The present invention relates to heat exchangers, and more particularly to evaporative heat exchangers having a number of stacked plates at least partially defining two separate and substantially adjacent fluid flow paths
Attempts to use stacked plate style heat exchangers in applications where one of the fluids experiences a change of phase from a liquid to a vapor have been problematic. In such applications the fluid that is evaporating exists, over at least a portion of its flow path through the heat exchanger, as a two-phase fluid having both vapor and liquid fractions. The vapor fraction tends to separate from the liquid fraction due to the substantial differences in densities between the phases, making it difficult to achieve a uniform distribution of the fluid over the multiple parallel passages. This maldistribution effect can be especially pronounced when the flow path through the heat exchanger is circuitous, requiring the fluid to make multiple changes in flow direction. When the distribution is not uniform, the performance of the heat exchanger tends to suffer. Separation of the phases of the evaporating fluid can result in liquid flooding of certain regions, with slugs of the liquid forced through the heat exchanger at a non-constant rate. For this reason, evaporative heat exchangers have often been of a construction wherein the evaporating fluid does not require redistribution along its flow path.
In certain evaporative heat exchanger applications, it may be especially beneficial to arrange the flow passages so that the hot fluid and the evaporating fluid pass through the heat exchanger in a counter-flow or in a concurrent flow orientation to one another. A counter-flow orientation may be desirable when the hot fluid is to be cooled to as low a temperature as possible, or when the evaporating fluid is to be superheated to as high a temperature as possible. A concurrent flow orientation may be desirable when the hot fluid and the evaporating fluid are to exit the heat exchanger at one common temperature. Examples of such applications include, but are not limited to, air-conditioning and refrigeration chillers, Rankine cycle evaporators, and water and/or fuel vaporizers for fuel processing and fuel cell applications. A disadvantage of using a tube and fin evaporator construction in such applications is the difficulties that it poses in arranging the hot and cold fluid flows in a circuiting arrangement other than cross-flow.
According to one embodiment of the invention, a stacked plate evaporative heat exchanger for the transfer of heat from a first fluid to a second fluid to vaporize the second fluid includes a plurality of separate parallel flow passages to direct the first fluid through the heat exchanger, and a plurality of parallel arranged fluid flow plates for the second fluid interleaved with the parallel flow passages for the first fluid. The fluid flow plates have a first and second set of flow channels extending from a first end of the fluid flow plate to a second end of the fluid flow plate to define a first flow pass for the second fluid. The fluid flow plates further have a third set of flow channels to define a second flow pass for the second fluid parallel to the first pass. A first collection manifold is located at the second end to receive at least a portion of the second fluid flow from the first pass and transfer it to the second pass. A second collection manifold is located between the first and second ends and intersects the second set of flow channels and at least some of the third set of flow channels, but not the first set of flow channels, to receive at least a portion of the second fluid from the first pass and transfer it to the second pass.
In some embodiments, the fluid flow plate is constructed by corrugating a thin sheet of material. The second collection manifold may be defined by slots passing through the corrugations of the fluid flow plate.
In some embodiments, the plurality of separate parallel flow passages are arranged to direct the first fluid through the heat exchanger in a direction approximately perpendicular to the first and second flow passes for the second fluid. In some embodiments the plurality of separate parallel flow passages are arranged to direct the first fluid in two or more sequential passes through the heat exchanger.
In some embodiments, the pressure resistance and heat transfer performance of the heat exchanger may be improved by having a uniformly narrow channel width for the flow channels of the fluid flow plates. In some embodiments the second collection manifold can consist of one or more slots extending through the fluid flow plate. In some embodiments the one or more slots can each have a slot width that is approximately equal to the channel width.
In some embodiments, the fluid flow plates include a fourth set of flow channels to additionally define the second flow pass, and a fifth set of flow channels to define a third pass downstream of the first and second passes A third collection manifold is located at the first end of the fluid flow plate to receive at least a portion of the second fluid from the second pass and transfer it to the third pass. A fourth collection manifold is located between the first and second ends and intersects the fourth set of flow channels and at least some of the fifth set of flow channels, but not the third set of flow channels, to receive at least a portion of the second fluid from the second pass and transfer it to the third pass. In some such embodiments the fluid flow plates include additional flow passes downstream of the third pass.
In some embodiments, the plurality of separate parallel flow passages are at least partially defined by a plurality of stamped plates. Each of the stamped plates can include a recessed area to receive one of the fluid flow plates.
