US20260043614A1
HEAT EXCHANGER
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
MAHLE International GmbH
Inventors
Masahiro Ariyama, Junko Tanaka
Abstract
A heat exchanger may include a laminated body, a bottomed cylindrical case housing the laminated body, and a base plate. The laminated body may include a plurality of plates, a first fluid flow path, and a second fluid flow path. The flow paths may be formed via lamination of the plates. The case may include an opening disposed on a side of the laminated body, a side wall part covering a side surface of the laminated body, a top face part disposed on a side of the case facing the laminated body, a sloped surface part extending at an inclination relative to the side wall part, and an inlet and/or an outlet for passage of a first fluid. The sloped surface part may be contiguous to the side wall part and to the top face part. The inlet and/or the outlet may be disposed on the sloped surface part.
Figures
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001]This application claims priority to Japanese Patent Application No. JP 2024-129721 filed on Aug. 6, 2024, the contents of which is hereby incorporated by reference in its entirety.
TECHNICAL FIELD
[0002]The present invention relates to a heat exchanger.
BACKGROUND
[0003]Heat exchangers that perform heat exchange between a plurality of fluids may use as a long-life coolant (LLC) or the like as the water-cooled oil cooler to cool the lubricant oil of an internal combustion engine. Among heat exchangers, it is known that there are some heat exchangers that have a casing and a core contained within the space of this casing, with a fluid inlet and a fluid outlet on a side of the peripheral wall that may be provided on the side surface of the casing (see, for example, Patent literature 1).
[0004](PATENT LITERATURE 1) Japanese Unexamined Patent Application Publication 2011-127819
[0005]In the conventional heat exchanger such as that presented in Patent literature 1, the upper limit of the diameter of the fluid inlet and fluid outlet is restricted by the height of the peripheral wall. For this reason, if the diameter of the fluid inlet and fluid outlet is greater than the height of the peripheral wall in the heat exchanger, the fluid inlet and fluid outlet were provided on the wall surface in the vertical direction of the casing.
[0006]However, due to factors such as the electrification of vehicles, there is increasing demand for miniaturization of the dimensions in the vertical (height) direction and for reduction of the pressure drop in heat exchangers. For this reason, it is necessary to have a configuration in which the size of the heat exchanger in the vertical (height) direction is reduced as well as in which the diameter of the fluid inlet and fluid outlet is increased.
[0007]Therefore, the present invention was created in consideration of the above-mentioned issues, and is intended to provide a heat exchanger that can achieve both miniaturization and an increase in the diameter of the fluid path.
SUMMARY
[0008]In order to solve the above-noted problem, the heat exchanger according to the present invention is provided with a laminated body in which a flow path for a first fluid and a flow path for a second fluid may be mutually formed in the lamination direction through the lamination of a plurality of plates, a bottomed cylindrical case to not only house said laminated body but that also has an opening on one side of said laminated body, and a base plate that may be provided on the side of the opening of said case, wherein said case has a side wall part that covers the side surface of said laminated body, a top face part that may be provided on the side of said case that faces said laminated body, a sloped surface part that is contiguous to said side wall part and said top face part and that may be provided at an inclination in relation to said side wall part, and either one of an inlet or an outlet, or both of these, that may be provided on said sloped surface part for the passage of a first fluid.
[0009]In the heat exchanger pertaining to one aspect of the present invention, the diameter of at least one of either said inlet or said outlet is greater than the length of said lamination direction of said side wall part.
[0010]In the heat exchanger pertaining to one aspect of the present invention, said sloped surface part may be provided to protrude outwardly from said side wall part.
[0011]In the heat exchanger pertaining to one aspect of the present invention, said sloped surface part may be provided at an incline in a plurality of directions in relation to said side wall part.
[0012]In the heat exchanger according to one aspect of the invention, said sloped surface part may be provided facing the top face side.
[0013]According to the present invention, it will be possible to provide a heat exchanger that can achieve both miniaturization and an increase in the diameter of the fluid path.
