This application claims priority to German Application No. DE 10 2018 200 809.4, filed on Jan. 18, 2018, the contents of which are hereby incorporated by reference in its entirety.
The invention relates to a stacked plate heat exchanger, in particular an oil cooler, a chiller or a condenser for a motor vehicle.
Stacked plate heat exchangers are already known from the prior art and are used for example as oil coolers, chillers or condensers in a motor vehicle. A stacked plate heat exchanger has here several elongate plates stacked on one another, between which cavities are formed. In the cavities, arranged on one another, two media flow—a cooling medium and a medium which is to be cooled, —so that a heat exchange can take place between the two media. The cavities are delimited here by a surface and a surface edge of the respective plate and by the adjacent resting plate. In each of the plates, four openings are formed which correspond with one another in the plates lying on one another and form a total of four channels perpendicular to the plates. Two of these channels are provided for the feeding and discharging of the one medium, and two of these channels are provided for the feeding and discharging of the other medium into the respective cavities. The cavities for the two media alternate here in the stacked plate heat exchanger, and the channels are fluidically connected exclusively with the corresponding cavities.
The respective medium flows from one opening to the other opening over the surface of the respective plate. The flow can be u-shaped, for example, as is described in DE 10 2012 107 381 A1. In order to enlarge the surface of the plate taking part in the heat exchange, an elongate shaping—a so-called bead—is formed on the plate. The shaping extends here parallel to the longitudinal centre axis of the respective plate and separates the two openings from one another.
The respective medium can thereby not flow directly from the one opening to the other opening, and the heat exchange is intensified. Alternatively to a u-shaped flow, other flows can also be provided, such as is described for example in U.S. Pat. No. 5,735,343 A. Here, the bead separates the surface of the plate into two parts, so that each of the parts is flowed through separately by the respective medium.
In the stacked plate heat exchanger, at least one of the media changes its aggregate state from gaseous to liquid or respectively from liquid to gaseous, and the volume flow changes accordingly. Here, the volume of the medium available for heat exchange is not utilized optimally, and the output- and pressure ratio in the stacked plate heat exchanger is thereby not optimum.
It is therefore the object of the invention to indicate for a stacked plate heat exchanger of the generic type an improved or at least alternative embodiment, in which the described disadvantages are overcome.
This problem is solved according to the invention by the subject of the independent claim(s). Advantageous embodiments are the subject of the dependent claim(s).
The present invention is based on the general idea of adapting a flow cross-section in a stacked plate heat exchanger to an aggregate state of a medium which is flowing through. The stacked plate heat exchanger here can be, in particular, an oil cooler, a chiller or a condenser for a motor vehicle. The stacked plate heat exchanger has several elongate plates stacked on one another, between which cavities are formed in an alternating manner for two media—a cooling medium and a medium which is to be cooled. The cavities are delimited at the respective plates zonally by respectively a plate surface and a surrounding wall projecting from the plate surface and running around the latter. In the respective plate, in addition, two flow openings are formed in an adjacent manner on a first short side and two passage openings on a second short side lying opposite the first short side, wherein in the respective plate around the two passage openings respectively a dome is formed projecting from the plate surface into the cavity. On the plate surface at least of one of the plates, an elongate separation shaping is formed, projecting into the cavity, which separation shaping extends from the first short side between the two flow openings in the direction of the second short side. According to the invention, the separation shaping adjoins the first short side at an angle α between 45° and 90°.
