Bryant 355CAV Astm, Material Pipe Fittings, Description, Cement, Marked on Primers Material

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Table 5 – Approved Combustion-Air and Vent Pipe, Fitting and Cement Materials

ASTM

 

 

 

 

 

SPECIFICATION

MATERIAL

PIPE

FITTINGS

SOLVENT

DESCRIPTION

CEMENT

 

 

 

 

 

(MARKED ON

 

 

 

AND PRIMERS

 

MATERIAL)

 

 

 

 

 

 

 

 

 

D1527

ABS

Pipe

Schedule40

D1785

PVC

Pipe

Schedule40

D2235

For ABS

Solvent

For ABS

 

 

 

 

Cement

 

D2241

PVC

Pipe

SDR21 & SDR26

D2466

PVC

Fittings

Schedule40

D2468

ABS

Fittings

Schedule40

D2564

For PVC

Solvent

For PVC

 

 

 

 

Cement

 

D2661

ABS

Pipe

Fittings

DWV at Schedule40 IPS sizes

D2665

PVC

Pipe

Fittings

DWV

F438

CPVC

Fittings

Schedule40

F441

CPVC

Pipe

Schedule40

F442

CPVC

Pipe

SDR

F493

For CPVC

Solvent

For CPVC

 

 

 

 

Cement

 

F628

ABS

Pipe

Cellular Core DWV at Schedule40

IPS sizes

 

 

 

 

 

F656

For PVC

Primer

For PVC

F891

PVC

Pipe

Cellular Core Schedule40 &

DWV

 

 

 

 

 

355CAV

Installation Guidelines for Combustion Air Pipe and Vent Pipe

It is recommended that all pipes be cut, prepared, and preassembled before permanently cementing any joint.

1.Attach combustion air pipe and vent pipe per instructions in sections “Combustion Air Pipe” and “Vent Pipe.”

2.Working from furnace to outside, cut pipe to required length(s).

3.Deburr inside and outside of pipe.

4.Chamfer outside edge of pipe for better distribution of primer and cement.

5.Clean and dry all surfaces to be joined.

6.Check dry fit of pipe and mark insertion depth on pipe.

7.After pipes have been cut and preassembled, apply generous layer of cement primer to pipe fitting socket and end of pipe to insertion mark. Quickly apply approved cement to end of pipe and fitting socket (over primer). Apply cement in a light, uniform coat on inside of socket to prevent buildup of excess cement. Apply second coat.

8.While cement is still wet, twist pipe into socket with 1/4 turn. Be sure pipe is fully inserted into fitting socket.

9.Wipe excess cement from joint. A continuous bead of cement will be visible around perimeter of a properly made joint.

10.Handle pipe joints carefully until cement sets.

11.Horizontal portions of the venting system shall be supported to prevent sagging. Support combustion air

piping and vent piping a minimum of every 5 ft (1.5 m)(3 ft (.91 m) for SDR-21 or -26 PVC) using perforated metal hanging strap.

12.Slope combustion air piping and vent piping downward towards furnace a minimum of 1/4-in. per linear ft with no sags between hangers.

13.Horizontal portions of the venting system shall be installed so as to prevent the accumulation of condensate.

14.Use appropriate methods to seal openings where combustion air pipe and vent pipe pass through roof or sidewall.

Combustion-Air and Vent Pipe Diameter

Determine combustion-air and vent pipe diameter.

1.Using Table 7, individually determine the diameter of the combustion-air and vent pipe allowed. If different, pick the larger of these two diameters and use this diameter for both combustion-air and vent pipes.

2.When installing vent systems of short pipe length, use the smallest allowable pipe diameter. Do not use pipe size greater than required or incomplete combustion, flame disturbance, or flame sense lockout may occur.

NOTE: Do not count elbows or pipe sections in terminations or within furnace.

NOTE: A 2-in. diameter pipe must be used within furnace casing. Make all pipe diameter transitions outside furnace casing.