BRIEF DESCRIPTION OF THE DRAWINGS
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DETAILED DESCRIPTION
[0023]The examples of embodiment of the present invention will be described below with reference to the drawings.
[0024]
[0025]First, an outline of the representative examples of embodiment of the present invention as disclosed in this application shall be discussed. In the following description, by way of example, the reference numerals on the drawings corresponding to the components of the present invention are noted in parentheses.
[0026]The heat exchanger (1) is provided with a laminated body (2) in which a flow path for a first fluid and a flow path for a second fluid may be mutually formed in the lamination direction through the lamination of a plurality of plates (21, 22, 23, 24), a bottomed cylindrical case (3) to not only house the laminated body but that also has an opening on one side of the laminated body, and a base plate (4) that may be provided on the side of the opening of the case, wherein the case has a side wall part (32) that covers the side surface of the laminated body, a top face part (31) that may be provided on the side of the case that faces said laminated body, a sloped surface part (35, 36) that is contiguous to the side wall part and the top face part and that may be provided at an inclination in relation to the side wall part, and either one of an inlet (33) or an outlet (34), or both of these, that may be provided on the sloped surface part for the passage of a first fluid.
[0027]At least one of either the inlet or outlet may have a diameter that is greater than the length of the side wall in the lamination direction.
[0028]The sloped surface part may be provided to protrude outwardly from the side wall part.
[0029]The sloped surface part may be provided at an incline in a plurality of directions in relation to the side wall part.
[0030]The sloped surface part may be provided facing the top face side.
Configuration of the Heat Exchangers
[0031]Heat exchanger 1 according to the present example of embodiment will be described in detail below. For the convenience of the description below, in heat exchanger 1 as shown in
[0032]Heat exchanger 1 may be used, for example, in a cooling water system of an automobile (vehicle). The automobile to which heat exchanger 1 may be provided may have only an internal combustion engine as the driving source, it may have an internal combustion engine and an electric motor, or it may have only an electric motor, and heat exchanger 1 may be provided in order to cool the fluids that may be used in these vehicles. Cooling water is an example of the fluid that may be used for cooling, and oils such as hydraulic oil are examples of the fluids to be cooled, but these fluids may be selected as appropriate according to the driving method of the automobile, the type of heating part, and the required cooling performance, etc. Further, according to the present embodiment, the fluid used for cooling may be treated as the first fluid, while the fluid to be cooled may be treated as the second fluid, but the fluid used for cooling may be treated as the second fluid and the fluid to be cooled may be treated as the first fluid.
[0033]Heat exchanger 1 may be provided with laminated body 2, case 3, base plate 4, inlet pipe 5 corresponding to the fluid inlet, and outlet pipe 6 corresponding to the fluid outlet (see
[0034]In laminated body 2, as shown in
[0035]In laminated body 2, second plate 22 is overlaid on the top of bottommost plate 23 (or in other words, on the opposite side to base plate 4), and first plate 21 is overlaid thereon. Topmost plate 24 is overlaid on the top of second plate 22, with a planar shape that is the same as that of first plate 21. Fin plate 25 is provided above second plate 22 and below first plate 21 or topmost plate 24 in order to form the flow path for the second fluid (oil). In contrast, the flow path for the first fluid (cooling water) may be formed in the space above first plate 21 and bottommost plate 23 and below second plate 22, and in the space above topmost plate 24 and the surface on the inner side of top face part 31 of case 3. For each plate comprising laminated body 2, it is acceptable to use an aluminum clad material or the like.
