functional Component Defi nitions ...............................................................................................................................................7

Refrigeration System Sequence of Operation ............................................................................................................................8

Sealed Refrigeration System Repairs ....................................................................................................................................9-12

T roubleshooting .....................................................................................................................................................................13-18

Part Diagrams and Part Lists ................................................................................................................................................19-23

Warranty ..................................................................................................................................................................................... 24

The information contained in t his manual is intended for use by a qualifi ed ser vice technician who is familiar

with the safety procedures required i n in stal la tion a nd repair, and who is equipped with the proper tools and test
instruments.

Installation or repairs made by unqualifi ed persons can result in hazards subjecting the unqualifi ed person making
such repai rs to the risk of injury or electrical shock which can be serious or even fatal not only to them, but also
to persons being served by the equipment.

If you install or perform service on equipment, you must assume responsibility for any bodily injur y or proper t y
damage which may result to you or others. Friedrich Air Conditioning Co mpany will not be responsible for any
injury or property damage arising from improper installation, service, and/or service procedures.

2

Specifi cations and Technical Parameters

Model CP14N10 CP18N30 CP24N30

Function COOLING COOLING COOLING

Rated Voltage 115V ~ 230/208V~ 230/208V~

Rated Frequency 60Hz 60Hz 60Hz

Total Capacity (Btu/h) 14000 18000/17600 23500/23100

Power Input (W) 1430 1850/1810 2740/2710

Rated Input (W) 1540 2478 3538

Rated Current (A) 15 12.57 18.09

Air Flow Volume (CFM) (H) 458.8 458.8 617.6

Dehumidifying Volume (pints/h) 3.38 4.65 8.46

EER / C.O.P BTU/W.H) 9.8 9.7/9.7 8.6/8.5

Energy Class / / /

Fan Type-Piece Centrifugal fl ow fan – 1 Centrifugal fl ow fan – 1 Centrifugal fl ow fan – 1

Diameter-Length (inch) φ7.93 X 4.31 φ7.93 X 4.31 φ8.82 X 4.31

Indoor Side

Outdoor Side

Fan Motor Speed (rpm) (H/M/L) 900/780/730 900/780/730 1000/900/800

Output of Fan Motor (W) 200 200 190

Fan Motor RLA(A) 3 1.45 1.35

Fan Motor Capacitor (uF) 15 MFD 7 MFD 7 MFD

Permissible Excessive Operating Pressure for the Discharge Side (Psig) 300 300 300

Permissible Excessive Operating Pressure for the Suction Side (Psig) 150 150 150

Dimension (H/W/D)( inch) 16.85 x 25.98 x 28.46 16.85 x 25.98 x 28.46 16.85 x 25.98 x 29.29

Dimension of Package (H/W/D)( inch) 19.96 x 31.1 x 29.13 19.96 x 31.1 x 29.13 19.69 x 29.29 x 36.22

Net Weight /Gross Weight (Pounds) 150/163 150/163 165/183

Refrigerant Charge (Ounce) R22/26.46 R22/27.87 R22/33.51

Evaporator Aluminum fi n-copper tube Aluminum fi n-copper tube Aluminum fi n-copper tube

Pipe Diameter (inch) φ0.276 φ0.276 φ0.276

Coil length (l) x height (H) x coil width (L) 16.61 X 15 X 1 16.61 X 15 X 1 16.61 X 15 X 1

Compressor Type ROTARY ROTARY ROTARY

L.R.A. (A) 58 42 56

Compressor RLA(A) 10.9 7.45 11.7/11.0

Compressor Power Input(W) 1182 1700 2425/2480

Overload Protector MRA13425-12007 MRA98982-9200 Built in

Working Temp Range (ºF) 50º-115º 50º-115º 50º-115º

Condenser Aluminum fi n-copper tube Aluminum fi n-copper tube Aluminum fi n-copper tube

Fan Type-Piece Axial fan –1 Axial fan –1 Axial fan –1

Fan Diameter (inch) φ15.59 φ15.59 φ15.59

Performance Data

PERFORMANCE

DATA * Cooling

CP14N10

CP18N30

CP24N30

EVAP. AIR TEMP.

