2 combustion air requirements for a heater, Located in a confined space, 0 uncrating and preparation – Reznor X Unit Installation Manual User Manual

Form I-X, P/N 150491 R10, Page 4

2.2 Combustion Air

Requirements

for a Heater

Located in a

Confined Space

Confined

Space

(1)

(2)

(3)

(3)

(2)

(1)

FIGURE 1 - Confined

Space: A space whose

volume is less than

50 cubic feet per 1000

BTUH of the installed

appliance input rating

3.0 Uncrating and

Preparation

3.1 Uncrating and Inspecting

This furnace was test operated and inspected at the factory prior to crating and was in

operating condition. If the furnace has incurred any damage in shipment, document the

damage with the transporting agency and immediately contact an authorized Reznor

distributor. If you are a Reznor distributor, follow the FOB freight policy procedures as

published by Reznor for Reznor products.
Check the rating plate for the gas specifications and electrical characteristics of the

furnace to be sure that they are compatible with the gas and electric supplies at the

installation site.

2.0 Furnace

Location

(cont'd)

WARNING

These furnaces are designed to take combustion air from the space in which the unit is installed

and are not designed for connection to outside combustion air intake ducts. Connecting outside air

duct voids the warranty and could cause hazardous operation. See Hazard Levels, page 2.

These duct furnaces are designed to take combustion air from the space in which the

furnace is installed. The air that enters into the combustion process is vented to the

outdoors. Sufficient air must enter the equipment location to replace the air exhausted

through the vent system. Modern construction methods involve the greater use of insu-

lation, improved vapor barriers and weather-stripping, with the result that buildings

generally are much tighter structurally than they have been in the past. The combus-

tion air supply for gas-fired equipment can be affected by these construction conditions

because infiltration that would have existed in the past may not be adequate. Exten-

sive use of exhaust fans aggravates the situation. In the past the filtration of outside

air assumed in heat loss calculations (one air change per hour) was assumed to be

sufficient. However, current construction methods may now require the introduction of

outside air into the space through wall openings or ducts.
Requirements for combustion air and ventilation air depend upon whether the unit

is located in a confined or unconfined space. An "unconfined space" is defined as a

space whose volume is not less than 50 cubic feet per 1000 BTUH of the installed

appliance. Under all conditions, enough air must be provided to ensure there will not

be a negative pressure condition within the equipment room or space. A positive seal

must be made in all return-air connections and ducts. Even a slight leak can create a

negative pressure condition in a confined space and affect combustion.
Do not install a unit in a confined space without providing wall openings leading to and

from the space. Provide openings near the floor and ceiling for ventilation and air for

combustion as shown in

FIGURE 1, depending on the combustion air source as noted

in Items 1, 2, and 3 below the illustration.
Add total BTUH of all appliances in the confined space and divide by figures below for

square inch free area size of each (top and bottom) opening.
1. Air from inside the building -- openings 1 square inch free area per 1000 BTUH.

Never less than 100 square inches free area for each opening. See (1) in

FIGURE 1.

2. Air from outside through duct -- openings 1 square inch free area per 2000

BTUH. See (2) in

FIGURE 1.

3. Air direct from outside -- openings 1 square inch free area per 4000 BTUH. See

(3) in

FIGURE 1.

NOTE: For further details on supplying combustion air to a confined space, see the

National Fuel Gas Code ANSI Z223.1a (latest edition ).

Hazards of Chlorine

The presence of chlorine vapors in the combustion air of gas-fired heating equipment

presents a potential corrosion hazard. Chlorine will, when exposed to flame, precipitate

from the compound, usually freon or degreaser vapors, and go into solution with any

condensation that is present in the heat exchanger or associated parts. The result is

hydrochloric acid which readily attacks all metals including 300 grade stainless steel.
Care should be taken to separate these vapors from the combustion process. This may

be done by wise location of the furnace with regard to exhausters or prevailing wind

direction. Remember, chlorine is heavier than air. This fact should be kept in mind when

determining installation locations of heating equipment and building exhaust systems.