[0036]As shown in
[0037]As shown in
[0038]As shown in
[0039]Bottommost plate 23 has a different shape than the other plates, as shown in
[0040]Peripheral flange parts 214, 224, and 244 are formed in the parts of the outer periphery of each plate excluding the parts that correspond to first blocked parts 215 and 245 and second blocked part 225, as may be seen in the planar view in
[0041]It will be possible to assemble a plurality of plates by fitting together the taper of these types of peripheral flange parts 214, 224, and 244 for brazing. For the assembled form of first plate 21, second plate 22, and topmost plate 24, rib 237 may be brazed together with the bottom surface near peripheral flange part 224 of second plate 22, which is at the bottommost side on top of bottommost plate 23 (see
[0042]Among peripheral flange parts 214, 224, and 244, the parts that extend along the Y direction as shown in
[0043]Following assembly, by overlapping first blocked parts 215 and 245 and second blocked part 225 in laminated body 2, depression 26 that is concave in the central direction of the Y direction of the side wall part will be formed near first corner part 201 of periphery part 20 of laminated body 2. In depression 26, a gap is formed between case 3 and laminated body 2, and between the outer surface of peripheral part 20 and the inner surface of side wall part 32, and this gap forms first distribution flow path 28 through which the first fluid can pass along the Z direction.
[0044]Boss 211 is formed in first plate 21 to extend towards the top side in the area surrounding through-hole 212, while boss 221 is formed in second plate 22 to extend towards the bottom side in the area surrounding through-hole 222. Boss 241 that extends towards the top side in the area surrounding through-hole 242 is formed in topmost plate 24 in the position that corresponds to boss 211 and boss 221 of the other plates. These bosses may be joined together in laminated body 2. Following assembly, in laminated body 2, bosses 211, 221, and 231 overlap each other, while through-holes 212, 222, and 232 are connected with each other, resulting in the formation of second distribution flow path 27 through which the second fluid can pass along the Z direction. Boss 241 of topmost plate 24 may be brazed with the inner surface side of top face part 31 of case 3 such that through-hole 242 of boss 241 will be blocked. In the present example of embodiment, through-hole 242 is formed in boss 241 of topmost plate 24, but it is also acceptable to omit the formation of through-hole 242. Also, the space between the top side of first plate 21 and the bottom side of second plate 22 will be divided from second distribution flow path 27, ensuring that the second fluid that passes through second distribution flow path 27 will not flow into this space. In contrast, the space between the bottom side of first plate 21 and the top side of second plate 22 is connected to second distribution flow path 27.
[0045]As a result of the formation of peripheral flange parts 214, 224, and 244 and rib 237 in laminated body 2, there is a division between the space between plates and the external space (the space within case 3) excluding depression 26. As a result of the joining of first blocked part 215 and second blocked part 225 in depression 26, it is possible to create a division between the space between the bottom side of first plate 21 and the top side of second plate 22 and the external space, while the space between the top side of first plate 21 and the bottom side of second plate 22 is connected to the external space.
[0046]Heat exchanger 1 is provided with case 3 that has a flat, approximately rectangular parallelepiped shape. As shown in
[0047]In case 3 as well, the corners may be connected by first diagonal line L1 and second diagonal line L2 as described above. In case 3, the pair of corners that may be connected by first diagonal line L1 is set as first corner part 3A, while the pair of corners that may be connected by second diagonal line L2 is set as second corner part 3B.
[0048]Top face part 31 may be formed in a tabular shape along the XY plane. Top face part 31 may be formed such that the planar shape covers the rectangular laminated body 2 from the top surface side while also covering the top surface side of sloped surface parts 35 and 36.
[0049]Side wall part 32 has a pair of long-side side wall parts 321 that correspond to the long side of top surface part 31, a pair of short-side side wall parts 322 that correspond to the short side, and a total of four curved surface parts 323 that are positioned in the space between long-side side wall part 321 and short-side side wall part 322. Side wall part 32 extends along the Z direction and X direction or Y direction. Long-side side wall part 321 extends along the Z direction and Y direction. Short-side side wall part 322 extends along the Z direction and X direction.
[0050]Side wall part 32 has enlarged part 324 in which the inner dimensions and outer dimensions have been enlarged at the bottom edge on the bottom side, which is the side of the opening of case 3. Bottommost plate 23 has external dimensions that are larger than that of the other plates, and it has enlarged part 324 for attachment of bottommost plate 23.