The two short sides are connected with one another by long sides, which are longer than the two short sides. The plate surface is substantially rectangular, and the two short sides and the two long sides are respectively equal in length. The separation shaping divides the plate surface into two flow regions. Here, the first flow region surrounds the first flow opening for the inflow of the respective medium, and extends between the separation shaping and the one long side from the first short side to the second short side. The second flow region surrounds the second flow opening for the outflow of the respective medium, and extends between the separation shaping and the other long side from the first short side to the second short side. The two flow regions are separated fluidically from one another along the separation shaping, and are only connected fluidically with one another at the second short side. The separation shaping adjoins the first short side here, so that no flow can take place along the first short side, and the respective medium is forced to a u-shaped flow in the respective plate. Through the fact that the separation shaping adjoins the first short side at an angle, the flow cross-section changes in the flow direction of the respective medium. In particular, the flow cross-section is adaptable to the aggregate state of the respective medium, so that the output- and pressure ratio in the stacked plate heat exchanger can be optimized, and the volume available for the heat exchange can be utilized optimally. The several plates, stacked on one another, can be configured so as to be identical here, or can differ from plate to plate.
Advantageously, provision can be made that the separation shaping is rectilinear or is curved towards a long side connecting the two short sides. The separation shaping can also have at least two rectilinear separation regions, which adjoin one another at a bend angle. A ratio of a length of one of the separation regions to a total length of the separation shaping then lies between 0 and 1. With the ratio equal to 0 or 1, the one separation region continues into the other separation region, so that the separation shaping in the two separation regions corresponds to the rectilinear separation shaping. By an adaptation of the bend angle, the flow at the respective plate and thereby also the heat exchange between the two media can be optimized. The bend angle β can vary here between 90° and 180°.
Advantageously, the separation shaping divides the first short side in a ratio between 0.3 and 0.5 to a total length of the short side. With a ratio equal to 0.5, the separation shaping adjoins the short side centrally, so that the two regions formed by the separation shaping have an identical flow cross-section at least at the first short side. With a smaller ratio, the separation shaping at the first short side is offset to one of the flow openings or respectively to one of the long sides, so that the flow cross-sections differ at least at the first short side. The separation shaping can extend, in addition, up to 0.2 times to 0.8 times the length of the long side from the first short side in the direction of the second short side. The remaining 0.8 times to 0.2 times length of the long side from the second short side in the direction of the first short side then corresponds to the length of a connection region, in which the two flow regions overlap and are fluidically connected with one another.
In order to optimize the flow of the respective medium in the respective flow regions, and the heat exchange in the stacked plate heat exchanger, advantageously at least one flow guide structure can be arranged in the cavity of at least one of the plates. The flow guide structure can guide the respective medium through the flow region and mix it. The respective flow guide structure can be, for example, a turbulence insert. Alternatively, the respective flow guide structure can be formed—stamped, for example—in the plate surface of the respective plate, projecting into the cavity. The flow guide structure can comprise here several nub-like or elongate or undulating shapings. Advantageously, on both sides on the separation shaping of at least one of the plates respectively a flow guide structure can be arranged, and the respective flow guide structures can be configured so as to be identical or different. Thereby, a great variety of possible configurations of the respective plate arise, so that the flow and the heat exchange in the respective plate are able to be adapted to the respective medium and to the changing aggregate state of the respective medium.
In an advantageous further development of the stacked plate heat exchanger according to the invention, provision can be made that the flow openings and/or the passage openings at least of one of the plates have a flow cross-section differing from one another. In addition, the flow openings and the passage openings of the plates which are stacked on one another can correspond with one another fluidically, and flow cross-sections of the flow- and passage openings of the plates which are stacked on one another in the stacked plate heat exchanger can continuously increase or decrease from plate to plate. In this advantageous manner, a flow cross-section of a channel formed by the flow- and passage openings can continuously increase or decrease. The ratio of the minimum flow cross-section to the maximum flow cross-section of the respective channel can lie here between 0.25 and 1. In this advantageous manner, the flow cross-section of the respective channel can also be adapted to the aggregate state of the through-flowing medium.