DEG. F

Discharge

Air

59 21 118 173 56 41 54 78 267 12.1 / 58 26.5 115 15
58 22 119 173 66 52 55 77 269 8.3 /
57 23 119 172 66 52 55 77 269 8.5 / 208
57 23 117 197 60 44 50 75 264 12.3 /
56 24 117 195 57 44 50 75 264 13.1 / 208

Temp.

Drop F.

CONDENSER

TEMPERATURE

DEG. F

Discharge

Temp

Suction

Temp

Super

Heat

Sub-Cooling

*Rating Conditions: 80 degrees F, room air temp. & 50% relative humidity, with 95 degree F, outside air temp & 40% relative humidity.

OPERATING
PRESSURES

Suction Discharge

ELECTRICAL RATING S R-22 REF.

Amps

Amps

Cool

Heat

Locked

Rotor Amps

38.9/42.4 27.9

56A(230V) 33.5

Charge in

OZ.

Voltage

230

230

BREAKER

FUSE

60 Hertz

Amps

15

20

3

Outer Component Identifi cati o n

Models: CP14N10, CP18N30, CP24N30

Front intake grille

Cabinet

Air inlet louver

Front grille

Air filter
(behind front intake grille)

Power cord

Control panel cover

4

Installation Dimensions

Models: CP14N10, CP18N30, CP24N30

(Top View)

Over 2'

Fence / obstruction

16.85"

Over
1'

(Front View)

25.98"

Over
1'

Wall Or window

Ceiling

Over 1'

(Side View)

Over 1'

Less than

8.66"

Over 2'

5

Wiring Diagrams

CP24N30

CP18N30 / CP14N10

6

Functional Component Defi nitions

MECHANICAL C OMPONEN TS

Vent d o o r Allows introduction of fresh air into the room and /or

exhausts stale room air outside (on select models. )
Plenum assembly Diffuser with directional louvers used to direct

the conditioned airfl ow.
Blower wheel Attaches to the indoor side of the fan motor shaft

and is used for distributing unconditioned, room side air though the
heat exchanger and delivering conditioned air into the room.

Slinger fan blade Attaches to the outdoor side of the fan motor
shaft and is used to move outside air through the condenser coil,
while slinging condensate water out of t he base pan and onto
the condenser coil, thus lowering the temperature and pressures
within the coil.

ELECTRICAL COMPONENTS

Thermostat Used to maintain the specifi ed room side comfort

level

Capacitor Reduces line current and steadies the voltage supply ,
while greatly improving the torque characteristics of the fan motor
and compressor motor.

MoneySaver® switch W hen engaged, it sends the power sup ­ply to the fan motor through t he thermost at, which allows for a
cycle-fan operation.

Fan Motor Dual- shaf ted fan motor operate s the indoor blower
wheel and the condenser fan blade simultaneously.

Heat anticipator Used to provide better thermostat and room
air temperature control.

HERMETIC COMPONENTS

Compressor Motorized device used to compress refrigerant

through the sealed system.
Check valve A pressure-operated device used to direct the fl ow

of refrigerant to the proper capillary tube, during either the heating
or cooling cycle.

Capillary tube A cylindrical meter device used to evenly distribute
the fl ow of refrigerant to the heat exchangers (coils.)

7

Refrigeration System Sequence of Operation

A good understanding of t he basic operation of the refrigera ­tion system is essential for the s ervic e technician. Without t his
understanding, accurate troubleshooting of refrigeration system
problems will be more diffi cult and time consuming, if not (in some
cases) entirely impossible. The re frigeration system uses four basic
principles (laws) in its operation they are as follows:

1. “Heat always fl ows from a warmer body to a cooler body . ”

2. “Heat must be added to or removed from a substance before
a change in state can occur”

3. “Flow is always from a higher pressure area to a lower
pressure area.”

