Goodman Mfg ANSI Z21.47CSA-2.3 installation instructions Drive Belt Tension Adjustment

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System Voltage - That nominal voltage value assigned to a circuit or system for the purpose of designating its voltage class.

Nameplate Voltage - That voltage assigned to a piece of equipment for the purpose of designating its voltage class and for the purpose of defining the minimum and maximum voltage at which the equipment will operate.

Utilization Voltage - The voltage of the line terminals of the equipment at which the equipment must give fully satisfac- tory performance. Once it is established that supply voltage will be maintained within the utilization range under all sys- tem conditions, check and calculate if an unbalanced condi- tion exists between phases. Calculate percent voltage un- balance as follows:

Three Phase Models

 

 

2) MAXIMUM VOLTAGE DEVIATIONS

3) PERCENT VOLTAGE

= 100 X

 

FROM AVERAGE VOLTAGE

 

UNBALANCE

 

 

1) AVERAGE VOLTAGE

 

 

 

HOW TO USE THE FORMULA:

EXAMPLE: With voltage of 220, 216, and 213

1)Average Voltage = 220+216+213=649 / 3 = 216

2)Maximum Voltage Deviations from Average Voltage = 220 - 216 = 4

3) Percent Voltage Unbalance = 100 x

4

=

400

= 1.8%

216

216

 

 

 

Percent voltage unbalance MUST NOT exceed 2%.

FIELD DUCT CONNECTIONS

Verify that all duct connections are tight and that there is no air bypass between supply and return.

CONTROL VOLTAGE CHECK

With disconnect switch in the open “OFF” position, discon- nect blue wire from low voltage transformer TRANS1. Close the disconnect switch to energize TRANS1 control trans- former. Check primary and secondary (24V) of control trans- former TRANS1.

THERMOSTAT PRELIMINARY CHECK

With disconnect switch open and blue wire disconnected from TRANS1 transformer, attach one lead of ohmmeter to termi- nal R on TB1 terminal block. Touch, in order, the other ohm- meter lead to terminals Y1, Y2 and G at TB1 terminal block. There must be continuity from terminal R to terminals Y and G. R to Y indicates cool. R to G indicates fan (auto). Replace blue wire on TRANS1 transformer.

FILTER SECTION CHECK

Remove filter section access panels and check that filters are properly installed. Note airflow arrows on filter frames.

BEARING CHECK

Prior to energizing any fans, check and make sure that all setscrews are tight so that bearings are properly secured to shafts.

SET EVAPORATOR FAN RPM

Actual RPM’s must be set and verified with a tachometer or strobe light. Refer to Appendices A and B for basic unit fan RPM. Refer also to “Airflow” section of this manual. With disconnect switch open, disconnect thermostat wires from terminals Y and W. This will prevent heating and mechanical cooling from coming on. Place a jumper wire across termi- nals R and G at TB1 terminal block. Close disconnect switch; evaporator fan motor will operate so RPM can be checked.

For gas heat units, the airflow must be adjusted so that the air temperature rise falls within the ranges given stated on Data Plate (see Appendix A - Blower Performance).

TENSION AND ALIGNMENT ADJUSTMENT

Correct belt tension is very important to the life of your belt. Too loose a belt will shorten its life; too tight, premature mo- tor and bearing failure will occur. Check you belt drive for adequate “run-in” belt tension by measuring the force required to deflect the belt at the midpoint of the span length. Belt tension force can be measured using a belt tension gauge, available through most belt drive manufacturers.

t = Span length, inches

C = Center distance, inches

D = Larger sheave diameter, inches d = Smaller sheave diameter, inches

h = Deflection height, inches

DRIVE BELT TENSION ADJUSTMENT

 

TYPE

SHEAVE

DEFLECTION

DEFLECTION

MODEL

DIAMETER

FORCE (lbs)

(in)

 

 

 

(in)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

BELT

DRIVE

 

Used

New

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

15 Ton

B, BA

Standard

4.3 to 5.5

5.5 + .5

8.2 + .5

1/4 ± 1/16

 

 

 

 

 

 

 

15 Ton

B, BA

High

4.3 to 5.5

5.5 + .5

8.2 + .5

1/4 ± 1/16

Static

 

