This invention relates generally to refrigerated beverage and food service merchandisers and, more particularly, to a foul resistant condenser coil therefor.
It is long been the practice to sell soda and other soft drinks by way of vending machines or coin operated refrigerated containers for dispensing single bottles of beverages. These machines are generally stand alone machines that are plugged into standard outlets and include their own individual refrigeration circuit with both evaporator and condenser coils.
This self serve approach has now been expanded to include other types of “plug in” beverage and food merchandisers that are located in convenience stores, delicatessens, supermarkets and other retail establishments.
In such stores, cold beverages, such as soft drinks, beer, wine coolers, etc. are commonly displayed in refrigerated merchandisers for self-service purchase by customers. Conventional merchandisers of this type usually comprise a refrigerated, insulated enclosure defining a refrigerated product display cabinet and having one or more glass doors. The beverage product, typically in cans or bottles, single or in six-packs, is stored on shelves within the refrigerated display cabinet. To purchase a beverage, the customer opens one of the doors and reaches into the refrigerated cabinet to retrieve the desired product from the shelf.
Beverage merchandisers of this type necessarily include a refrigeration system for providing the cooled environment within the refrigerated display cabinet. Such refrigeration systems include an evaporator coil housed within the insulated enclosure defining the refrigerated display cabinet and a condenser coil and compressor housed in a compartment separate from and exteriorly of the insulated enclosure. Cold liquid refrigerant is circulated through the evaporator coil to cool the air within the refrigerated display cabinet. As a result of heat transfer between the air and the refrigerant passing in heat exchange relationship in the evaporator coil, the liquid refrigerant evaporates and leaves the evaporator coil as a vapor. The vapor phase refrigerant is then compressed in the compressor coil to a high pressure, as well as being heated to a higher temperature as a result of the compression process. The hot, high pressure vapor is then circulated through the condenser coil wherein it passes in heat exchange relationship with ambient air drawn or blown across through the condenser coil by a fan disposed in operative association with the condenser coil. As a result, the refrigerant is cooled and condensed back to the liquid phase and then passed through an expansion device which reduces both the pressure and the temperature of the liquid refrigerant before it is circulated back to the evaporator coil.
In conventional practice, the condenser coil comprises a plurality of tubes with fins extending across the flow path of the ambient air stream being drawn or blown through the condenser coil. A fan, disposed in operative association with the condenser coil, passes ambient air from the local environment through the condenser coil. U.S. Pat. No. 3,462,966 discloses a refrigerated glass door merchandiser having a condenser coil with staggered rows of finned tubes and an associated fan disposed upstream of the condenser coil that blows air across the condenser tubes. U.S. Pat. No. 4,977,754 discloses a refrigerated glass door merchandiser having a condenser coil with in-line finned tube rows and an associated fan disposed downstream of the condenser that draws air across the condenser tubes.
One problem that occurs with such self-contained merchandisers is that they are often in area that is heavily trafficked by people that tend to track in debris and dirt from the outside. This, in turn, tends to expose the condenser coil, which is necessarily exposed to the flow of air in the immediate vicinity, to be susceptible to airside fouling. With such fouling, the accumulation of dust, dirt and oils impede refrigeration performance. As the condenser coil fouls, the compressor refrigerant pressure rises, which leads to system inefficiencies and possibly compressor failure. Further, such products are often used in locations where periodic cleaning is not likely to occur.
The usual structure for such a condenser coil is a tube and fin design wherein a plurality of serpentine tubes with refrigerant flowing therein are surrounded by orthogonally extending fins over which the cooling air is made to flow by way of a fan. Generally, the greater the tube and fin densities, the more efficient the performance of the coil in cooling the refrigerant. However, the greater the tube and fin densities, the more susceptible it is to being fouled by the accumulation of dirt and fiber.
This problem has been addressed in one form by the elimination of fins and relying on conventional tubes as set forth in U.S. patent application Ser. No. 10/421,575, assigned to the assignee of the present application and incorporated herein by reference. A further approach has been to selectively stagger the successive rows of tubes in relation to the direction of airflow as described in U.S. Patent Application No. (PCT/US03/12468), Continuation In Part Application of Provisional Application Ser. No. 60/376,486 filed on Apr. 30, 2002, assigned to the assignee of the present application and incorporated herein by reference.
Briefly, in accordance with one aspect of the invention, the tube and fin condenser coil is replaced by a condenser coil having a greater number of microchannel tubes than the previous number of round tubes but, with the clearances from tube to tube being relatively large such that air side fouling is less likely to occur.
