Desa CDCFPR, CDCFTNA, CDCFTPA AIR for Combustion Ventilation, Providing Adequate Ventilation

Page 7

AIR FOR COMBUSTION

AND VENTILATION

Continued

PROVIDING ADEQUATE

VENTILATION

The following are excerpts from National Fuel Gas Code, ANSI Z223.1/NFPA 54, Section 5.3, Air for Combustion and Ventilation.

All spaces in homes fall into one of the three fol- lowing ventilation classifications:

1.Unusually Tight Construction

2.Unconfined Space

3.Confined Space

The information on pages 6 through 8 will help you classify your space and provide adequate ventilation.

Unusually Tight Construction

The air that leaks around doors and windows may provide enough fresh air for combustion and ventilation. However, in buildings of unusually tight construction, you must provide additional fresh air.

Unusually tight construction is defined as construction where:

a.walls and ceilings exposed to the out- side atmosphere have a continuous water vapor retarder with a rating of one perm (6 x 10-11kg per pa-sec-m2) or less with openings gasketed or sealed and

b.weather stripping has been added on openable windows and doors and

c.caulking or sealants are applied to areas such as joints around window and door frames, between sole plates and floors, between wall-ceiling joints, between wall panels, at penetrations for plumbing, electrical, and gas lines, and at other openings.

If your home meets all of these three criteria, you must provide additional fresh air. See Ventilation Air From Outdoors, page 8.

If your home does not meet all of the three criteria above, proceed to Determining Fresh-Air Flow For Fireplace Location.

Confined and Unconfined Space

The National Fuel Gas Code, ANSI Z223.1/NFPA 54 defines a confined space as a space whose volume is less than 50 cubic feet per 1,000 Btu per hour (4.8 m3 per kw) of the aggregate input

rating of all appliances installed in that space and an unconfined space as a space whose volume is not less than 50 cubic feet per 1,000 Btu per hour (4.8 m3 per kw) of the aggregate input rating of all appliances installed in that space. Rooms com- municating directly with the space in which the appliances are installed*, through openings not furnished with doors, are considered a part of the unconfined space.

*Adjoining rooms are communicating only if there are doorless passageways or ventilation grills between them.

DETERMINING FRESH-AIR FLOW FOR FIREPLACE LOCATION

Determining if You Have a Confined or Unconfined Space

Use this work sheet to determine if you have a confined or unconfined space.

Space: Includes the room in which you will install fireplace plus any adjoining rooms with doorless pas- sageways or ventilation grills between the rooms.

1.Determine the volume of the space (length x width x height).

Length x Width x Height =__________cu. ft. (volume of space)

Example: Space size 16 ft. (length) x 14 ft. (width) x 8 ft. (ceiling height) = 1792 cu. ft. (volume of space)

If additional ventilation to adjoining room is supplied with grills or openings, add the volume of these rooms to the total volume of the space.

2.Multiply the space volume by 20 to determine the maximum Btu/Hr the space can support.

__________ (volume of space) x 20 = (Maximum Btu/Hr the space can support)

Example: 1792 cu. ft. (volume of space) x 20 = 35,840 (maximum Btu/Hr the space can support)

3.Add the Btu/Hr of all fuel burning appliances in the space.

Vent-free fireplace

____________Btu/Hr

Gas water heater*

____________Btu/Hr

Gas furnace

____________Btu/Hr

Vented gas heater

____________Btu/Hr

Gas fireplace logs

____________Btu/Hr

Other gas appliances*

+____________Btu/Hr

Total

=____________Btu/Hr

*Do not include direct-vent gas appliances. Di- rect-vent draws combustion air from the outdoors and vents to the outdoors.

Example:

Gas water heater

 