 

 

 

 

 

 

 

 

 

 

 

 

20 Ton

B, BA

Standard

4.3 to 5.5

5.5 + .5

8.2 + .5

1/4 ± 1/16

 

 

 

 

 

 

 

20 Ton

B, BA

High

4.3 to 5.5

5.5 + .5

8.2 + .5

1/4 ± 1/16

Static

 

 

 

 

 

 

RECOMMENDED POUNDS OF FORCE PER BELT

The correct deflection force is 5 Ibs. for a new belt and 3.5 Ibs. for a belt that has been run in. New belt tension includes initial belt stretch. When new V-belts are installed on a drive the initial tension will drop rapidly during the first few hours.

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Contents CPG Series Safety Instructions Replacement PartsGeneral Information High VoltageUnit Location Electrical Entrance Locations Before installing this unitUnit Clearances ClearancesRigging Details Roof Curb POST-INSTALLATION ChecksRoof Curb Installation Roof TOP Duct ConnectionsCorner & Center of Gravity Locations Electrical WiringDrop Power and LOW Voltage Block LocationsCPG240 GAS Heat GAS Supply PipingProper Piping Practice Natural Gas ConnectionTypical Propane GAS Piping Propane GAS InstallationsCirculating AIR and Filters Venting Condensate Drain ConnectionDrain Connection Moving Machinery Hazard STARTUP, ADJUSTMENTS, and ChecksRecommended Pounds of Force PER Belt Drive Belt Tension AdjustmentRollout Protection Control With Power And Gas On Burn Hazard Normal Sequence of Operation Heat Exchanger and Burner Orifice SpecificationsCheck rollout limit TroubleshootingInput Rating AIR Flow AdjustmentsMaintenance Motor Sheave AdjustmentsBurner Flame CPG180 Standard Belt Drive Appendix a Blower Performance Data Belt Drive High Static Appendix B Electrical Data Vertical Discharge TOP View Appendix C Unit DimensionsIIC 0140L00955 REV a IIC 0140L00957 REV a

ANSI Z21.47CSA-2.3 specifications

Goodman Manufacturing's ANSI Z21.47/CSA 2.3 standard is pivotal in ensuring safety and performance in gas appliances and their components. This industry benchmark outlines rigorous safety regulations for residential gas conversion appliances, specifically focusing on categories like storage water heaters, pool heaters, and certain types of boilers.

One of the main features of Goodman’s offering under this standard is its emphasis on user safety. The ANSI Z21.47/CSA 2.3 certification mandates the implementation of robust safety mechanisms to prevent accidents associated with gas leaks or malfunctions. This includes enhanced safety controls and features that mitigate the risk of combustion-related incidents, ensuring peace of mind for both manufacturers and consumers.

Technologically, Goodman Mfg has integrated advanced electronic ignition systems into its products, eliminating the need for pilot lights while enhancing energy efficiency. This technology not only reduces the risk of accidental fires but also contributes to lower energy consumption, making it an environmentally friendly option. Additionally, models compliant with this standard often incorporate smart technology, allowing for remote monitoring and control. This feature further enhances user convenience and energy management, granting homeowners the ability to optimize their energy usage.

In terms of construction and design characteristics, Goodman’s appliances are built to withstand varied operating conditions. They are designed with high-quality materials that provide durability and reliability over time, essential for maintaining performance and safety. These appliances typically feature built-in corrosion protection mechanisms to prolong their lifespan, especially in humid or corrosive environments.

Moreover, Goodman’s adherence to the ANSI Z21.47/CSA 2.3 standard signifies their commitment to energy efficiency, aligning with modern-day sustainability goals. Appliances that meet this standard often exceed governmental energy efficiency mandates, making them a wise investment for consumers aiming to reduce their carbon footprint while enjoying high-performance utility.

In conclusion, Goodman Manufacturing’s adherence to ANSI Z21.47/CSA 2.3 marks a significant dedication to safety, efficiency, and innovation in the gas appliance sector. Through advanced technologies, robust safety features, and a commitment to user satisfaction, Goodman continues to set the standard for excellence in home heating and water heating solutions.