This invention relates generally to air treatment modules, such as, for example, heating units, ventilation units including a heat exchanger, or air conditioning (HVAC) units, and, more particularly, to improvement of heat exchanger performance in such air treatment modules. Air treatment units of the type including an air heating module are commonly used in connection with residential and commercial buildings to heat air for supply to a climate controlled space. Such air treatment units include, for example, products designed with both heating and cooling capability and also seasonal heating products.
Commercial HVAC units including a heating function in addition to a cooling or cooling/dehumidifying function contained in a common cabinet are commonly used for heating, ventilating and air conditioning on commercial buildings. Typically, such packaged HVAC units are mounted on the rooftop of the building and connected into an air duct system associated with the building for passing air from within the building to be temperature conditioned to the HVAC unit and distributing temperature conditioned air throughout the building. In some applications, packaged HVAC units are ground mounted outside the building, rather than being mounted on the rooftop of the building.
Such year-around packaged HVAC units include an indoor section and an outdoor section housed within a common cabinet, but segregated by partitions and walls into separate compartments. The outdoor section includes one or more condensing units, each having a condenser heat exchanger coil and an associated fan, as well as other components such as a refrigerant compressor. The indoor section includes an air conditioning module, having an evaporator heat exchanger coil and an associated evaporator fan or fans, and an air heating module.
Commonly, the air heating module includes a furnace heat exchanger and an associated combustion system. In one type of air heating module, the furnace heat exchanger comprises a plurality of elongated hairpin-configured tubes defining an interior flow passage through hot flue gas generated by the associated combustion system is passed. The furnace heat exchanger is disposed in an air heating plenum through which indoor air is passed over the external surface of the heat exchanger tubes in heat exchange relationship with the hot flue gas passing through the furnace heat exchanger tubes.
The air heating plenum is typically disposed downstream with respect to air flow of the air discharge outlet of one or more indoor air fans. The heat exchanger tubes extend horizontally across the air heating plenum. The flue gas passing through each of the heat exchange tubes is hottest at the inlet end of each hairpin-configured tube and coolest at the outlet end of each hairpin-configured tube. In some designs, the air passes vertically downwardly over the heat exchange tubes to discharge downwardly through an opening in the floor of the air plenum. In other designs, the air passes vertically downwardly into the air heating plenum, but turns through 90-degrees within the plenum to exit horizontally through an opening in an end side of the air heating plenum. Thus, the air flow passes both across and along the hairpin-configured tubes of the furnace heat exchanger thereby increasing the time for which the air flow passes in heat exchange relationship with the flue gas relative to applications in which the air flows directly vertically downwardly over the heat exchange tubes.
The effectiveness of the heat exchange will be adversely impacted, that is heat exchange from the flue gas to the air will be reduced, in regions that may have relatively low air flow across or along the heat exchange tubes. The reduction of air flow across or along the heat exchange tubes may occur in certain regions due to the turning of the air flow as it passes through the air plenum. The reduced heat transfer may result in high temperature zones, i.e. hot spots, of the surface of the heat exchange tubes, which can also adversely impact reliability of the heat exchanger. Common steps taken in an attempt to provide a more uniform air flow across the heat exchanger and/or increase air flow in regions experiencing weak air flow, such as increasing the fan exhaust and air discharge opening areas, installing large fans, adding flow baffles within the heat exchanger, or adding fins on the heat exchanger tubes, add increased cost to the system and are not always effective in improving heat transfer to the air flow.
In an aspect of the invention, an air treatment module includes an air plenum, a heat exchanger tube and a bypass duct. The air plenum defines an air flow path and has an air inlet for receiving a flow of air to be treated and an air outlet through which a flow of treated air discharges from the air plenum. The heat exchanger tube is disposed in the air flow path within the air plenum for conveying a heat transfer fluid in heat exchange relationship with the flow of air to be treated. The bypass duct has an inlet opening in flow communication with the air plenum in juxtaposition with a selected region of the heat exchanger tube downstream with respect to air flow of the heat exchange tube and an outlet opening in flow communication with a zone of lower air pressure. In an embodiment, the outlet of the bypass duct opens in flow communication with an air supply duct for conveying the flow of air to be treated to the air plenum.
