This disclosure relates to enclosures for HVAC systems, and particularly to an enclosure having one or more heating elements or burner boxes positioned between the floor and the roof of such enclosure to provide for easier access to the heating elements or burner boxes and improve the air flow through the enclosure.
Large buildings such as factories, warehouses, hospitals, schools, arenas and the like require HVAC systems to heat and cool the air in the structure. The equipment is usually placed outside the building, either at ground level or on the roof of the structure. Accordingly, air intakes must be designed to block the inflow of precipitation, such as rain or snow, while still allowing air to enter the enclosure. Likewise, sufficient airflow must be maintained around the heating and cooling elements contained within the enclosure.
A general configuration of such structures may be seen in U.S. Pat. No. 8,186,119, issued to Huff et al, which depicts, in general terms, the type of HVAC enclosure utilized to enclose and protect the operating elements of the HVAC system. As above referenced, these enclosures are often roof mounted, or positioned at some height above the ground. Many such enclosures are several feet in height and pose a risk of injury from maintenance personnel falling from the top of such enclosures.
As shown in attached prior art
In such prior art designs, the air intake is mounted to the roof of the structure, and the burner box is interposed between the air intake and roof of the enclosure. Accordingly, service of the air intake and the burner box requires working from the roof of the structure. Further, the amount of airflow available to the interior of the unit is a function of the dimensions of the air intake structure. If the dimensions of the air intake structure are limited, the force and velocity of the incoming air through the air intake structure may be increased which may pull in snow or rain into the enclosure thereby affecting the performance of the HVAC system. Additionally, the enclosure must be designed with sufficient strength for the roof to support both the air intake and the burner box which may increase the cost of the enclosure. Such a structure also requires the air intake structure and burner box to be built and shipped as modules which increases the costs of shipping and assembling the enclosure.
The present disclosure relates an air handling apparatus for a HVAC system for a building. The air handling apparatus includes an enclosure having at least one inlet opening for drawing outside air into the enclosure, and at least one outlet opening for directing air from within the enclosure to outside the enclosure. At least one fan is located within the enclosure for drawing air through the enclosure. A burner box is mounted within the enclosure for heating outside air drawn into the enclosure through the at least one inlet opening and may be centrally located within the enclosure.
The enclosure may include a pair of side walls, a pair of end walls, a roof, and a floor. The burner box may be positioned between the roof and floor of the enclosure. The at least one inlet opening may be formed in the roof or side walls of the enclosure. Downwardly extending louvers may be formed within the at least one inlet opening. The floor of the enclosure may be formed from an open grate material which creates a floor air inlet for allowing outside air to flow into the enclosure.
The at least one outlet may be formed in the end walls of the enclosure. A duct system may be in communication with the at least one outlet to direct air from within the enclosure to a predetermined location.
The invention is best understood from the following detailed description when read in conjunction with the accompanying drawings. It is emphasized that, according to common practice, the various features of the drawings are not to-scale. On the contrary, the dimensions of the various features are arbitrarily expanded or reduced for clarity.
Initially, reference to the prior art device shown in
As seen in
As seen in
Air conditioning evaporator coils 216 may also be provided within the enclosure 202 to provide cool air to the building. The air conditioning evaporator coils 216 are associated with a separate compressor (not shown) external to the enclosure 202, thereby providing a source of refrigerated air to the building in a fashion well-known to those skilled in the art. As a non-limiting example, four sets of the air conditioning evaporator coils 216 may be provided within the enclosure 202 wherein two sets of the air conditioning evaporator coils 216 are mounted at an angle with respect to one another at each end of the enclosure 202. The two sets of air conditioning evaporator coils 216 mounted at an angle with respect to one another form a āVā shape wherein the open portion of the V-shape is open to the middle or center of the enclosure 202 to receive the flow of air which travels from the mid-section or plenum of the enclosure 202 toward the end walls 205 of the enclosure 202. This provides for proper heat transfer as the air is cooled when passing over the air conditioning evaporator coils 216.
The HVAC system 200 of the present invention is unique over the prior art in that a burner box 212 is centrally mounted within the six sides 204, 205, 206, 208 of the enclosure 202, and the burner box 212 is positioned at a working height in relation to the floor 208 of the enclosure 202. By having the burner box 212 mounted between the roof 206 and the floor 208 within the enclosure 202 as opposed to on the roof 106 of the enclosure, maintenance can be performed on the burner box 212 without having to climb onto the roof of the enclosure 202 thereby enhancing the safety of the maintenance worker. In addition, maintenance can be performed within the enclosure 202 by allowing access to the interior of the enclosure 202 through a door in the end walls 205 or side walls 204 of the enclosure 202 thereby protecting the maintenance worker from any harsh environmental conditions. The burner box 212 operates in the same manner as described in the prior art, that is, intake air is directed into the burner box 212 from openings 222 provided in the side walls 204 and/or the roof 206 of the enclosure 202, as will be described below. The burner box 212 is gas fired and heats the intake air as the intake air passes through the burner box 212. The heated air is then directed to the outlet openings in the end walls 205 via the fans 210.
In order to enhance air flow through the enclosure 202 and prevent precipitation from entering the enclosure 202, downwardly angled louvers 218 may be mounted within the inlet openings 222 extending along the roof 206 and/or the side walls 104 of the enclosure 202. By providing a sufficient number of inlet openings and louvers 218 along the side walls 204 and the roof 206 of the enclosure 202, the incoming air flows into the enclosure 202 at a lower force and velocity than provided in the prior art design, and thus, precipitation and/or snow are not pulled into the enclosure by the incoming air. In addition, the louvers are angle downward thereby directing and deflecting precipitation and/or snow from entering the enclosure 202 and affecting the performance of the HVAC system 200. At least a portion of the floor 208 of the enclosure 202 is formed of a rigid, open grate material which allows incoming outside air to flow through a floor air inlet formed in the grate material. The grate material in the floor 208 of the enclosure ensures for proper air flow into and through the enclosure 202 while ensuring that precipitation and/or snow cannot enter the interior of the enclosure 202.
In this fashion, the present disclosure presents a configuration which provides convenient service access to the burner box 212 and other internal components of the HVAC system 200, without the need for access to the roof 206 of the enclosure 202. The enclosure 202 of the HVAC system 200 is also lighter in weight than prior art devices and occupies a smaller footprint where installed. In addition, the present disclosure provides a simplified assembly which can be shipped to the job site in fewer sections, since the burner box 212 is contained within the enclosure and does not require a separate intake hood 114. The increased air intake dimensions over the prior art also permit a reduction in incoming air velocity while still providing sufficient volumes of air thereby prohibiting precipitation and/or snow from being pulled into the disclosure.
While the invention has been described in connection with certain embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures as is permitted under the law.
This application claims the benefit of U.S. Provisional Application Ser. No. 62/554,643, filed on Sep. 6, 2017, the entire disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20190137139 A1 | May 2019 | US |
Number | Date | Country | |
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62554643 | Sep 2017 | US |