Friedrich R-410A service manual Cooling Load Estimate Form, Heat Gain from Quantity Factors, Day

Page 82

COOLING LOAD ESTIMATE FORM

HEAT GAIN FROM

 

QUANTITY

FACTORS

 

 

BTU/Hr.

 

DAY

 

 

 

 

 

 

 

 

 

(Quantity x Factor)

1.

WINDOWS: Heat gain from the sun.

 

 

No

Inside

Outside

(Area

 

 

 

Shades*

Shades*

Awnings* X Factor)

 

Northeast

*

These factors are for single glass

 

____sq. ft.

60

25

20 ____

Use

____

 

East

 

____sq. ft.

80

40

25 ____

only

____

 

 

only. For glass block, multiply the

 

 

Southeast

 

 

____sq. ft.

75

30

20 ____

the

____

 

 

above factors by 0.5; for double

 

 

South

 

 

____sq. ft.

75

35

20 ____

largest

____

 

 

glass or storm windows, multiply the

 

Southwest

 

above factors by 0.8.

 

____sq. ft.

110

45

30 ____

load.

____

 

West

 

 

 

____sq. ft.

150

65

45 ____

Use

____

 

Northwest

 

 

 

____sq. ft.

120

50

35 ____

only

____

 

North

 

 

 

____sq. ft.

0

0

0 ____

one.

____

 

 

 

 

 

 

 

 

 

 

2.

WINDOWS: Heat by conduction

 

 

 

 

 

 

 

 

 

(Total of all windows.)

 

 

 

 

 

 

 

_____

 

Single glass

 

 

____sq. ft.

 

14

 

 

 

 

Double glass or glass block

 

____sq. ft.

 

7

 

 

 

_____

 

 

 

 

 

 

 

3.

WALLS: (Based on linear feet of wall)

 

Light Construction

Heavy Construction

 

 

a. Outside walls

 

 

 

 

 

 

 

_____

 

North Exposure

 

____ ft.

30

 

20

 

 

Other than North exposure

 

____ ft.

60

 

30

 

_____

 

b. Inside Walls (between conditioned and

 

 

 

 

 

 

 

_____

 

unconditioned spaces only.)

 

____sq. ft.

 

30

 

 

 

 

 

 

 

 

 

 

 

 

 

4.

ROOF OR CEILING: (Use one only)

 

 

 

 

 

 

 

_____

 

a. Roof, uninsulated

 

____sq. ft.

 

19

 

 

 

 

b. Roof, 1 inch or more insulation

 

____sq. ft.

 

8

 

 

 

_____

 

c. Ceiling, occupied space above

 

____sq. ft.

 

3

 

 

 

_____

 

d. Ceiling, insulated, with attic space above

 

____sq. ft.

 

5

 

 

 

_____

 

e. Ceiling, uninsulated, with attic space above

 

____sq. ft.

 

12

 

 

 

_____

 

 

 

 

 

 

 

 

 

5.

Floor: (Disregard if fl oor is directly on ground or

____sq. ft.

 

3

 

 

 

_____

 

over a basement.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

6.

NUMBER OF PEOPLE

 

____

 

600

 

 

 

_____

 

 

 

 

 

 

 

 

 

7.

LIGHTS AND ELECTRICAL EQUIPMENT IN USE

____watts

 

3

 

 

 

_____

 

 

 

 

 

 

 

 

 

 

8.

DOORS AND ARCHES CONTINUOUSLY

 

 

 

 

 

 

 

_____

 

OPENED TO UNCONDITIONED SPACE: (TOTAL

____ft.

 

300

 

 

 

 

LINEAR FEET OF WIDTH.)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

9.

SUBTOTAL

 

 

*****

 

*****

 

 

 

_____

 

 

 

 

 

 

 

 

10. TOTAL COOLING LOAD (BTU per hour to be used

 

 

 

 

 

 

 

 

for selection of room air conditioner(s).)

____ Total in Item 9 X ____

(Factor from Map) =

____

 

 

 

 

 

 

 

 

 

 

 

 