[0051]Sloped surface parts 35 and 36 are provided in first corner 301, which is the position that corresponds to depression 26 of laminated body 2 among the corners of case 3. Sloped surface parts 35 and 36 have a surface that is inclined from top surface part 31 on the top side in the Z direction towards base plate 4 and bottommost plate 23 on the bottom side, towards the periphery side of base plate 4 in the X-Y plane direction. In other words, sloped surface parts 35 and 36 are provided at an angle with respect to at least the Z direction among the directions in which side wall part 32 extends. For this reason, sloped surface parts 35 and 36 are provided such that they face the top side. Sloped surface part 35 may be provided in a plurality of directions with respect to side wall part 32, or in other words, it may be provided in the Z direction, as well as in the X direction and Y direction. In other words, sloped surface part 35 may be provided at an angle facing the right side in the Y direction and the top side in the X direction in
[0052]In sloped surface parts 35 and 36, inlet 33 and outlet 34 are formed through which the first fluid may pass. Inlet 33 and outlet 34 may be formed in sloped surface parts 35 and 36, for example, in the center.
[0053]Inlet pipe 5 and outlet pipe 6 are cylindrical members through which the first fluid may pass, and are each connected to inlet 33 and outlet 34, respectively, in a liquid-tight manner. Because inlet 33 and outlet 34 are provided in sloped surface part 35 and sloped surface part 36 of the oblique side, the length dimensions of sloped surface part 35 and sloped surface part 36 are greater than the height dimensions of side wall part 32, making it possible to attach inlet pipe 5 and outlet pipe 6 with a pipe diameter that is larger than the height dimensions of case 3 (see
[0054]Base plate 4 may be formed in a tabular shape. A pair of through-holes 41 to enable the passage of the second fluid and a plurality of mounting holes 42 for use in attachment to another device may be formed in base plate 4. In the state in which laminated body 2 is housed in case 3 and base plate 4 is attached to case 3, through-hole 41 and second distribution flow path 27 will be connected (see
[0055]
[0056]As shown in
[0057]In heat exchanger 1, the planar part of bottommost plate 23 that may be provided on the bottom side in the lamination direction, which is the other end of the lamination direction of laminated body 2, is in contact with the surface of the top side in the lamination direction, which is the surface on the inner side of base plate 4 (see
[0058]
[0059]As shown in
[0060]Laminated body 2B is laminated such that peripheral flange parts 214, 224, and 294 face downward. To rephrase, laminated body 2B of heat exchanger 1B has a form in which laminated body 2B is housed inside case 3 by inverting the parts excluding bottommost plate 23 of heat exchanger 1 against laminated body 2 of heat exchanger 1 in the vertical direction, and placing [laminated body 2B] on top of bottommost plate 23B, which is formed such that it will have a line-symmetrical shape having the long side of bottommost plate 23 when viewing the XY plane as the reference.
[0061]By configuring laminated body 2B as described above, the position of first distribution flow path 28 that may be formed by depression 26 and the position of second distribution flow path 27 that connects through-holes 212, 222, 232B, and 292 to enable the second fluid to pass through in the Z direction will be different positions from those in laminated body 2 of heat exchanger 1 as described above. More specifically, the position of first distribution flow path 28 in heat exchanger 1B is in second corner part 302 on second diagonal line L2, while first distribution flow path 28 in heat exchanger 1 is positioned in first corner part 301 on first diagonal line L1. Also, the position of second distribution flow path 27 in heat exchanger 1B is in first corner part 301 on first diagonal line L1, while second distribution flow path 27 in heat exchanger 1 is positioned in second corner part 302 on second diagonal line L2.
[0062]The reason why the positions of first distribution flow path 28 and second distribution flow path 27 differ from those in heat exchanger 1 is because in heat exchanger 1B, the positions are aligned to the position of through-hole 41 B, which is located at a different position in base plate 4B or in other words, because the positions are aligned to different fluid ports on the vehicle side. Because of the differences in the position of first distribution flow path 28 and second distribution flow path 27, in heat exchanger 1B, the position of boss 231B and through-hole 232B for connecting second distribution flow path 27 with through-hole 41B in bottommost plate 23B differs from the position of boss 231 and through-hole 232 in bottommost plate 23 of heat exchanger 1.