In accordance with another aspect of the invention, such a microchannel refrigerant tube is able to operate with lower amounts of refrigerant when compared to traditional round tube condensers, such that the additional tube surface that is required to make up for using less fins does not significantly increase refrigerant charge requirements.
By yet another aspect of the invention, the fin density of a microtubes condenser coil is reduced to a level which will substantially eliminate the bridging of fibers between fins such that the occurrence of fouling is substantially reduced or eliminated. If the fin density is reduced to the extent that there is little or no support between the microchannel tubes, then provision is made to include a support structure, in spaced relationship between the adjacent tubes to prevent movement and/or damage thereto.
In accordance with another aspect of the invention, in order to provide sufficient heat exchange surface area with the reduced tube and fin densities, multiple rows of microchannel tubes may be provided with each row having its own header. In order to obtain better heat exchange efficiencies without an attendant increase in fouling, the tubes rows are staggered such that the tubes from the downstream row are located so as to be substantially between the tubes of the upstream row.
In the drawings as hereinafter described, a preferred embodiment is depicted; however various other modifications and alternate constructions can be made thereto without departing from the true spirit and scope of the invention.
Referring now to
The refrigerated display cabinet 25 is defined by an insulated rear wall 22 of the enclosure 20, a pair of insulated side walls 24 of the enclosure 20, an insulated top wall 26 of the enclosure 20, an insulated bottom wall 28 of the enclosure 20 and an insulated front wall 34 of the enclosure 20. Heat insulation 36 (shown by the looping line) is provided in the walls defining the refrigerated display cabinet 25. Beverage product 100, such as for example individual cans or bottles or six packs thereof, are displayed on shelves 70 mounted in a conventional manner within the refrigerated display cabinet 25, such as for example in accord with the next-to-purchase manner shown in U.S. Pat. No. 4,977,754, the entire disclosure of which is hereby incorporated by reference. The insulated enclosure 20 has an access opening 35 in the front wall 34 that opens to the refrigerated display cabinet 25. If desired, a door 32, as shown in the illustrated embodiment, or more than one door, may be provided to cover the access opening 35. It is to be understood however that the present invention is also applicable to beverage merchandisers having an open access without a door. To access the beverage product for purchase, a customer need only open the door 32 and reach into the refrigerated display cabinet 25 to select the desired beverage.
An evaporator coil 80 is provided within the refrigerated display cabinet 25, for example near the top wall 26. An evaporator fan and motor 82, as illustrated in
Refrigerant is circulated in a conventional manner between the evaporator 80 and the condenser 50 by means of the compressor 40 through refrigeration lines forming a refrigeration circuit (not shown) interconnecting the compressor 40, the condenser coil 50 and the evaporator coil 80 in refrigerant flow communication. As noted before, cold liquid refrigerant is circulated through the evaporator coil 80 to cool the air within the refrigerated display cabinet 25. As a result of heat transfer between the air and the refrigerant passing in heat exchange relationship in the evaporator coil 80, the liquid refrigerant evaporates and leaves the evaporator as a vapor. The vapor phase refrigerant is then compressed in the compressor 40 to a high pressure, as well as being heated to a higher temperature as a result of the compression process. The hot, high pressure vapor is then circulated through the condenser coil 50 wherein it passes in heat exchange relationship with ambient air drawn or blown across through the condenser coil 50 by the condenser fan 60.
Referring now to
In order to increase the heat exchange capacity of the coil 110, a plurality of fins 118 may be placed between adjacent microchannel tube pairs. These fins are preferably aligned orthogonally to the microchannel tube 111 and parallel with the direction of airflow through the microchannel condenser coil 110. The lateral spacing between adjacent fins is the dimension “W”.
One advantage offered by the microchannel tube 111 over the conventional round tubes in a condenser coil is that of obtaining more surface area per unit volume. That is, generally, a plurality of small tubes will provide more external surface area than a single large tube. This can be understood by comparison of a single ⅜ inch (8 millimeter) tube with a 5 millimeter tube. The external surface area-to-volume ratio of the 5 millimeter tube is 0.4, which is substantially greater than that for a 8 millimeter tube, which is 0.25.
One disadvantage to the use of a greater number of smaller tubes rather than fewer larger tubes is that it is generally more expensive to implement. However, the techniques that have been developed for manufacturing microchannel tubes with a plurality of channels has evolved to the extent that they are now economical as compared with the manufacturer and implementation of round tubes in a heat exchanger coil.