81

Image 82
Contents Heat Pump with Electric Heat Cool OnlyCool with Electric Heat Heat Pump Volt YS10M10Table Of Contents Important Safety Information Your safety and the safety of others are very importantRefrigeration System Repair Hazards Property Damage Hazards Introduction Model and Serial Number LocationUnit Identification Specifications Performance DataInstallation Information / Sleeve Dimensions Electric Shock Hazard Electrical DataFire Hazard Make sure the wiring is adequate for your unit Control Panel Operation Special Functions System Exit Back FAN Mode Speed Display Schedule Enter Digital Control Panels Access Codes Summary Key Sequence ActionRemote Control Operation Remote Control Operation Electronic Control System Maintenance IntroductionElectronic Control System Maintenance Operation Test mode Bypasses Following functions Can be TestedTo Clear Error Codes’ History Factory USE onlyUnit Operation Front PanelCOOL-HEAT SET Points System Set Point Mapping FigureElectronic Control Sequence of Operation Compressor OperationHeating Mode Control Operation Heat Control Heat Pump OnlyHeat Pump With Electric Heat Operation ConditionElectric Heat Operation in Cool with Electric Heat Units Compressor Lock Out Time Fan Mapping During Heat Mode Unit Operation with a WALL-STATRemoving the Front Cover Replacing the Indoor Coil Thermistor Swing OutConnecting a Remote Wall Thermostat Remote Wall Thermostat Location Capacitor Check with Capacitor Analyzer Components TestingCapacitors Capacitor ConnectionsHeating Element Heat Pump Models Testing the Heating Element Electric Shock HazardHeating Element Drain PAN ValveRefrigeration Sequence of Operation 410A Sealed System Repair Considerations Refrigeration system under high pressureEquipment Must be Capable 410A Sealed Refrigeration System RepairsEquipment Required Risk of Electric ShockBurn Hazard Method Of Charging / RepairsFreeze Hazard Undercharged Refrigerant Systems Overcharged Refrigerant SystemsRestricted Refrigerant System Check Valve Hermetic Components CheckMetering Device Capillary Tube SystemsReversing Valve DESCRIPTION/OPERATION Reversing Valve in Heating Mode Testing the Reversing Valve Solenoid CoilChecking the Reversing Valve Touch Test in Heating/Cooling Cycle Procedure For Changing Reversing ValveExplosion Hazard Compressor Checks Ground Test Single Phase Resistance TestChecking Compressor Efficiency Recommended procedure for compressor replacement Compressor ReplacementHigh Temperatures High Pressure Hazard Routine Maintenance Decorative Front Cover Sleeve / DrainClearances Standard Filter Cleaning Installation Instructions Control Panel Battery Change Procedure Battery type Lithium, 3 Volts, #CR2450Service and Assistance Room AIR Conditioner Unit Performance Test Data Sheet Error Codes and Alarm Status IconTroubleshooting Tips Problem Possible Cause Possible SolutionTroubleshooting Tips Cooling only Room AIR Conditioners Troubleshooting Tips Problem Possible Cause Possible SolutionReplace fuse, reset breaker. If repeats, check Possible Cause Possible Solution Problem Possible Cause Possible Solution Heat / Cool only Room AIR Conditioners Troubleshooting Tips Bad outdoor coil thermistor Replace thermistorTroubleshooting Chart Heat Pump Heat Pump Room AIR Conditioners Trouble Shooting TipsProblem Possible Cause Action Heat Pump Electrical Troubleshooting Chart Heat PumpSystem Cools When Heating is Desired YESNormal Function of Valve Malfunction of ValveElectronic Control Board Components Identification DischargeRemote Wall Thermostat Wiring Diagrams Cool W/O Electric HeatSchematic Kuhl Electronic Control Cool only ModelsSL28M30A, SL36M30A KUHL+ Electronic Control Cool with Electric Heat Models ES12M33A, ES15M33A EM18M34A, EM24M34AKUHL+ Electronic Control Cool with Electric Heat Model EL36M35AKUHL+ Electronic Control Heat Pump only Model YS10M10AHeat KUHL+ Electronic Control Heat Pump with Electric Heat Model YL24M35ATHERMISTORS’ Resistance Values This Table Applies to All ThermistorsReplacement Remote Control Configuration Instructions Checking the Remote Control’s OPT # Code Replacement Instructions Aham PUB. NO. RAC-1 Heat Gain from Quantity Factors Cooling Load Estimate FormDAY Following is an example using the heat load form Heat Load FormWindows & Doors Area, sq. ft Heating Load Form Friedrich Room Unit Heat PumpsInfiltration Windows & Doors AVG Room AIR Conditioners Limited Warranty Technical Support Contact Information Friedrich AIR Conditioning CO
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R-410A specifications

Friedrich R-410A is an advanced refrigerant widely used in HVAC (Heating, Ventilation, and Air Conditioning) systems, known for its high efficiency and environmental friendliness. As a hydrofluorocarbon (HFC) blend, R-410A has become the preferred alternative to R-22, which is being phased out due to its ozone-depleting potential. One of the main features of R-410A is its high latent heat of vaporization, which allows for efficient heat transfer and improved cooling performance in air conditioning units.

Technologically, R-410A operates at higher pressures than older refrigerants, meaning systems designed for R-410A need to be built with more robust components to safely handle these pressures. This results in a more compact system design that offers enhanced performance and reliability. The dual-component nature of R-410A—composed of difluoromethane (R-32) and pentafluoroethane (R-125)—provides an optimal balance of thermodynamic properties, leading to superior energy efficiency, especially in variable speed applications.

In terms of characteristics, R-410A has a higher cooling capacity, which enables HVAC systems to effectively cool larger spaces or run more efficiently when cooling smaller areas. The refrigerant is non-toxic and non-flammable, which enhances safety during its use. In addition, R-410A has a lower global warming potential relative to other refrigerants, making it a more environmentally responsible choice for modern cooling systems.

Moreover, R-410A systems typically require less refrigerant charge due to their efficiency, contributing to reduced greenhouse gas emissions. The adoption of R-410A aligns with regulatory trends aimed at minimizing the environmental impact of refrigerants in cooling applications.

Overall, the Friedrich R-410A refrigerant embodies a combination of technology and environmental stewardship, making it a cornerstone of contemporary HVAC design. Its ability to provide effective and energy-efficient cooling solutions while being compliant with modern environmental regulations positions R-410A as the refrigerant of choice for engineers and installers focused on sustainability and performance in air conditioning systems.