Table 3 Ð Electrical Data

 

 

OPERATIONAL

COMPRESSOR

 

POWER SUPPLY

UNIT SIZE

 

VOLTAGE*

 

V-PH-Hz

 

 

 

 

 

38HDL

Min

Max

RLA

LRA

Fan FLA

MCA

Max Fuse² or HACR-Type

 

 

 

Ckt Bkr Amps

 

 

 

 

 

 

 

 

018

 

 

 

10.7

47.0

.70

14.1

25

024

 

 

 

13.2

59.0

.70

17.2

30

030

208/230-1-60

187

254

15.7

73.0

.70

20.3

35

036

14.2

86.7

.70

18.5

30

 

 

 

048

 

 

 

24.3

131.0

1.45

31.8

50

060

 

 

 

28.6

170.0

1.45

37.2

65

 

LEGEND

FLA

Ð Full Load Amps

HACR Ð Heating, Air Conditioning, Refrigeration

LRA

Ð Locked Rotor Amps

MCA

Ð Minimum Circuit Amps per NEC Section 430-24

NEC

Ð National Electrical Code (U.S.A. Standard)

RLA

Ð Rated Load Amps (Compressor)

*Permissible limits of the voltage range at which unit will operate satisfactorily.

²Time-delay fuse.

NOTES:

1.Control circuit is 24 v on all units and requires an external power source.

2.All motors and compressors contain internal overload protection.

3.In compliance with NEC (U.S.A. Standard) requirements for mul- timotor and combination load equipment (refer to NEC Articles 430 and 440), the overcurrent protective device for the unit shall be fuse or HACR breaker.

4.Motor RLA values are established in accordance with UL (Under- writers' Laboratories) Standard 465 (U.S.A. Standard).

Low Pressure Switch Ð This switch, mounted on the suction line, has ®xed non-adjustable settings. To check pres- sure switch, attach pressure gage to suction service valve gage port. Slowly close liquid shutoff valve and allow compres- sor to pump down. Do not allow compressor to pump down below 2 psig (14 kPa). Compressor should shut down when suction pressure drops to cutout pressure in Tables 1A and 1B, and should restart when pressure builds up to cut-in pres- sure shown after accessory CLO (compressor lockout) switch has been reset and accessory Time Guard II device has com- pleted its timing cycle.

Service Valves Ð The service valves in the outdoor unit come from the factory frontseated. This means the refrig- erant charge is isolated from the line-set connection ports. To prevent damage to the valve, use a wet cloth or other acceptable heat sink material on the valve before brazing.

The service valves must be backseated (turned counter- clockwise until seated) before the service port caps can be removed and the hoses of the gage manifold connected. In this position, refrigerant has access from the through out- door and indoor unit. The service valve cannot be ®eld re- paired; only a complete valve or valve stem seal and service port caps are available for replacement.

AccuRater (Bypass Type) Device Ð See Fig. 4 for bypass type AccuRater device components. The piston has a refrigerant metering hole through it. The retainer forms a stop for the piston in the refrigerant bypass mode and a sealing surface for liquid line ¯are connection. To check, clean or replace piston:

1.Shut off power to unit.

2.Pump down using Pumpdown Procedure section on page 7.

3.Remove liquid line ¯are connection from AccuRater device.

4.Pull retainer out of body, being careful not to scratch flare sealing surface. If retainer does not pull out easily, care- fully use locking pliers to remove retainer.

5.Slide piston out by inserting a small soft wire, with small kinks, through metering hole. Ensure metering hole, seal- ing surface around piston cones, and ¯uted portion of pis- ton are not damaged.

6.Clean piston refrigerant metering hole.

7.Replace retainer O-ring before reassembling AccuRater device (O-ring part no. 99CC501052).

Refrigerant Charging

To prevent personal injury, wear safety glasses and gloves when handling refrigerant. Do not overcharge system Ð this can cause compressor ¯ooding.

NOTE: Do not vent or depressurize unit refrigerant to atmos- phere. Remove and reclaim refrigerant following practice.

SUPERHEAT METHOD (COOLING, NON-TXV) Ð To check and adjust charge during cooling season, use Tables

4A-5B and the following procedure:

1.Operate unit a minimum of 15 minutes before checking charge.

2.Measure suction pressure by attaching a gage to suction valve service port.

3.Measure suction line temperature by attaching a service thermometer to unit suction line near suction valve. In- sulate thermometer for accurate readings.

4.Measure outdoor coil inlet-air dry bulb temperature with a second thermometer.

5.Measure indoor coil inlet-air wet bulb temperature with a sling psychrometer.

6.Refer to Tables 4A and 4B. Find air temperature enter- ing outdoor coil and wet-bulb temperature entering indoor coil. At this intersection, note the superheat temperature.

7.Refer to Tables 5A and 5B. Find superheat temperature and suction pressure and note suction line temperature.

8.If unit has higher suction line temperature than charted temperature, add refrigerant until charted temperature, add refrigerant until charted temperature is reached.

9.If unit has lower suction line temperature than charted temperature, remove and recover refrigerant until charted temperature is reached.

10.If air temperature entering outdoor coil or pressure at suction valve changes, charge to new suction line tem- perature indicated on chart.

NOTE: The above procedure is independent of indoor air quantity.

8

Page 7 Page 9
Page 8
Image 8
Carrier 38HDL018-060 specifications Refrigerant Charging, Electrical Data
Page 7 Page 9

38HDL018-060 specifications

The Carrier 38HDL018-060 is a prominent model in the world of commercial HVAC solutions, offering exceptional performance, efficiency, and reliability for a variety of applications, including offices, retail spaces, and industrial environments. With a range of capacities from 1.5 tons to 5 tons, the 38HDL series serves diverse heating and cooling needs, making it a versatile option for many building types.

One of the standout features of the Carrier 38HDL018-060 is its advanced Scroll compressor technology. This technology is known for its energy efficiency and quieter operation compared to traditional reciprocating compressors. By optimizing the refrigeration cycle, the Scroll compressor enhances the overall system performance, providing consistent temperature control while minimizing energy consumption.

The unit also incorporates a vertical air discharge design, allowing for flexible installation and improved airflow distribution. This design minimizes air stratification, ensuring that conditioned air reaches every corner of the space effectively. Furthermore, the 38HDL series is equipped with a reliable multi-speed fan that adapts its operation based on the specific cooling or heating demand, further optimizing energy use and maintaining indoor comfort levels.

In terms of technology, the Carrier 38HDL018-060 features a microprocessor-based control system. This intelligent control allows for precise temperature management and system diagnostics, enabling easier maintenance and ensuring the longevity of the unit. Additionally, the unit can be integrated with Carrier’s advanced building automation systems for streamlined control across larger facilities, further enhancing operational efficiency.

The 38HDL series is also designed with durability in mind. It features a rugged aluminum cabinet that stands up to harsh environmental conditions while providing excellent insulation to improve overall efficiency. The corrosion-resistant coatings contribute to the longevity of the finned coil and other critical components, ensuring reliable performance over time.

Overall, the Carrier 38HDL018-060 exemplifies modern HVAC technology, blending efficiency, durability, and advanced control features to create a solution that meets the demands of today’s commercial buildings. Whether for new construction or retrofitting an existing system, the 38HDL series offers the reliability and performance required to create a comfortable indoor environment.
Top Page Image Contents