Another advantage of the microchannel tubes is that they are more streamlined so as to result in a lower pressure drop and lower noise level. That is, there is much less resistance to the air flowing over the relatively narrow microchannels than there is to the air flowing over relatively large round tubes.
Considering now the problem of air side fouling which results from the accumulation of dust, dirt and oils between adjacent tubes and/or adjacent fins of a condenser coil, the applicants have recognized that such a fouling starts with the bridging of an elongate fiber between adjacent tubes or between adjacent fins. That is, most small particles will pass through the passages of a coil unless a passage is somewhat blocked by the lodging of a fiber therein. When a bridging fiber is lodged between adjacent fins or adjacent tubes, then small particles tend to collect on that fiber with the build up eventually resulting in a fouling of the passageway. In order to prevent or reduce the occurrence of fouling, it is therefore necessary to understand the manner in which the bridging effect is influenced by the structural configuration of the coil. With that in mind, the applicants have conducted experimental tests to determine how the variation in the spacing of the tubes and the spacing of the fins can affect the tendency of fouling to occur. The results are shown in
A field analysis was conducted to determine the types of material that were most likely to cause fouling in the condenser coil, and it was found that cotton fibers were the predominant cause of the foulings and that fouling is generally started by the bridging of an elongate fiber between adjacent fin or between adjacent tubes. Accordingly, experimental analysis was conducted to determine the fouling tendencies of a condenser coil in an environment of cotton fibers as the spacing of the fins is selectively varied. A number of heat exchangers, each being of a standard design with round tubes and plate fins of a specific spacing were exposed to an environment of natural cotton fibers and tested for their relative tendencies to foul. A heat exchanger having seven fins per inch, or a fin spacing of 0.14 inches between adjacent fins, was arbitrarily assigned a fouling goodness parameter (FGP) of 1. This is shown at point A on the graph of
As the fin spacing is increased, the associated increase in FGP is substantially linear to point B where the spacing is 0.40 inches and the FGP is 1.5. At point C, the relationship is still close to linear wherein the spacing is point 0.50 inches with an associated FGP of 2, which means that the heat exchanger is twice as “good” as compared to the heat exchanger at Point A in regards to fouling.
As the front spacing is increased beyond the 0.50 spacing, it will be seen that the FGP begins to increase substantially beyond the linear relationship, and at a spacing of 0.75 inches as shown at point B, it approaches an asymptotic relationship. Thus, it can be concluded that ideally, the fin spacing should be maintained at 0.75 inches or greater if the maximum FGP is desired. At those higher spacing parameters, however, it will be recognized that the exposed surface area is reduced and therefore the heat exchange capability is also reduced. Accordingly, it may be desirable to maintain sufficient fin spacing so as to obtain a sufficiently high FGP while, at the same time, maintaining sufficient density to provide a desired amount of surface area. For example, at point E, a sufficiently high FGP of 6 is obtained with a fin spacing of 0.70 inches between adjacent fins.
Although the experiential data as discussed hereinabove relates to fin spacing on round tube heat exchangers, the applicants believe that the same performance characteristics will be true of fin spacing with a microchannel tubing heat exchanger as shown in
In the
With the complete elimination of fins as shown in
With the elimination of the fins as discussed hereinabove, another effect that must be considered is that with the resulting reduced heat exchange surface area, and with an associated increase in the density of the microchannel tubes, will there be still sufficient heat exchange surface area to obtain the necessary performance? Presuming that, because of the performance characteristics discussed hereinabove, the spacing L between adjacent microchannels tubes is maintained at around 0.75 inches, the resulting number of microchannel tubes may not be sufficient to bring about the desired amount of heat exchange. One approach for overcoming this problem is shown in
It will, of course, be understood that multiple rows of tubes can be placed in such a staggered relationship such that the third row would most likely be aligned with the first row and a fourth row would be most aligned with a second row and so forth. Again, the fouling goodness parameter would not significantly change since the controlling parameter would still be the distance L between tubes in any single row.
While the present invention has been particular shown and described with reference to preferred and alternate embodiments as illustrated in the drawings, it will be understood by one skilled in the art that various changes in detail may be effective therein without departing from the true spirit and scope of the invention as defined by the claims.
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Number | Date | Country | |
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20050241327 A1 | Nov 2005 | US |