The present application relates generally to air conditioning and refrigeration systems and more particularly relates to a microchannel coil manifold system that permits the connection of multiple microchannel coils.
Modern air conditioning and refrigeration systems provide cooling, ventilation, and humidity control for all or part of an enclosure such as a building, a cooler, and the like. Generally described, the refrigeration cycle includes four basic stages to provide cooling. First, a vapor refrigerant is compressed within a compressor at high pressure and heated to a high temperature. Second, the compressed vapor is cooled within a condenser by heat exchange with ambient air drawn or blown across a condenser coil by a fan and the like. Third, the liquid refrigerant is passed through an expansion device that reduces both the pressure and the temperature of the liquid refrigerant. The liquid refrigerant is then pumped within the enclosure to an evaporator. The liquid refrigerant absorbs heat from the surroundings in an evaporator coil as the liquid refrigerant evaporates to a vapor. Finally, the vapor is returned to the compressor and the cycle repeats. Various alternatives on this basic refrigeration cycle are known and also may be used herein.
Traditionally, the heat exchangers used within the condenser and the evaporator have been common copper tube and fin designs. These heat exchanger designs often were simply increased in size as cooling demands increased. Changes in the nature of the refrigerants permitted to be used, however, have resulted in refrigerants with distinct and sometimes insufficient heat transfer characteristics. As a result, further increases in the size and weight of traditional heat exchangers also have been limited within reasonable cost ranges.
As opposed to copper tube and fin designs, recent heat exchanger designs have focused on the use of aluminum microchannel coils. Microchannel coils generally include multiple flat tubes with small channels therein for the flow of refrigerant. Heat transfer is then maximized by the insertion of angled and/or louvered fins in between the flat tubes. The flat tubes are then joined with a number of manifolds. Compared to known copper tube and fin designs, the air passing over the microchannel coil designs has a longer dwell time so as to increase the efficiency and the rate of heat transfer. The increase in heat exchanger effectiveness also allows the microchannel heat exchangers to be smaller while having the same or improved performance and the same volume as a conventional heat exchanger. Microchannel coils thus provide improved heat transfer properties with a smaller size and weight, provide improved durability and serviceability, improved corrosion protection, and also may reduce the required refrigerant charge by up to about fifty percent (50%).
Microchannel coils generally are connected to the refrigeration system as a whole via an assembly or a refrigerant inlet manifold on one side of the coil and an assembly or a refrigerant outlet manifold on the other side. The microchannel coils may be connected in series, in parallel, or combinations thereof. The refrigerant inlet and outlet manifolds, however, should be able to accommodate these various configurations while permitting ease of installation, access, repair, removal, and/or reconfiguration and the like.
There is a desire therefore for an improved microchannel coil manifold system. Such an improved system should accommodate as many microchannel coils in as many different configurations as may be desired. Preferably, the manifold system may allow the easy reconfiguration of the microchannel coils in the field as well as in the factory.
The present application thus provides a microchannel coil manifold system. The microchannel coil manifold system may include a number of assembly inlet manifold sections that terminate in a first stub tube, a number of assembly outlet manifold sections that terminate in a second stub tube, and one or more microchannel coils. Each pair of assembly inlet and outlet manifold sections may be in communication with the one or more microchannel coils.
The microchannel coil manifold system further may include a coil manifold in communication with each microchannel coil and one of the assembly inlet manifold sections and one of the assembly outlet manifold sections. The coil manifold may include a coil manifold inlet brazed to an assembly inlet manifold section and a coil manifold outlet brazed to an assembly outlet manifold section. Each of the assembly inlet manifold sections and each of the assembly outlet manifold sections may be in communication with a pair of microchannel coils. A number of manifold coils may be used. Each stub tube may include a plug.
The microchannel coil manifold system further may include a frame with a slot. The microchannel coil may be positioned within the slot and the microchannel coil manifold system may be attached to the frame. The microchannel coil manifold system further may include a coil manifold in communication with each microchannel coil. The manifold coil may be attached to the frame via a coil attachment. The microchannel coil may slide within the slot. The microchannel coil may include a number of flat microchannel tubes with a number of fins extending therefrom. The microchannel coil may include an extruded aluminum.
The present application further may provide a method of installing a microchannel coil within a microchannel coil condenser assembly. The method may include the steps of attaching a first assembly inlet manifold section and a first assembly outlet manifold section to the microchannel coil, removing a first stub tube from the first assembly inlet manifold section and a second stub tube from the first assembly outlet manifold section, and attaching the first assembly inlet manifold section and the first assembly outlet section to a second assembly inlet manifold section and a second assembly outlet manifold section.
The method further may include the step of sliding the microchannel coil within a slot of a condenser assembly frame, attaching a coil manifold of the microchannel coil to a first end of the frame via a coil attachment, brazing an attachment between the coil manifold of the microchannel coil and the first assembly inlet manifold section and the first assembly outlet section, and installing a number of microchannel coils within the microchannel coil condenser assembly.
The present application further may provide for a microchannel coil condenser assembly. The microchannel coil condenser assembly may include a frame, a number of microchannel coils positioned within the frame, and a microchannel coil manifold system attached to the frame. The microchannel coil manifold system may include a number of assembly inlet manifold sections and a number of assembly outlet manifold sections. Each pair of assembly inlet and outlet manifold sections may be in communication with one or more microchannel coils.
The assembly inlet manifold sections may terminate in a first stub tube and the assembly outlet manifold sections may terminate in a second stub tube. The microchannel coil condenser. assembly further may include a coil manifold in communication with each microchannel coil and one of the assembly inlet manifold sections and one of the assembly outlet sections. The coil manifold may include a coil manifold inlet brazed to one of the assembly inlet manifold sections and a coil manifold outlet brazed to one of the assembly manifold outlet sections.
