Goodman Mfg AMV8 Circulating AIR and Filters, Ductwork AIR, Propane GAS Piping Charts

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For satisfactory operation, propane gas pressure must be 11 inch WC at the furnace manifold with all gas appliances in operation. Maintaining proper gas pressure depends on three main factors:

1.Vaporization rate, depending on temperature of the liquid, and “wetted surface” area of the container or containers.

2.Proper pressure regulation. (Two-stage regulation is recommended for both cost and efficiency).

3.Pressure drop in lines between regulators, and between second stage regulator and the appliance. Pipe size will depend on length of pipe run and total load of all appliances.

Complete information regarding tank sizing for vaporization, recommended regulator settings, and pipe sizing is available from most regulator manufacturers and propane gas suppliers.

Since propane gas will quickly dissolve white lead and most standard commercial compounds, special pipe dope must be used. Shellac-based compounds resistant to the actions of liquefied petroleum gases such as Gasolac®, Stalactic®, Clyde’s® or John Crane® are satisfactory.

Sizing Between Single or Second Stage Regulator and Appliance*

Maximum Propane Capacities Listed are Based on 1/2" W.C. pressure drop at 11" W.C. setting. Capacities in 1,000 BTU/hour.

Pipe or

 

 

 

 

 

 

 

Nominal Pipe Size

 

Tubing

 

Tubing Size, O.D. Type L

 

 

Schedule 40

 

Length,

3/8"

1/2"

5/8"

3/4"

7/8"

1-1/8"

1/2"

3/4"

1"

1-1/4"

1-1/2"

Feet

 

 

 

 

 

 

 

 

 

 

 

10

39

92

199

329

501

935

275

567

1,071

2,205

3,307

20

26

62

131

216

346

630

189

393

732

1,496

2,299

30

21

50

107

181

277

500

152

315

590

1,212

1,858

40

19

41

90

145

233

427

129

267

504

1,039

1,559

50

18

37

79

131

198

376

114

237

448

913

1,417

60

16

35

72

121

187

340

103

217

409

834

1,275

80

13

29

62

104

155

289

89

185

346

724

1,066

100

11

26

55

90

138

255

78

162

307

630

976

125

10

24

48

81

122

224

69

146

275

567

866

150

9

21

43

72

109

202

63

132

252

511

787

200

8

19

39

66

100

187

54

112

209

439

665

250

8

17

36

60

93

172

48

100

185

390

590

*Data in accordance with NFPA pamphlet NO. 54

X. CIRCULATING AIR AND FILTERS

DUCTWORK - AIR

Refer to the following illustration for typical propane gas installations

 

WARNING

 

and piping.

 

 

 

NEVER ALLOW THE PRODUCTS OF COMBUSTION, INCLUDING CARBON

 

 

MONOXIDE, TO ENTER THE RETURN DUCTWORK OR CIRCULATION AIR SUPPLY.

First Stage

5 to 15 PSIG

 

 

 

(20 PSIG Max.)

 

 

 

Regulator

Continuous

 

 

 

 

 

11" W.C.

200 PSIG

 

 

Second Stage

 

Maximum

 

 

Regulator

 

 

 

 

 

 

 

 

 

 

 

 

 

Propane Gas Installation (Typ.)

PROPANE GAS PIPING CHARTS

Sizing Between First and Second Stage Regulator*

Maximum Propane Capacities listed are based on 2 psig pressure drop at 10 psig setting. Capacities in 1,000 BTU/hour.

Pipe or

 

 

 

 

 

Nominal Pipe Size

Tubing

 

Tubing Size, O.D. Type L

 

Schedule 40

Length,

3/8"

1/2"

5/8"

3/4"

7/8"

1/2"

3/4"

Feet

 

 

 

 

 

 

 

10

730

1,700

3,200

5,300

8,300

3,200

7,500

20

500

1,100

2,200

3,700

5,800

2,200

4,200

30

400

920

2,000

2,900

4,700

1,800

4,000

40

370

850

1,700

2,700

4,100

1,600

3,700

50

330

770

1,500

2,400

3,700

1,500

3,400

60

300

700

1,300

2,200

3,300

1,300

3,100

80

260

610

1,200

1,900

2,900

1,200

2,600

100

220

540

1,000

1,700

2,600

1,000

2,300

125

200

490

900

1,400

2,300

900

2,100

150

190

430

830

1,300

2,100

830

1,900

175

170

400

780

1,200

1,900

770

1,700

200

160

380

730

1,100

1,800

720

1,500

To convert to capacities at 15 psig settings - multiply by 1.130

To convert to capacities at 5 psig settings - multiply by 0.879

Duct systems and register sizes must be properly designed for the CFM and external static pressure rating of the furnace. Ductwork should be designed in accordance with the recommended methods of “Air Conditioning Contractors of America” Manual D.

A duct system must be installed in accordance with Standards of the National Board of Fire Underwriters for the Installation of Air Conditioning, Warm Air Heating and Ventilating Systems. Pamphlets No. 90A and 90B.

A closed return duct system must be used, with the return duct connected to the furnace. NOTE: Ductwork must never be attached to the back of the furnace. Supply and return connections to the furnace may be made with flexible joints to reduce noise transmission. To prevent the blower from interfering with combustion air or draft when a central return is used, a connecting duct must be installed between the unit and the utility room wall. A room, closet, or alcove must not be used as a return air chamber.

When the furnace is used in connection with a cooling unit, the furnace should be installed in parallel with or on the upstream side of the cooling unit to avoid condensation in the heating element. With a parallel flow arrangement, the dampers or other means used to control the flow of air must be adequate to prevent chilled air from entering the furnace and, if manually operated, must be equipped with means to prevent operation of either unit unless the damper is in the full heat or cool position.