In an aspect of the invention, a packaged air conditioning unit is provided. The packaged air conditioner may be connected in flow communication with an indoor air return duct and with an indoor air supply duct, and an indoor air mover for drawing indoor air to be conditioned through the indoor air supply duct from a conditioned space, an air cooling module, and an air heating module. The air heating module includes a housing defining an air plenum establishing an air flow path and having an air inlet opening in flow communication to a discharge outlet of the indoor air mover and an air outlet opening in flow communication the indoor air supply duct, a heat exchanger module disposed in the air flow path within the air plenum for conveying a heat transfer fluid in heat exchange relationship with the flow of indoor air, and a bypass duct having an inlet opening in flow communication with the air plenum in juxtaposition with a selected region of the heat exchanger module downstream with respect to air flow of the heat exchange module and an outlet opening in flow communication with a zone of lower air pressure. For example, the bypass duct may open in flow communication with a region of the air plenum upstream with respect to air flow of the outlet opening from the air plenum and downstream with respect to air flow of the inlet to the bypass duct or with the indoor air return duct upstream with respect to air flow of an inlet to the indoor air mover.
In an embodiment of the packaged air conditioning unit, the indoor air mover to the air plenum is disposed upstream with respect to the heat exchanger module, the inlet of the bypass duct opens into the air plenum housing in juxtaposition to a selected region of the heat exchanger module, and the air outlet from the air plenum is disposed in an end wall of the air plenum housing. The air cooling module may comprise an air cooling evaporator disposed upstream with respect to indoor air flow of the indoor air mover. The air mover may comprise a centrifugal fan.
In an embodiment, the heat exchanger module includes a plurality of heat exchange tubes through which a flow of hot combustion flue gas is passed in heat exchange relationship with the flow of indoor air passing through the air plenum. The plurality of heat exchanges tubes may comprise a plurality of independent hairpin-shaped heat exchange tubes. The packaged air conditioning unit may include a plurality of flue gas generating burners, with a respective one burner of the plurality of flue gas generating burners operatively associated with a respective one of the plurality of heat exchange tubes.
For a further understanding of the disclosure herein, reference will be made to the following detailed description which is to be read in connection with the accompanying drawing, where:
An exemplary embodiment of the air treatment module of the invention will be described herein for purpose of illustrating with respect to a year-around packaged air conditioning unit, designated generally as 2. It is to be understood, however, that the air treatment module disclosed herein may be used in other applications, including, for example, but not limited to, seasonal heating products such as residential or commercial hot air furnaces.
Referring initially to
The indoor section 20 includes an indoor air mover 22 and generally, the indoor section 20 includes both an air cooling module 30 and an air heating module 40. The air cooling module 30, which comprises an evaporative heat exchanger, is disposed upstream with respect to indoor air flow of the air intake 24 to the indoor air mover 22 and the heating module 40 is disposed downstream with respect to indoor air flow of the air discharge 26 from the indoor air mover 22. The evaporative heat exchanger may comprise a heat exchanger tube coil or tube bank wherein a cooling medium, such as refrigerant or chilled water, may be selectively passed through the tubes in heat exchange relationship with the air passing over the tubes of the tube coil when it is desired to cool the air.
When installed in association with a building for conditioning the air within a temperature controlled space within the building, the packaged air conditioning unit 2 may be connected in flow communication with an indoor air return duct 6 and with an indoor air supply duct 8. In addition if desired, louvers or vents may be provided in the housing that may be selectively opened to allow outdoor air to be drawn into the supply air plenum 45 to mix with the indoor air passing therethrough. The indoor section 20 includes a return air plenum 35 having an inlet in flow communication with the return air duct 6 and a supply air plenum 45 having an outlet in flow communication with the supply air duct 8. In the depicted embodiment, the indoor air mover 22 may be a centrifugal fan having a pair of side air intakes 24. The air intakes 24 of the indoor air mover 22 are in flow communication with the return air plenum 35 and the discharge 26 from the indoor air mover 22 opens in flow communication to the supply air plenum 45 which is located in the heating module 40. In operation, the indoor air mover 22 draws a flow of indoor air from a climate controlled space within the building through the return air duct 6 and the return air plenum 35 and passes that air flow through the supply air plenum 45 and the supply air duct 8 back into the climate controlled space. In traversing the return air plenum 35, the air flows through the cooling module 30. It is to be understood that the return air plenum 35 may have multiple return air inlets opening thereto and a plurality of associated air movers, and the supply air plenum 45 may have multiple supply air outlets.