30,000

Btu/Hr

Vent-free fireplace

+

10,000

Btu/Hr

Total

=

40,000

Btu/Hr

111244-01F

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Contents What to do if YOU Smell GAS Shown with Optional Cabinet Mantel/Hearth Base AccessoryTable of Contents Safety Information Product Identification Unpacking Optional Remote Control AccessoriesProduct Features Local CodesHex wrench Scissors Hood AssemblySheet Metal Screws Hood Louver Firebox Top Tools Required Phillips screwdriverProviding Adequate Ventilation AIR for Combustion VentilationDetermining FRESH-AIR Flow for Fireplace Location Ventilation Air From Inside Building Ventilation AIRVentilation Air From Outdoors Check GAS Type InstallationMinimum Clearance to Combustible Materials Installation ItemsBUILT-IN Fireplace Installation Fireplace ClearancesDepth If you have not installed hood, follow instruc- tions onActual Framing Height Front WidthMantel Clearances for Built-In Installation Optional Mantel InstallationMantel Shelf Installing Optional Blower Accessory GA3450TA Cord Installing Blower AccessorySwitch Plate Wire Remote Blower Harness Bracket Switch PlateTest to make sure blower is working properly For Built-In InstallationLower louver Connecting to GAS Supply Installation Items Needed Connecting Equipment Shutoff Valve to Heater ControlChecking GAS Connections Gas Meter Correct all leaks at onceEquipment Open Shutoff Valve Closed Gas Regulator or Equipment Gas Control ValveOptional Wall Mounted Optional Wireless HAND-HELD Remote Control AccessoriesInstalling Receiver Installing 9-Volt Battery in Hand-Held Remote Control UnitRemove jumper wire from control valve see , Feed wires through rectangular slotsTerminal W Terminal R R Log Set Log Shoulder Screw Brick Liner Bracket ScreenRear Brick Liner Left Brick LinerIgnitor Button Control Knob For Your Safety Read Before LightingOperating Fireplace Lighting InstructionsOperating Blower Manual Lighting ProcedureTo Turn OFF GAS To Appliance Thermostat Control OperationAUTO/OFF/ON Switch REMOTE-READY Models For Your Safety Read Before LightingPiezo Flame Control Ignitor Adjustment Knob Button Pilot Burner Ignitor Electrode If Using Optional Hand-Held RemoteOptional HAND-HELD Remote Operation Pilot Ignitor Burner ElectrodeThermostat Series Model HRC200 Series Manual ModeAuto Thermostatic Mode ON/OFF Series Model HRC100Pilot Flame Pattern Optional GWMS2 Wall Mounted SwitchInspecting Burners Optional GWMT1 Wall Mounted ThermostatIf pilot flame pattern is incorrect, as shown in , Cleaning MaintenanceBurner Flame Pattern Burner Injector Holder and Pilot AIR Inlet HoleRemote-Ready Models Only Wiring DiagramLOG SET CabinetIgnitor cable dry TroubleshootingObserved Problem Possible Cause Remedy Ignitor cable pinched or wetOr replace burner orifice Burner orifice is cloggedMote-Ready Models Only Models OnlySlight smoke or odor during When heated, vapors fromWalls or furniture Cleaners, etc. may turn into Mote-Ready Models Only Power is lowMent above Gas odor even when controlFireplace produces unwanted Ers, chemicals, new carpetDimensions H x W x D including hood SpecificationsThermostat Models Parts Under Warranty Replacement PartsService Hints Technical ServiceIllustrated Parts Breakdown Parts List Cdcfpr Outer Casing Firebox Models Cdcfnr and Cdcfpr104281-02BR Firebox Hood Firebox Top Illustrated Parts Breakdown Hardware Pack Brass Flare Adapter FittingLighting Instruction Plate Not a field replaceable part FDCFTN/TP VDCFRN/RP CDCFNR/PR Lighting Instruction Plate Brass Trim KIT GA6095 AccessoriesTHERMOSTAT-CONTROLLED Blower KIT GA3450TA Equipment Shutoff Valve GA5010Information Video WALL-MOUNT Thermostat Switch GWMT1WALL-MOUNT ON/OFF Switch GWMS2 Receiver and HAND-HELD Remote Control KIT HRC100 Series111244-01F 111244-01F 111244-01

CDCFTNA, CDCFPR, CDCFTPA specifications

Desa CDCFTPA, CDCFPR, and CDCFTNA represent a suite of advanced technologies and methodologies employed in the development and management of efficient distribution networks within the field of telecommunications and data services. These frameworks are designed to enhance connectivity, streamline processes, and ensure optimal performance in various environments.

One main feature of Desa CDCFTPA (Coaxial Digital Channel Fiber Transmission Protocol Architecture) is its ability to integrate coaxial cables with fiber optic technology, enabling high-speed data transmission over existing infrastructures. This hybrid approach not only reduces the need for extensive renovations but also capitalizes on the advantages of both technologies, offering broadband accessibility and improved bandwidth capabilities. By leveraging both mediums, operators can deliver enhanced services while maintaining cost-efficiency.

CDCFPR (Centralized Data Control Fiber Processing Resource) represents a centralized approach to managing data flow within telecommunications networks. Its core characteristic lies in its architecture, which supports dynamic allocation of resources in real-time. This enables network operators to efficiently allocate bandwidth based on demand, optimize routing paths, and reduce latency. Additionally, CDCFPR employs advanced algorithms for data compression and encryption, ensuring that users experience a seamless and secure connection.

CDCFTNA (Carrier Digital Channel Fiber Transmission Network Architecture) is focused on creating robust networks that can support a variety of distribution channels, including 5G and IoT devices. Its design emphasizes scalability and adaptability, allowing network providers to easily expand or modify their infrastructure to meet evolving market needs. Key technologies incorporated in CDCFTNA include Software-Defined Networking (SDN) and Network Function Virtualization (NFV), which enable operators to manage their resources more flexibly and efficiently.

Each of these frameworks boasts unique characteristics that contribute to the overall enhancement of telecommunications systems. They embody a commitment to innovation, sustainability, and user-centric design, aligning with current trends in digital services and communication technologies. By deploying such advanced systems, service providers can ensure they remain competitive in a fast-paced and continuously evolving market. In summary, Desa CDCFTPA, CDCFPR, and CDCFTNA collectively represent the future of telecommunications infrastructure, promising improved connectivity, efficiency, and adaptability for a diverse range of applications.
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