[0063]Here, regarding the terms “lamination direction” and “top/bottom” as used in
[0064]In laminated body 2B, the topmost plate is second plate 22, unlike topmost plate 24 in laminated body 2. More specifically, in laminated body 2, the height of peripheral flange part 244 in first plate 21 is lower than the height of peripheral flange part 224 of first plate 21, so that topmost plate 24 will have approximately the same height as boss 241, while the topmost plate in laminated body 2B has the same structure as second plate 22 of laminated body 2. Bottommost plate 23B is formed such that bottommost plate 23 of laminated body 2 will have a line-symmetrical shape with the long-side as viewed on the XY plane as reference, as was described above. Bottom plate 29, which is the plate at the very bottom of laminated body 2B excluding bottommost plate 23B, has the same structure as topmost plate 24 of laminated body 2, as was described above.
[0065]As shown in
[0066]In heat exchanger 1B, the planar part of bottommost plate 23B that may be provided on the lower side in the lamination direction, which is the other end of the lamination direction of laminated body 2B, is in contact with the surface of the upper side in the lamination direction, which is the surface on the inner side of base plate 4.
Operation of the Heat Exchanger
[0067]Next, the operation of heat exchangers 1 and 1B as described above will be discussed.
[0068]In heat exchangers 1 and 1B as described above, for example, by performing heating while laminated body 2 or 2B is housed within case 3 or 3B, the brazing filler metal that has been provided on the surface of each part of laminated body 2 or 2B will melt, and by performing cooling, the brazing filler metal will solidify, joining each part. More specifically, the peripheral flange parts of adjacent plates will be joined together, while at the same time, the tip of the protruding part of the plates will be joined with the bottom surface and top surface of the plates.
[0069]Next, the relationship between each part of cases 3 and 3B and laminated bodies 2 and 2B, as well as the flow of fluid, will be discussed. The external dimensions of laminated bodies 2 and 2B, which have a rectangular parallelepiped shape, are mostly the same or slightly smaller than the internal dimensions of side wall part 32, which is a rectangular cylinder. In other words, of laminated bodies 2 and 2B, for the parts excluding bottommost plates 23 and 23B, the peripheral part 20 follows the inner surface of side wall part 32 excluding the area around depression 26, first projecting part 235, and second projecting part 236. In addition, inlet 33 and outlet 34 are provided near first corner part 301 or second corner part 302, while depression 26 is provided near first corner part 201 or second corner part 202. In the space between depression 26 and side wall part 32, there is a space to connect inlet 33 and outlet 34.
[0070]In this way, a gap is formed between case 3 or 3B and laminated body 2 or 2B in depression 26 between the outer surface of peripheral part 20 and the inner surface of side wall part 32, and this gap forms first distribution flow path 28. Also, for laminated bodies 2 and 2B, first distribution flow path 28 is connected to the space between the upper side of first plate 21 and the lower side of first plate 22 in laminated body 2, and to the space between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2B.
[0071]The first fluid may be introduced from inlet pipe 5 into case 3 and drawn outwards from outlet pipe 6. The first fluid that was introduced into inlet 33 by inlet pipe 5 will reach first distribution flow path 28. In first distribution flow path 28, not only will it be possible for the first fluid to flow along the Z direction, it will also be able to flow into the space between the upper side of first plate 21 and the lower side of second plate 22 in laminated body 2, or into the space between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2B. In other words, the first fluid will be distributed in the Z direction, and it will flow into the plurality of spaces between the upper side of first plate 21 and the lower side of second plate 22 in laminated body 2, and into the space between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2B.
[0072]In laminated bodies 2 and 2B, the first fluid will reach first distribution flow path 28 on the side of outlet 34 from first distribution flow path 28 on the side of inlet 33. Then, the first fluid that had flowed into first distribution flow path 28 on the outlet 34 side will flow along the Z direction so as to be directed towards outlet 34 from each of the spaces between the upper side of first plate 21 and the lower side of second plate 22 in the case of laminated body 2, and from each of the spaces between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2B. In other words, the first fluid that had been distributed will be aggregated once again. The first fluid will then be drawn outwards from outlet 34 by outlet pipe 6.