Referring now also to
In depicted embodiment, the air heating module 40 includes a pair of heat exchanger modules 50, with one module being disposed above the other module. The air passing from the discharge 26 of the indoor air mover 22 flows generally downwardly and across both of the heat exchanger modules 50 before exiting the supply air plenum 45 into the supply air duct 8. It is to be understood, however, that in some installations, the air heating module 40 may include a single heat exchanger module 50 or more than two heat exchanger tube modules.
In the depicted embodiment, each heat exchanger tube module 50 includes a plurality of individual heat exchanger tubes 52 through which a flow of hot combustion flue gas is passed in heat exchange relationship with the flow of indoor air passing through the air plenum. However, it is to be understood that the heat exchanger module 50 may instead comprise a liquid-to-air tubular heat exchanger or an electric resistance heating element or other type of heat exchanger wherein the air is heated by passing the air over a heated surface. Each of the heat exchange tubes 52 may comprise a hairpin shaped heat exchange tube. The plurality of heat exchanges tubes may comprise a plurality of independent hairpin-shaped heat exchange tubes. In the depicted embodiment, a plurality of flue gas generating burners 54, with a respective one burner 54 of the plurality of flue gas generating burners operatively associated with a respective one tube 52 of the plurality of heat exchange tubes. Each burner 54 combusts a fossil fuel, typically natural gas, in air to generate hot combustion products, termed flue gas, which pass into the inlet end of the respective heat exchanger tube 52 associated with the respective burner 54. The hot flue gas passes through the heat exchange tube 52 and discharges from the outlet of the heat exchange tube into an exhaust chamber 57 from which the flue gas is discharged via a fan 56 into and through a flue duct 58 which opens to the atmosphere. In passing through the heat exchange tubes 52, the hot flue gas is cooled as it transfers heat to the indoor air passing through the supply air plenum 45.
The bypass duct 60 is disposed in juxtaposition with the heat exchanger module 50, or the lower heat exchanger module of a plurality of heat exchanger modules, with a specific region of the heat exchanger module 50 wherein it is desired to increase the flow of indoor air over the heat exchanger tubes in that specific region. As the outlet 64 of the bypass duct 60 opens into a zone of lower air pressure, such as the return air plenum 35 in the depicted embodiment, an increased amount of the indoor air flow passing through the supply air plenum 45 will be drawn through the inlet openings 62 of the supply air duct, thereby increasing the flow of air over the heat exchange tubes 52 within this specific region of the heat exchanger module. For example, in the depicted embodiment, as best seen in
The bypass air may be reintroduced into the main air flow passing through the air treatment module at a zone of lower air pressure. In an embodiment, the bypass duct may open in flow communication with a zone of lower air pressure upstream with respect to air flow of the air mover as illustrated schematically in
In an embodiment, the bypass duct may open in flow communication with a zone of lower air pressure further downstream with respect to air flow of the inlet to the bypass duct as illustrated schematically in
Applying the bypass air flow concept disclosed herein in connection with a selected region or regions of a heat exchanger module results in an increased air flow over the heat exchanger tubes or heating elements in the selected region or regions, thereby increasing heat transfer in the selected region or regions, and typically in a more uniform airflow across the heat exchanger module. Thus, heat exchanger module performance is increased and system reliability may be enhanced through the elimination of high temperature zones, i.e. hot spots, on the surface of the heat exchanger tubes or other heating elements. Because the bypass air flow is reintroduced into the main air flow through the air treatment module, the heat energy of the bypass air flow is recovered, thereby maintaining the thermal efficiency of the system. The bypass air concept disclosed herein is also less costly to implement than prior methods of increasing heat exchanger performance such as increasing fan capacity,
The terminology used herein is for the purpose of description, not limitation. Specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as basis for teaching one skilled in the art to employ the present invention. While the present invention has been particularly shown and described with reference to the exemplary embodiments as illustrated in the drawing, it will be recognized by those skilled in the art that various modifications may be made without departing from the spirit and scope of the invention. Those skilled in the art will also recognize the equivalents that may be substituted for elements described with reference to the exemplary embodiments disclosed herein without departing from the scope of the present invention.
Therefore, it is intended that the present disclosure not be limited to the particular embodiment(s) disclosed as, but that the disclosure will include all embodiments falling within the scope of the appended claims.
This application claims priority to U.S. Provisional Patent Application Ser. No. 61/154,974 entitled “Air Treatment Module,” filed on Feb. 24, 2009. The content of this application is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2010/024425 | 2/17/2010 | WO | 00 | 7/25/2011 |
Number | Date | Country | |
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61154974 | Feb 2009 | US |