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Contents Table of Contents Installation InstructionsRequired Notice for Massachusetts Installations CUT Hazard Safety ConsiderationsDimensional Drawing Dimensions In. / mmInstallation Codes and Standards Upflow Application Electrostatic Discharge ESD PrecautionsIntroduction ApplicationsCondensate Trap Alternate Upflow Orientation Carbon Monoxide Poisoning HazardCondensate Trap Tubing Alternate Upflow Orientation Upper Inducer Housing Drain Connection Condensate Trap Field Drain AttachmentCondensate Trap Freeze Protection Condensate Trap Location Downflow ApplicationsHorizontal Left SUPPLY-AIR Discharge Applications Horizontal Left Tube ConfigurationManual Shutoff GAS Valve Sediment Trapcondensate Trap Property DamageHorizontal Right SUPPLY-AIR Discharge Applications Construct a Working PlatformUnit Operation Hazard Condenste Trap Field Drain Attachment LocationFire or Death Hazard Prohibit Installation on BackInstallation FIRE, EXPLOSION, Injury or Death HazardUnit MAY not Operate Hazard Furnace, Plenum, and Coil Assembly or Coil Box Locations Reqd PER ROD AIR Ducts Fire Hazard FIRE, Carbon Monoxide and Poisoning HazardUnit MAY not Operate Bottom Closure Panel Gas PipingFire or Explosion Hazard Removing Bottom Closure Panel Wiring Maximum Capacity of PipeElectrical Shock Hazard Electrical Shock and Fire Hazard Disconnect Switch and FurnaceFactory Installed J-Box Location AccessoriesFire or Electrical Shock Hazard Fire and Explosion Hazard AIR for Combustion and VentilationCement AstmMaterial Pipe Fittings DescriptionFurnace Control Direct Vent Termination Clearance Ventilated Combustion Air Vent Termination Clearance Vent Pipe Termination for Ventilated Combustion Air System Unit Corrosion Hazard Combustion AIR PipeCombustion Air Termination Ventilated Combustion Air Option Attachment of Combustion Air Intake Housing Plug FittingAttachment of Vent Pipe Vent PipeCombustion Air Termination-Direct Vent / 2-Pipe System Carbon Monoxide Poisoning Property Damage Hazard304.8mm minimum 76.2mm minimum Extended Exposed Sidewall Pipes Vent TerminationTwo-Pipe Termination Kit Direct Vent/2-Pipe System Only Vent Termination Kit Direct Vent/2-Pipe System Only042060 Btuh Maximum Allowable Pipe Length Ft / MUnit Size Personal Injury Hazard Condensate DrainAdditional Setup Switches SW4 START-UP, Adjustment and Safety CheckAir Conditioning A/C Setup Switches Continuous Fan CF Setup SwitchesPrime Condensate Trap with Water Example of Setup Switch in Off PositionWiring Diagram Furnace Setup Switch Description Inducer Housing Drain TubePurge Gas Lines Sequence of OperationTwo-Stage Thermostat and Two-Stage Low / High Heating See -55 for thermostat connections Thermidistat ModeHeat Pump Super Dehumidify ModeContinuous Blower Mode Continuous Blower Speed Selection from ThermostatStep-Modulating Furnace with Single-Speed Air Conditioning Furnace and Two-Speed Heat Pump Pump Furnace and Two-Speed Air ConditionerRedundant Automatic Gas Valve Set Gas Input RateBurner Orifice A07253 A07254 Burner Flame Altitude Derate Multiplier for U.S.ASet Temperature Rise Gas Rate cu Ft/HrSet Thermostat Heat Anticipator Check Primary Limit Control ChecklistCheck Safety Controls Check Pressure SwitchesCombustion and Vent Piping Checklist Installation
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355CAV specifications

The Bryant 355CAV is a state-of-the-art automated vertical machining center designed to enhance precision and efficiency in the manufacturing sector. Renowned for its robust construction, this machine is engineered to handle a broad spectrum of machining tasks, making it suitable for both small and large-scale production environments.

One of the standout features of the Bryant 355CAV is its advanced CNC control system, which provides users with exceptional ease of use. The intuitive user interface allows operators to program complex machining operations with minimal effort, significantly reducing setup times. The machine's high-speed spindle achieves impressive rotational speeds, which allows for quick material removal, ultimately optimizing productivity and throughput.

The Bryant 355CAV exhibits superior rigidity and stability due to its solid cast iron frame and carefully designed structural components. This construction minimizes vibrations during machining, ensuring that even the most intricate parts are produced with high accuracy. The machine's precision ground linear guideways further enhance its performance by providing smooth motion and high load capacity.

Equipped with a large work envelope, the Bryant 355CAV enables manufacturers to accommodate various part sizes and geometries. Additionally, its automatic tool changers can hold a variety of tools, thus facilitating quick transitions between different machining operations without requiring manual intervention. This flexibility is essential for meeting the diverse needs of modern manufacturing.

Another notable characteristic of the Bryant 355CAV is its energy-efficient design. It integrates modern technologies aimed at reducing power consumption while maintaining optimum performance. This environmentally conscious approach not only cuts operational costs but also aligns with the growing demand for sustainable manufacturing practices.

Moreover, the Bryant 355CAV features advanced monitoring capabilities, allowing operators to track machine performance in real time. Data analytics from these systems can be utilized to improve operational efficiency, reduce downtime, and enhance predictive maintenance protocols.

In summary, the Bryant 355CAV is a versatile, high-performance machining center that showcases cutting-edge features and technologies. Its combination of user-friendly controls, sturdy construction, energy efficiency, and advanced monitoring positions it as a vital asset for manufacturers aiming to elevate their productivity and precision in an increasingly competitive landscape.