[0073]The second fluid may be introduced into and drawn out of laminated bodies 2 and 2B using one of the pair of through-holes 41 and 41B as the inlet and using the other as the outlet. The second fluid that was flowed from one of the pair of through-holes 41 and 41B into second distribution flow path 27 can flow along the Z direction, and can flow into the space between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2, or into the space between the upper side of first plate 21 and the lower side of second plate 22 in laminated body 2B. In other words, the second fluid will be distributed in the Z direction, and it will flow into the plurality of spaces between the lower side of first plate 21 and the upper side of second plate 22 in laminated body 2, and into the space between the upper side of first plate 21 and the lower side of second plate 22 in laminated body 2B.
[0074]In laminated bodies 2 and 2B, the second fluid will flow from one of the pair of second distribution flow path 27 towards the other. The second fluid that had flowed into the other of second distribution flow path 27 will flow along the Z direction so as to be directed towards the other of through-holes 41 and 41B from each of the spaces between the lower side of first plate 21 and the upper side of second plate 22 in the case of laminated body 2, and from each of the spaces between the upper side of first plate 21 and the lower side of second plate 22 in laminated body 2B. In other words, the second fluid that had been distributed will be aggregated once again. The second fluid will then be drawn outside from the other through-hole 41 or 41B.
[0075]When the first fluid and the second fluid flow as described above, it is preferable for the direction of flow in the X direction to be opposite to each other. In other words, it is preferable for the second fluid to be introduced into case 3 from through-hole 41 or 41B that is closer to outlet 34 in the X direction among the pair of through-holes 41 and 41B. Depending on conditions such as fluid type and flow rate, it is also acceptable for the first fluid and the second fluid to flow in the same direction in the X direction.
[0076]In heat exchangers 1 and 1B, cases 3 and 3B have side wall parts 32 that cover the side surfaces of laminated bodies 2 and 2B as well as sloped surface parts 35 and 36 that are connected to top surface part 31 that may be provided on the upper side, which is the other side in the lamination direction in cases 3 and 3B, and that are provided at an inclination in relation to side wall part 32. Sloped surface parts 35 and 36 are provided with inlet 33 and outlet 34 through which the first fluid may pass.
[0077]According to heat exchangers 1 and 1B, by providing inlet 33 and outlet 34 in sloped surface parts 35 and 36, the diameter of inlet 33 and outlet 34 can be made to be greater than the length of wall part 32 in the lamination direction without being bound by the dimensions of side wall part 32.
[0078]In other words, according to heat exchangers 1 and 1B, in response to the demand for a reduction in the size of the dimensions of heat exchangers in the vertical (height) direction and a reduction in pressure losses as a result of factors such as the electrification of vehicles, it will be possible to realize a configuration that can achieve both a reduction in the size of the dimensions in the vertical (height) direction and an increase in the diameter of the inlet and outlet.
[0079]Also, heat exchangers 1 and 1B may be provided with sloped surface parts 35 and 36 that protrude outwardly from side wall part 32. By using this type of configuration, it will be possible to ensure a flow path that connects first distribution flow path 28 that may be formed between peripheral part 20 and the inner surface of side wall part 32 with inlet 33 and outlet 34 in heat exchangers 1 and 1B, thereby making it possible to provide inlet 33 and outlet 34 at a variety of positions.
[0080]In heat exchangers 1 and 1B, sloped surface parts 35 and 36 may be provided at an incline in a plurality of directions relative to side wall part 32. In addition, in heat exchangers 1 and 1B, sloped surface parts 35 and 36 may be provided facing the side of top face part 31. By using this type of configuration, it will be possible to realize a design that matches the layout of the vehicle while enabling both a reduction in the size of the dimensions in the vertical (height) direction and an increase in the size of the inlet and outlet in heat exchangers 1 and 1B.