In some embodiments, the present invention provides an evaporative heat exchanger operable to at least partially vaporize fluid. The heat exchanger can include a number of parallel flow passages extending through the heat exchanger, together the flow passages define a first fluid flow path, and a number of substantially parallel stacked plates interleaved with the parallel flow passages. Each plate can have a first end and a second end spaced apart from the first end and at least partially define a first set of flow channels extending from the first end to the second end and a second set of flow channels extending from the first end to the second end parallel to the first set of flow channels. The first and second sets of flow channels together can comprise a first flow pass of a second fluid flow path. Each plate can also include a third set of flow channels extending from the first end to the second end and comprising a second flow pass of the second fluid flow path substantially parallel to the first flow pass of the second fluid flow path, a first collection manifold adjacent to the second end and connecting the first and second passes, and a second collection manifold between the first end and the second end, the second collection manifold intersecting the second set of flow channels and at least some of the third set of flow channels. The can plate separate the first set of flow channels from the second collection manifold.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
a-c are diagrammatic illustrations of possible fluid flow paths through a heat exchanger according to embodiments of the present invention.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
In some such applications, the heat that is so transferred may be sufficient to fully vaporize the second fluid flow 3, whereas in other applications the heat may be sufficient to vaporize only a portion of the first fluid flow 3. Furthermore, in some applications, the heat that is transferred from the first fluid flow 2 to the second fluid flow 3 may exceed the amount of latent heat required to fully vaporize the second fluid flow 3, so that the second fluid flow 3 exits the heat exchanger 1 as a superheated vapor.
The heat exchanger 1 shown in
As best seen in
In the illustrated embodiment of
Features of the fluid flow plates 4 and stamped shells 5 will now be further described with reference to
In the depicted embodiment, the fluid flow plate 4 is a corrugated thin metal sheet. Each of the eight fluid passes 14-21 comprise a plurality of flow channels 13 defined by corrugations of the fluid flow plate 4. The crests of the corrugations may be rounded as shown, or they may be some other shape such as, for example, flat or peaked. During fabrication of the heat exchanger 1, the crests of the corrugations can be bonded to the adjacent surfaces of the stamped plates 5 and 7 in order to define the flow channels 13. Alternatively or in addition, the crest of the corrugations can engage correspondingly shaped recesses or protrusions on the adjacent surfaces of the stamped plates 5 and 7 to seal the flow channels 13. Adjacent ones of the channels 13 are generally non-communicative with each other, except in the manifold regions to be described later on.
The inlet port 11 is directly connected to the channels 13 comprising the fluid pass 14 at the end 40, so that a portion of the second fluid flow 3 can enter the space between the stamped shell 5 and an adjacent stamped shell 7 or top plate 8 and can flow through the fluid pass 14. After traveling through the pass 14, the fluid can transfer to the pass 15 by way of the collection manifold 22 located at the end 41, and additionally by way of the collection manifold 23 located between the ends 40 and 41. It should be observed that the collection manifold 23 does not intersect some of the channels 13 comprising the pass 14, so that any fluid traveling through these channels is forced to travel the entire length of the channels and through the manifold 20. Additionally, the collection manifold 23 as shown does not intersect some of the channels 13 comprising the pass 15, and any fluid traveling through those channels must come from the collection manifold 22.
After flowing through the pass 15, the fluid can transfer to the pass 16 by way of the collection manifold 24 located at the end 40, and additionally by way of the collection manifold 25 located between the ends 40 and 41. Again, the collection manifold 25 as shown does not intersect some of the channels comprising the pass 15 and does not intersect some of the channels comprising the pass 16.
As can be inferred from inspection of
In the illustrated embodiment, the collection manifold 25 consists of three approximately parallel slots 25a, 25b and 25c extending through the fluid flow plate 4. In different embodiments, the collection manifold can consist of more or fewer slots, so that the flow area in the collection manifold can be adjusted. Some advantages can be found, however, in having multiple slots to comprise the manifold rather than one larger slot. A smaller slot width will result in a smaller hydraulic diameter than a larger slot width, and this will reduce the negative impact on heat transfer performance caused by removal of the corrugations in the slot area. Additionally, a smaller slot width will provide greater structural support to resist deformation of the shells 5, 7 when the second fluid flow 3 is at a substantially higher pressure than the first fluid flow 2, as is frequently the case in evaporative systems. It should be understood by those having skill in the art that the proper slot width and number of slots may vary depending on the application.
In a manner similar to that described above, the fluid flows through the pass 16, then by way of the manifolds 26 and 27 through the pass 17, then by way of the manifolds 28 and 29 through the pass 18, then by way of the manifolds 30 and 31 through the pass 19, then by way of the manifolds 32 and 33 through the pass 20, then by way of the manifolds 34 and 35 through the pass 21, after which the fluid exits the heat exchanger 1 through outlet port 12.
The manifolds 24, 28 and 32 at the end 40 are separated from each other by protrusions 36 that extend from the wall of the recess in the plate 5 that houses the fluid flow plate 4. These protrusions extend approximately to the end 40 of the fluid flow plate 4 in order to provide a highly tortuous flow path for the fluid to flow directly from one of the manifolds 24, 28 and 32 to an adjacent one of the manifolds 24, 28 and 32 without passing through two of the flow passes in the plate 4. Similar protrusions 36 prevent or substantially inhibit bypass flow from the inlet port 11 to the manifold 24, and between the manifolds 22, 26, 30 and 34 located at the end 41.