4. “The temperature at w hich a liquid or gas c hanges state is
dependent upon the pressure.”

The refrigerat ion cycle begins at the compre ssor. Starting the

compressor creates a low pressure in the suction line which draws
refrigerant gas (vapor) into the compressor. The compressor then

“compresse s” this refrigerant, raising it s pressure and its (heat

intensity) T emperature.

The refrigerant leaves the compressor through the discharge line

as a hot high pressure gas (vapor). The refrigerant enter s the
condenser coil where it gives up some of its heat. The condenser
fan moving air across the coil’s fi nned surface facilitates the transfer
of heat from the refrigerant to the relatively cooler outdoor air.

When a suffi cient quantity of heat has be en removed from the
refrigerant gas (vapor), the refrigerant will “condense” (i.e. change
to a liquid). Once the refrigerant has been condensed (changed)
to a liquid it is cooled even further by the air that continues to fl ow
across the condenser coil.

In the case of the capillary tube this is accomplished (by design)
through size (and length) of device, and the pressure difference
present across the device.

Since the evaporator co il is under a lower p res sure (due to the
suction created by the compressor) than the liquid line, the liquid
refrigerant leaves the metering device entering the evaporator coil.
As it enters the evaporator coil, the larger area and lower pressure
allows the refrigerant to expand and lower its temperature (heat
intensity). This expansion is often referred to as “boiling”. Since
the unit’s blower is moving Indoor air across the fi nned surface
of the evaporator coil, the expanding refrigerant absorbs some of
that heat. This results in a lowering of the indoor air temperature,
hence the “cooling” effect.

The expansion and absorbing of heat cause the liquid refrigerant

to evaporate (i.e. change to a gas). Once the refrigerant has been
evaporated (changed to a gas), it is heated even further by the
air that continues to fl ow across the evaporator coil.

The particular system design determines at exactly what point (in

the evaporator) the change of state (i.e. liquid to a gas) takes place.
In all cases, however, the refrigerant must be totally evaporated
(changed) to a gas before leaving the evaporator coil.

The low pressure (suction) created by the compre ssor caus es

the refrigerant to le ave the evaporator through t he suctio n line
as a cool low pressure vapor . The refrigerant then returns to the
compressor, where the cycle is repeated.

Refrigerant System Components

The RAC design determines at exactly what point (in the condenser)

the change of state (i.e. gas to a liquid) takes plac e. In all cas es,
however, the refrigerant must be totally condensed ( changed) to a

liquid before leaving the condenser coil.

The refrigerant leaves the condenser coil through the liquid line

as a warm high pressure liquid. It next will pass through the
refrigerant drier (if so equipped). It is the function of the drier to
trap any moisture present in the system, contaminants, and large
particulate matter.

The liquid refrigerant nex t enters the metering device. The

metering device is a capillary tube. The purpose of the metering
device is to “meter ” (i.e. control or me asure) th e quantity of
refrigerant entering the evaporator coil.

Suction
Line

Evaporator
Coil

Metering
Device

Refrigerant
Dryer

Discharge
Line

Condenser
Coil

Compressor

Refrigerant Drier

Liquid

Line

8

Sealed Refrigeration System Repairs

IMPORTANT

ANY SEALED SYSTEM REPAIRS TO COOL -ONLY MODELS REQUIRE THE INST ALLATION OF A LIQUID LINE DRIER.

ALSO, ANY SEALED SYSTEM REPAIRS TO HEAT PUMP MODELS REQUIRE THE INSTALLATION OF A SUCTION LINE DRIER.