[0081]In heat exchangers 1 and 1B, it is also acceptable for laminated bodies 2 and 2B to be in contact with the inner surface of top face part 31 and base plate 4 in the lamination direction. By using this type of configuration, it will be possible to enable both a reduction in the size of the dimensions in the vertical (height) direction and an increase in the size of the inlet and outlet in heat exchangers 1 and 1B.
[0082]In heat exchangers 1 and 1B, plate 24 (29) matches or mostly matches the height of boss 241, protruding part 243, and peripheral flange part 244 in laminated bodies 2 and 2B. Therefore, in heat exchangers 1 and 1B, it is possible to select one of either an arrangement in which the tip part of peripheral flange parts 214, 224, and 244 of the plate faces the upper side in the lamination direction (see
[0083]Various examples/embodiments are described herein for various apparatuses, systems, and/or methods. Numerous specific details are set forth to provide a thorough understanding of the overall structure, function, manufacture, and use of the examples/embodiments as described in the specification and illustrated in the accompanying drawings. It will be understood by those skilled in the art, however, that the examples/embodiments may be practiced without such specific details. In other instances, well-known operations, components, and elements have not been described in detail so as not to obscure the examples/embodiments described in the specification. Those of ordinary skill in the art will understand that the examples/embodiments described and illustrated herein are non-limiting examples, and thus it can be appreciated that the specific structural and functional details disclosed herein may be representative and do not necessarily limit the scope of the embodiments.
[0084]Reference throughout the specification to “examples, “in examples,” “with examples,” “various embodiments,” “with embodiments,” “in embodiments,” or “an embodiment,” or the like, means that a particular feature, structure, or characteristic described in connection with the example/embodiment is included in at least one embodiment. Thus, appearances of the phrases “examples, “in examples,” “with examples,” “in various embodiments,” “with embodiments,” “in embodiments,” or “an embodiment,” or the like, in places throughout the specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more examples/embodiments. Thus, the particular features, structures, or characteristics illustrated or described in connection with one embodiment/example may be combined, in whole or in part, with the features, structures, functions, and/or characteristics of one or more other embodiments/examples without limitation given that such combination is not illogical or non-functional. Moreover, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from the scope thereof.
[0085]It should be understood that references to a single element are not necessarily so limited and may include one or more of such element. Any directional references (e.g., plus, minus, upper, lower, upward, downward, left, right, leftward, rightward, top, bottom, above, below, vertical, horizontal, clockwise, and counterclockwise) are only used for identification purposes to aid the reader's understanding of the present disclosure, and do not create limitations, particularly as to the position, orientation, or use of examples/embodiments.
[0086]“One or more” includes a function being performed by one element, a function being performed by more than one element, e.g., in a distributed fashion, several functions being performed by one element, several functions being performed by several elements, or any combination of the above.
[0087]It will also be understood that, although the terms first, second, etc. are, in some instances, used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of the various described embodiments. The first element and the second element are both elements, but they are not the same element.
[0088]The terminology used in the description of the various described embodiments herein is for the purpose of describing particular embodiments only and is not intended to be limiting. As used in the description of the various described embodiments and the appended claims, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will also be understood that the phrase “at least one of” followed by successive elements separate by the word “and” (e.g., “at least one of A and B”) is to be interpreted the same as “and/or” and as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items. It will be further understood that the terms “includes,” “including,” “comprises,” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
[0089]Joinder references (e.g., attached, coupled, connected, and the like) are to be construed broadly and may include intermediate members between a connection of elements, relative movement between elements, direct connections, indirect connections, fixed connections, movable connections, operative connections, indirect contact, and/or direct contact. As such, joinder references do not necessarily imply that two elements are directly connected/coupled and in fixed relation to each other. Connections of electrical components, if any, may include mechanical connections, electrical connections, wired connections, and/or wireless connections, among others. Uses of “e.g. ” and “such as” in the specification are to be construed broadly and are used to provide non-limiting examples of embodiments of the disclosure, and the disclosure is not limited to such examples.