In some embodiments, the bypass prevention may be improved by providing notches in the fluid flow plate 4 to receive portions of the protrusions 36 therein in order to provide an even more tortuous flow path. In some embodiments the protrusions 36 may be joined to one or more of the corrugations comprising the channels 13 of the fluid flow plate 4 to completely block such bypass flow. In some such embodiments, the joining can be accomplished by creating a brazed joint. In such embodiments, the protrusions 36 can block off one end of one or more of the channels 13 located between adjacent passes in the fluid flow plate 4 in order to direct substantially all of the fluid flow through the passes. In some embodiments, the flow blocking protrusions 36 may alternatively extend from the fluid flow plate 4 to engage the wall of the plate 5.
The flow manifolds 26, 28, 30, 32 and 34 also can be seen to include a flow area constriction region defined by features 37 that extend partially into the manifolds from the wall of the plate 5, the purpose of which will be described later.
Turning now to
The portion of the fluid flow path shown in
The passes A and B extend from an end 38 of the fluid flow plate 4 to an end 39 of the fluid flow plate 4. Additional (not shown) flow passes may be located upstream and/or downstream of the passes A and B. The ends 38 and 39 can correspond to the ends 40 and 41, respectively, in the embodiment of
The passes A and B are fluidly connected to one another by way of manifolds C and D, where manifold C is located at the end 39 and manifold D is located between the ends 38 and 39. The pass A comprises a set of channels A1 that directly connect to the manifold C, and another set of channels A2 that directly connect to both manifolds C and D.
The channels comprising the pass B are each connected to at least one of the manifolds C and D. As shown in
When a heat exchanger including a flow plate 4 according to the embodiment of
As a result of having the set of channels A1 only connect to the manifold C, the entirety of the fluid traveling in the set of channels A1 will be directed into manifold C. This can prevent the accumulation of liquid in manifold C, as any vapor present in the set of channels A1 will “push” the liquid through into the pass B. In the embodiment of
In the alternative embodiment of
In the embodiment of
The flow 113 is distributed into the first pass by way of the manifolds 115 and 116. From the first pass, the flow 113 is distributed into the second pass by way of the manifolds 117 and 118, which serve the purpose of the manifolds C and D of
Some of the flow channels 113 may be blocked by a ring 115 surrounding a port 110 through which the flow 102 is collected from the plurality of flow layers 107 interleaved with the flow layers 105. A portion 118a of the manifold 118 is located so as to intersect those channels and allow for the fluid passing through those channels to bypass around the ring 115.
The flow 103 is directed into the second pass from the manifolds 117 and 118, and is directed from the second pass into the third pass through the manifolds 119 and 120. The fluid is directed from the third pass to the fourth pass through the manifolds 121 and 122, and from the fourth pass to the fifth pass through the manifolds 123 and 124. The manifolds 125 and 126 redirect the fluid from the fifth pass into the port 112, through which the fluid 103 is removed from the heat exchanger 101.
Similar to the first pass, some of the channels in the fifth flow pass are blocked by a ring 114 surrounding the inlet distribution port 106 for the fluid 102. A portion 124c of the manifold 124 is located such that a portion of the fluid 103 can be directed into those channels despite the flow blockage due to the ring 114.
The manifolds 117, 119, 121 and 123 have local constrictions caused by protrusions or extensions 128 protruding from the fluid flow plate 104 into the manifold areas. These extensions 128 serve a similar function as the previously described protrusions 37.
The manifolds 117, 121 and 125 are separated from one another by protrusions 136 extending from the wall of the plate 105, said protrusions being received into notches 127 in the fluid flow plate 104. The manifolds 115, 119 and 123 are similarly separated from one another.
Various alternatives to the certain features and elements of the present invention are described with reference to specific embodiments of the present invention. With the exception of features, elements, and manners of operation that are mutually exclusive of or are inconsistent with each embodiment described above, it should be noted that the alternative features, elements, and manners of operation described with reference to one particular embodiment are applicable to the other embodiments.
The embodiments described above and illustrated in the figures are presented by way of example only and are not intended as a limitation upon the concepts and principles of the present invention. As such, it will be appreciated by one having ordinary skill in the art that various changes in the elements and their configuration and arrangement are possible without departing from the spirit and scope of the present invention.
The present application claims priority to U.S. Provisional Patent Application Ser. No. 61/102,458, filed Oct. 3, 2008, the entire contents of which is hereby incorporated by reference.
Number | Date | Country | |
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61102458 | Oct 2008 | US |