These and other features and improvements of the present application will become apparent to one of ordinary skill in the art upon review of the following detailed description when taken in conjunction with the several drawings and the appended claims.
Referring now to the drawings, in which like numerals refer to like elements throughout the several views,
The microchannel tubes 20 generally extend from one or more manifolds 30. The manifolds 30 may be in communication with the overall air-conditioning system as is described above. Each of the microchannel tubes 20 may have a number of fins 40 positioned thereon. The fins 40 may be straight or angled. The combination of a number of small tubes 20 with the associated high density fins 40 thus provides more surface area per unit volume as compared to known copper fin and tube designs for improved heat transfer. The fins 40 also may be louvered over the microchannel tubes 20 for an even further increase in surface area. The overall microchannel coil 10 generally is made out of extruded aluminum and the like.
Examples of known microchannel coils 10 include those offered by Hussmann Corporation of Bridgeton, Mo.; Modine Manufacturing Company of Racine, Wis.; Carrier Commercial Refrigeration, Inc. of Charlotte, N.C.; Delphi of Troy, Mich.; Danfoss of Denmark; and from other sources. The microchannel coils 10 generally may be provided in standard or predetermined shapes and sizes. Any number of microchannel coils 10 may be used together, either in parallel, series, or combinations thereof. Various types of refrigerants may be used herein.
The microchannel coils 110 may be supported by a frame 140. The frame 140 may have any desired shape, size, or configuration. The frame 140 also may be modular as is described in more detail below. Operation of the microchannel coils 110 and the microchannel condenser assembly 100 as a whole may be controlled by a controller 150. The controller 150 may or may not be programmable. A number of fans 160 may be positioned about each microchannel coil 110 and the frame 140. The fans 160 may direct a flow of air across the microchannel coils 110. Any number of fans 160 may be used herein. Other types of air movement devices also may be used herein. Each fan 160 may be driven by an electrical motor 170. The electrical motor 170 may operate via either an AC or a DC power source. The electrical motors 170 may be in communication with the controller 150 or otherwise.
The microchannel condenser assembly 100 likewise may include an assembly inlet manifold 230 with an assembly inlet connector 235 and an assembly outlet manifold 240 with an assembly outlet connector 245. The assembly inlet manifold 230 is in communication with the coil manifold 200 via the coil manifold inlet 210 and the assembly inlet connector 235 while the assembly outlet manifold 240 is in communication with the coil manifold 200 via the coil outlet manifold 220 and the assembly outlet connector 245. Other connections may be used herein. The assembly manifolds 230, 240 may be supported by one or more brackets 250 or otherwise. The assembly manifolds 230, 240 may be in communication with other elements of the overall refrigeration system as was described above.
The coil manifold inlets and outlets 210, 220 and/or the assembly connectors 235, 245 may include stainless steel with copper plating at one end. The coil inlets and outlets 210, 220 and the assembly connectors 235, 245 may be connected via a brazing or welding operation and the like. Because the copper and the aluminum do not come in contact with one another, there is no chance for galvanic corrosion and the like. Other types of fluid-tight connections and/or quick release couplings also may be used herein.
In use, one end of each assembly manifold 230, 240 of the microchannel coil manifold system 300 will be connected to the refrigeration system as a whole and the other end will terminate at a stub tube 320, 330, 350, 360. Other configurations may be used herein.
As is shown in
Not only does the use of the microchannel coil manifold system 300 allow for the connection of as many microchannel coils 110 as may be desired, but the combination of the microchannel manifold system 300 and the ability to slide the microchannel coils 110 into the frame 140 via the slot 180 further provides ease of access for installation, removal, and repair. Moreover, the microchannel condenser assembly 100 as a whole may be more compact given the use of manifolding only on one side of the microchannel coils 110. Further, although the microchannel coils 110 are positioned on one side of the microchannel coil manifold system 300, the microchannel coils 110 themselves may be positioned on both sides of the microchannel coil system 300 if desired, providing an even more compact system as a whole.
It should be apparent that the foregoing relates only to certain embodiments of the present application and that numerous changes and modifications may be made herein by one of ordinary skill in the art without departing from the general spirit and scope of the invention as defined by the following claims and the equivalents thereof.
The present application claims priority to U.S. Provisional Application Ser. No. 61/286,851 filed on Dec. 16, 2009. This application is incorporated herein by reference in full.
Number | Name | Date | Kind |
---|---|---|---|
1899629 | Morse | Feb 1933 | A |
2191146 | Mitchell | Feb 1940 | A |
3447598 | Kaess, Jr. | Jun 1969 | A |
4292958 | Lee | Oct 1981 | A |
20050161202 | Merkys et al. | Jul 2005 | A1 |
20090084131 | Reifel et al. | Apr 2009 | A1 |
20100254081 | Koenig et al. | Oct 2010 | A1 |
20100294460 | Duchet-Annez et al. | Nov 2010 | A1 |
20110056668 | Taras et al. | Mar 2011 | A1 |
Number | Date | Country |
---|---|---|
1 557 622 | Jul 2005 | EP |
2 923 594 | May 2009 | FR |
2001124490 | May 2001 | JP |
2009007168 | Jan 2009 | WO |
2009134760 | May 2009 | WO |
Number | Date | Country | |
---|---|---|---|
20110139423 A1 | Jun 2011 | US |
Number | Date | Country | |
---|---|---|---|
61286851 | Dec 2009 | US |