When the furnace is installed without a cooling coil, it is recommended that a removable access panel be provided in the outlet air duct. This opening shall be accessible when the furnace is installed and shall be of such a size that the heat exchanger can be viewed for visual light inspection or such that a sampling probe can be inserted into the airstream. The access panel must be made to prevent air leaks when the furnace is in operation.

When the furnace is heating, the temperature of the return air entering the furnace must be between 55°F and 100°F.

When a furnace is installed so that supply ducts carry air circulated by the furnace to areas outside the space containing the furnace, the return air shall also be handled by a duct sealed to the furnace casing and terminating outside the space containing the furnace.

IO-247A

20

12/04

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Contents Installation & Operating Table of Contents XII. Start-up Procedure and Adjustment XIV. Safety Circuit DescriptionXV. Troubleshooting XVI. MaintenanceII. Safety To the InstallerHomeowner Notice To the OwnerAdditional Safety Considerations Electrostatic Discharge ESD PrecautionsIII. Product Application American National Standards InstituteIV. Location Requirements and Considerations National Fire Protection AssociationCSA International National Fire Protection Association, IncThermostat Influences Furnace SuspensionThermostat Location Existing Furnace RemovalCombustion and Ventilation AIR Requirements Z223.1 Section GeneralEquipment Located in Unconfined Spaces Space, UnconfinedSpecially Engineered Installations Minimum Vent VI. Category I Venting Vertical VentingLouvers and Grilles Check 1 Proper Chimney Termination Checklist SummaryVII. Exterior Masonry Chimneys Category I Furnaces only Check 5 Liner Condition Check 4 Debris in CleanoutCheck 3 Chimney Crown Condition Check 7 Complete the Installation Check 6 Dilution AIRFIX 1 Liner Termination FIX 2 -CHANGE Venting ArrangementsWiring Harness VIII. Electrical ConnectionsVolt Line Connections Junction BOX RelocationVolt Thermostat Wiring Single Stage Thermostat ApplicationSetting the Heat Anticipator Volt Dehumidistat WiringSINGLE-STAGE Thermostat Application Fossil Fuel ApplicationsAltitude NAT. GAS Orifice Size IX. GAS Supply and PipingHigh Altitude Derate Meter Time in Minutes and Seconds for Normal Input Rating of Furnaces Equipped for USE with NaturalGAS AT 0 2,000 Feet Altitude GAS Piping ConnectionsPropane GAS Tanks and Piping Upflow InstallationsGAS Piping Checks Ductwork AIR Propane GAS Piping ChartsCirculating AIR and Filters XI. Sequence of Operation Integrated Ignition Control XII. START-UP Procedure and Adjustment White-Rodgers Model 36E54 Connected to ManometerGAS Manifold Pressure Measurement and Adjustment GAS Input Rate Measurement Natural GAS onlyTemperature Rise Circulator Blower Speed AdjustmentAdjust Blower Heat OFF Delay Circulator Blower FAN Timing AdjustmentXIII. Safety Circuit Description XIII. Operational ChecksXV. Troubleshooting XVI. MaintenanceXVII. Before Leaving AN Installation XVIII. Repair and Replacement PartsTroubleshooting Chart Continuously Wiring Diagram Are Subject to Change Without Notice

AMV8 specifications

Goodman Manufacturing has long been recognized as a key player in the HVAC industry, and the Goodman AMV8 stands out as a remarkable addition to their lineup of high-efficiency air conditioning units. Designed with the latest technological advancements, the AMV8 focuses on providing enhanced performance, energy efficiency, and reliability, making it a popular choice among homeowners and contractors alike.

One of the primary features of the Goodman AMV8 is its high SEER (Seasonal Energy Efficiency Ratio) rating, which typically reaches up to 16 SEER. This impressive rating signifies that the unit is capable of delivering substantial energy savings compared to older models. By using less electricity to cool your home, the AMV8 not only impacts utility bills positively but also contributes to reducing your carbon footprint.

The Goodman AMV8 is built with a powerful and efficient scroll compressor, known for its ability to operate quietly while maintaining a smooth and reliable performance. The advanced design minimizes vibration, ensuring a quieter operation, which is particularly appealing for residential settings. Additionally, the unit features a multi-speed ECM blower motor that enhances airflow consistency and operational efficiency.

Construction quality is also noteworthy with the Goodman AMV8. The cabinet is made of durable galvanized steel, coated with a corrosion-resistant finish that protects against rust and weather-related wear and tear. This durability extends the lifespan of the unit and provides assurance of quality to consumers.

Another characteristic that elevates the AMV8 is its integrated comfort control system. This feature allows users to easily manage cooling settings, ensuring optimal comfort throughout the home. The intelligent design of the unit includes a communicator control board, which optimizes system performance and simplifies installation.

The Goodman AMV8 also incorporates environmentally conscious technologies, including the use of R-410A refrigerant. This refrigerant is known for its efficiency and lack of ozone depletion potential, aligning with standards for environmentally friendly HVAC options.

In summary, the Goodman AMV8 is a high-efficiency air conditioning unit that showcases impressive features such as a high SEER rating, a reliable scroll compressor, a durable exterior, and advanced comfort control capabilities. Its commitment to energy efficiency and environmental consideration make it an exemplary choice for those seeking a dependable and cost-effective cooling solution for their homes. Whether for new installations or replacements, the AMV8 stands as a testament to Goodman Manufacturing's dedication to quality and innovation in HVAC technology.