Johnson Controls R-410A Section VII System Charge, Superheat Charging Method Piston Indoor

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835964-UIM-A-0112

SECTION VII: SYSTEM CHARGE

The factory charge in the outdoor unit includes enough charge for the unit, a 15 ft. (4.6 m) line set, and the smallest indoor coil match-up. Some indoor coil matches may require additional charge. See tabular data sheet provided in unit literature packet for charge requirements.

Do not leave the system open to the atmosphere.

The “TOTAL SYSTEM CHARGE” must be permanently stamped on the unit data plate.

Total system charge is determined as follows:

1.Determine outdoor unit charge from tabular data sheet.

2.Determine indoor coil adjustment from tabular data sheet.

3.Calculate the line charge using the tabular data sheet if line length is greater than 15 feet (4.6 m).

4.Total system charge = item 1 + item 2 + item 3.

5.Permanently stamp the unit data plate with the total amount of refrigerant in the system.

Use the following charging method whenever additional refrigerant is required for the system charge.

DO NOT attempt to pump “Total System Charge” into outdoor unit for maintenance, service, etc. This may cause damage to the com- pressor and/or other components. the outdoor unit only has enough volume for the factory charge, not the “Total System Charge”.

Refrigerant charging should only be carried out by a qualified air conditioning contractor.

Compressor damage will occur if system is improperly charged. On new system installations, charge system per tabular data sheet for the matched coil and follow guidelines in this instruction.

If a calibrated charging cylinder or accurate weighing device is avail- able, add refrigerant accordingly. Otherwise, model-specific charging charts are provided on the access panel of the unit.

SUPERHEAT CHARGING METHOD -

PISTON INDOOR

1.Set the system running in cooling mode by setting the thermostat at least 6°F below the room temperature and operate system for at least 10 – 15 minutes.

2.Refer to the technical guide for the recommended airflow and ver- ify indoor airflow (it should be about 400 SCFM per ton).

3.Measure and record the outdoor ambient (DB) temperature and the suction pressure at the suction service valve.

4.Using the charging chart located on the unit, find the intersection of the outdoor ambient dry bulb and the suction pressure obtained in step 3. This is the recommended suction tube temperature at the service valve.

5.Measure and record the suction tube temperature at the service valve and compare to the recommended temperature obtained in step 4.

6.Add charge if the measured suction temperature in step 5 is above the recommended value. Remove / recover refrigerant if the mea- sured suction temperature is below the recommended value.

Example: The suction tube temperature listed on the table at the intersection of the outdoor DB and the suction pressure is 63°F. Temperature of the suction tube at the service valve is 68°F. It would be necessary to add refrigerant to drop the suction tube temperature to 63°F.

SUBCOOLING CHARGING METHOD - TXV INDOOR

For cooling operation, unless otherwise specified, the default subcool- ing is 10°F.

1.Set the system running in cooling mode by setting the thermostat at least 6°F below the room temperature and operate system for at least 10 – 15 minutes.

2.Refer to the technical guide for the recommended indoor airflow and verify it is correct (it should be about 400 SCFM per ton).

3.Measure and record the indoor wet bulb (WB) and the outdoor ambient dry bulb (DB) temperature.

4.Using the charging chart located on the unit, find the intersection of the indoor wet bulb and the outdoor dry bulb. This is the recom- mended liquid pressure (and subcooling value).

5.Measure and record the pressure at the liquid valve pressure port and compare to the value obtained in step 4.

6.Add charge if the measured liquid pressure is lower than the rec- ommended value. Remove / recover charge if the measured liquid pressure is above the recommended value.

Example: The liquid pressure listed at the intersection of the indoor WB and the outdoor DB 320 psig. Pressure at the liquid valve is 305 psig. It would be necessary to add refrigerant to increase the liquid pressure to 320 psig.

Condenser subcooling is obtained by calculating the difference of the saturated refrigerant temperature of the pressure measured at the liquid base valve and the liquid tube temperature as measured at the liquid base valve.

Subcooling Temp. (TC) = Saturated Temp. (TS) – Liquid Temp. (T).

IT IS UNLAWFUL TO KNOWINGLY VENT, RELEASE OR DIS- CHARGE REFRIGERANT INTO THE OPEN AIR DURING REPAIR, SERVICE, MAINTENANCE OR THE FINAL DISPOSAL OF THIS UNIT.

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Johnson Controls Unitary Products

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Contents List of Tables Section II SafetyList of Figures Section I GeneralLimitations Section III Unit InstallationADD-ON REPLACEMENT/RETROFIT LocationPrecautions During Line Installation Ground InstallationRoof Installation Liquid Line FILTER-DRIERPrecautions During Brazing of Lines Precautions During Brazing Service ValveSection IV Orifice Installation Section V TXV InstallationSection VI Evacuation Section VII System Charge Superheat Charging Method Piston IndoorSubcooling Charging Method TXV Indoor Field Connections Power Wiring Section Viii Electrical ConnectionsGeneral Information & Grounding Field Connections Control Wiring Power WiringID Models AC 1AThermostat PSC Single Stage AIR Handler AIR ConditionerAC 1B PSC Single Stage AIR AIR Handler ConditionerAC 5D Single Stage PSC AIR Furnace ConditionerAC 5E Single Stage PSC FurnaceSingle Stage AIR Conditioner Maintenance Section IX Instructing the OwnerSubcooling Charge Table is on the Unit Rating Plate Section X Wiring Diagram 412217 Johnson Controls Unitary Products York Drive Norman, OK
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R-410A specifications

Johnson Controls R-410A is a widely recognized refrigerant in the HVAC industry, primarily used in air conditioning and heat pump applications. Known for its environmental benefits and efficiency, R-410A has risen to prominence as a reliable replacement for older refrigerants such as R-22, which are being phased out due to their harmful impact on the ozone layer.

One of the standout features of R-410A is its low impact on global warming potential, making it an environmentally-friendly choice. It is composed of a mixture of hydrofluorocarbons (HFCs), specifically difluoromethane (R-32) and pentafluoroethane (R-125). This blend allows for efficient heat transfer while minimizing harmful emissions, addressing the growing concerns over climate change.

Johnson Controls emphasizes the efficiency of R-410A systems, which can provide a highly effective cooling performance. They are designed to operate at higher pressures compared to R-22, allowing for more efficient heat exchange and better overall system performance. This results in greater energy efficiency ratings, contributing to lower electricity bills for consumers.

In terms of technology, R-410A systems often feature advanced compressor designs and enhanced coil configurations, which optimize the system’s performance. Johnson Controls integrates state-of-the-art variable speed technologies and smart controls that enhance responsiveness and adaptability to changing environmental conditions. These innovations not only improve thermal comfort but also reduce energy consumption, leading to a smaller carbon footprint.

Another significant characteristic of R-410A is its compatibility with various lubricants, which is crucial for maintaining system performance and longevity. Johnson Controls often utilizes specially formulated lubricants that work optimally with R-410A, ensuring reliable operation and reducing the risk of issues related to lubrication.

In summary, Johnson Controls R-410A is an important refrigerant characterized by its efficient, environmentally friendly properties and advanced technologies. Its application in modern HVAC systems provides users with excellent performance, substantial energy savings, and an effective solution for climate-conscious cooling. As the industry continues to evolve, R-410A remains a central player in the push toward more sustainable and efficient heating and cooling solutions.