[0090]While processes, systems, and methods may be described herein in connection with one or more steps in a particular sequence, it should be understood that such methods may be practiced with the steps in a different order, with certain steps performed simultaneously, with additional steps, and/or with certain described steps omitted.
[0091]As used herein, the term “if” is, optionally, construed to mean “when” or “upon” or “in response to determining” or “in response to detecting,” depending on the context. Similarly, the phrase “if it is determined” or “if [a stated condition or event] is detected” is, optionally, construed to mean “upon determining” or “in response to determining” or “upon detecting [the stated condition or event]” or “in response to detecting [the stated condition or event],” depending on the context.
[0092]All matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative only and not limiting. Changes in detail or structure may be made without departing from the present disclosure.
Claims
1. A heat exchanger, comprising:
a laminated body including a plurality of plates, a first flow path for a first fluid, and a second flow path for a second fluid, the first flow path and the second flow path mutually formed in a lamination direction via lamination of the plurality of plates;
a bottomed cylindrical case housing the laminated body, the bottomed cylindrical case including an opening disposed on one side of the laminated body; and
a base plate arranged on a side of the opening of the bottomed cylindrical case;
wherein the bottomed cylindrical case includes:
a side wall part covering a side surface of the laminated body;
a top face part disposed on a side of the bottomed cylindrical case facing the laminated body;
a sloped surface part contiguous to the side wall part and to the top face part, the sloped surface part extending at an inclination relative to the side wall part; and
an inlet and/or an outlet for passage of the first fluid, the inlet and/or the outlet disposed on the sloped surface part.
2. The heat exchanger as described in
3. The heat exchanger as described in
4. The heat exchanger as described in
5. The heat exchanger as described in
6. The heat exchanger as described in
7. The heat exchanger as described in
8. A heat exchanger, comprising:
a laminated body including a plurality of plates, a first flow path through which a first fluid is flowable, and a second flow path through which a second fluid is flowable, the first flow path and the second flow path formed in a stacking direction via the plurality of plates;
a case in which the laminated body is arranged, the case having an open end and a closed end disposed opposite the open end; and
a base plate covering the open end of the case;
wherein the case includes:
a top face part at least partially defining the closed end of the case;
a side wall part projecting from the top face part toward the base plate;
at least one sloped surface part contiguous to the top face part and to the side wall part, the at least one sloped surface part extending transversely relative to the top face part and to the side wall part; and
at least one fluid port through which the first fluid is flowable.
9. The heat exchanger as described in
10. The heat exchanger as described in
11. The heat exchanger as described in
12. The heat exchanger as described in
the at least one sloped surface part includes a first sloped surface part and a second sloped surface part; and
a portion of the side wall part is disposed between and separates the first sloped surface part and the second sloped surface part.
13. The heat exchanger as described in
14. The heat exchanger as described in
the at least one sloped surface part includes a first sloped surface part and a second sloped surface part;
the at least one fluid port includes a first fluid port and a second fluid port defining an inlet and an outlet for the first fluid;
the first sloped surface part includes the first fluid port; and
the second sloped surface part includes the second fluid port.
15. The heat exchanger as described in
the first fluid port includes a first pipe projecting from the first sloped surface part; and
the second fluid port includes a second pipe projecting from the second sloped surface part.
16. The heat exchanger as described in
the laminated body has a first end, a second end disposed opposite the first end, a third end, and a fourth end disposed opposite the third end;
the first pipe protrudes from the first sloped surface in a direction extending away from the first end and the second end of the laminated body; and
the second pipe protrudes from the second sloped surface in a direction extending toward the first end of the laminated body
17. The heat exchanger as described in
the first sloped surface part is disposed adjacent to and outwardly offset from the first end of the laminated body; and
the second sloped surface part is disposed adjacent to and outwardly offset from the third end of the laminated body.
18. The heat exchanger as described in
19. The heat exchanger as described in
20. The heat exchanger as described in