EQUIPMENT REQUIRED

1. Voltmeter

2. Ammeter

3. Ohmmeter

4. E.P.A. Approved Refrigerant Recovery System.

5. V acuum Pump ( capable of 200 microns or less vacuum. )

6. Acetylene Welder

7. Electronic H alogen Leak Detector (G.E. Type H-6 or
equivalent.)

8. Accurate refrigerant charge measuring device such as:

a. Balance Scales - 1/2 oz. accuracy
b. Charging Board - 1/2 oz. accuracy

9. High Pressure Gauge - (0 - 400 lbs.)

1 0. Low Pressure Gauge - (30 - 150 lbs. )
11 . Vacuum Gauge - (0 - 1000 microns)

EQUIPMENT MUST BE CAPABLE OF:

1. Recovery CFC’s as low as 5%.

2. Evacuation from both the high side and low side of the
system simultaneously.

3. Introducing refrigerant charge into high side of the
system.

4. Accurately weighing the refrigerant charge actually
introduced into the system.

5. Facilities for fl owing nitrogen throu gh refriger ation tubing
during all brazing processes.

HERMETIC COMPONENT REP LAC EMEN T

The following proc edure applies when replacing component s
in the sealed refrig eration circuit or repairing ref rigerant leaks.
(Compressor, condenser, evaporator, capillary tub e, refrigerant

leaks, etc.)

1. Recover the refr igerant from the system at the proc ess
tube located on the high side of the system by installing a
line tap on the proc ess tube. App ly gauge from pr ocess
tube to EP A ap pro v ed gauges from process tube to E PA
approved recovery system. Recover CFC’s in system to at
least 5%.

2. Cut the process tube below pinch off on the suction side
of the compressor .

3. Connect the line from the nitr ogen tank to the suction
process tube.

4. Dr ift dry ni trogen through the system and un- solder the
more distant connection fi rst. (Filter drier, high side process
tube, etc.)

5. Replace inoperative component, and always install a new
fi lter drier. Drift dr y nitrogen through the system when
making these connections.

HERMETIC COMPONENT REP LAC EMEN T cont’d

6. Pressurize system to 30 PSIG with proper refrigerant and boost
refrigerant pressure to 1 50 PSIG with dry nitrogen.

7. Leak test complete system with electric halogen leak
detector, correcting any leaks found.

8. Reduce the system to zero gauge pressure.

9. Connect vacuum pump to high side and low side of system
with deep vacuum hoses, or c op per tubin g. (Do n ot use
regular hoses.)

1 0. Evacuate system to maximum absolute holding pressure

of 200 micro ns or less. NOTE: This process c an be
accelerated by use of heat lamps, or by breaking the
vacuum with refrigerant or dry nitrogen at 5,000 microns.
Pressure system to 5 PSIG and leave in system a
minimum of 10 minutes. Release refrigerant, and proceed
with evacuation of a pressure of 200 microns or less.

11. Break vacuum by charging system from the high side with
the correct amount of liquid refrigerant specifi ed. This will
prevent boiling the oil out of the crankcas e, and damage
to the compressor due to over heating.

NOTE: If the entire charge will not enter the high side, allow the
remainder to enter the low side in small increments while operating
the unit.

12. Restart unit several times after allowing pressures to stabilize.
Pinch off process tubes, cut and solder the ends. Remove
pinch off tool, and leak check the process tube ends.

SPECIAL PROCE DURE IN THE CASE OF COM PRESSOR
MOTOR BURNOUT

1. Recover all refrigerant and oil from the system.

2. Remove compressor, capillary tube and fi lter drier from the
system.

3. Flush evaporator condenser and all connecting tubing with
dry nitro gen or equivalent, to remove all contamination
from system. Inspect suction and discharge line for carbon
deposits. Remove and clean if necessary.

4. Reassemble the system, including new drie r str ainer and
capil l a ry t u b e .

5. Proceed with processing as outlined under hermetic
component replacement.

ROTA RY COMPRESSOR SPECIAL TROUBLESHOOTING
AND SERVICE

Basically, troubleshooting and ser vicing rotary c ompressors
is the same as on the reciprocating compressor with only one
main exception:

NEVER, under any circumstances, charge a rotary compressor
through the LOW side. Doing so would cause permanent damage
to the new compressor.

9