In summary, in the stacked plate heat exchanger according to the invention, the flow cross-section in the respective plate can be adapted to the aggregate state of the respective through-flowing medium. Thereby, the output- and pressure ratio in the stacked plate heat exchanger can be optimized, and the volume available for heat exchange can be utilized optimally. Advantageously, the stacked plate heat exchanger can then have fewer or respectively smaller plates, without the output of the stacked plate heat exchanger being reduced. Cost advantages result considerably thereby.
Further important features and advantages of the invention will emerge from the subclaims, from the drawings and from the associated figure description with the aid of the drawings.
It shall be understood that the features mentioned above and to be explained further below are able to be used not only in the respectively indicated combination, but also in other combinations or in isolation, without departing from the scope of the present invention.
Preferred example embodiments of the invention are illustrated in the drawings and are explained further in the following description, wherein the same reference numbers refer to identical or similar or functionally identical components.
There are shown, respectively diagrammatically
The respective plate 1 is shaped so as to be elongate and has a first short side 6a and a second short side 6b lying opposite the first short side 6a. The two short sides 6a and 6b are connected with one another by two opposite long sides 7a and 7b. The short sides 6a and 6b and the long sides 7a and 7b delimit the plate surface 4. On the first short side 6a, two flow openings 8a and 8b are formed. A first medium M1 can flow through the flow openings 8a and 8b into the cavity 3 and can flow out from the cavity 3. On the second short side 6b, two passage openings 9a and 9b are arranged, around which respectively a dome 10a and 10b is formed, projecting from the plate surface 4 into the cavity 3. The domes 10a and 10b prevent an inflow of a second medium M2 into the cavity 3 and an outflow of the first medium M1 out from the cavity 3. The flow openings 8a and 8b and the passage openings 9a and 9b alternate in the plates 1 of the stacked plate heat exchanger 2 which lie on one another, so that in the stacked cavities 3 respectively the first medium M1 or the second medium M2 flows. As generally shown in
On the plate surface 4, an elongate separation shaping 11—a so-called bead—is formed projecting into the cavity 3, which bead extends from the first short side 6a between the two flow openings 8a and 8b in the direction of the second short side 6b. Here, the separation shaping 11 adjoins the first short side 6a at an angle α, which lies preferably between 45° and 90°. In this example embodiment, the separation shaping 11 is rectilinear and adjoins the first short side 6a at an angle α equal to 60°. The separation shaping 11 divides the first short side 6a in a ratio of 0.3 to the total length of the first short side 6a and extends from the first short side 6a in the direction of the second short side 6b up 0.8 times the length of the long sides 7a and 7b.
The separation shaping 11 divides the plate surface 4 into two flow regions 4a and 4b, which have an unequal flow cross-section. From a feed channel 12a, the first medium M1 flows through the first flow opening 8a into the first flow region 4a and further in the direction of the second short side 6b. At the second short side 6b, the first medium M1 is diverted and flows in the second flow region 4b to the flow opening 8b and into the discharge channel 12b. The first medium M1 flows in the plate 1 in a u-shaped manner, as indicated here and further by arrows, and the flow cross-section decreases in the flow direction from the flow opening 8a to the flow opening 8b. The flow cross-section is thereby adapted to the aggregate state of the first medium M1, which changes here from gaseous to liquid, as in a condenser. In particular, the output- and pressure ratio can thereby be optimized in the stacked plate heat exchanger 2, and the volume of the first medium M1 available for the heat exchange can be utilized optimally. In addition, the flow openings 8a and 8b also have flow cross-sections differing from one another and adapted to the aggregate state of the first medium M1. It shall be understood that the flow cross-section in the plate 1 and the flow cross-sections of the flow openings 8a and 8b can also be adapted to a first medium M1, which changes the aggregate state from liquid to gaseous—such as for example in a chiller or an evaporator.
In addition, in the flow region 4a a first flow guide structure 13a is arranged, and in the flow region 4b a second flow guide structure 13b is arranged. In this example embodiment, the first flow guide structure 13a comprises several nubs 14, which are formed integrally—stamped, for example—in the plate surface 4 in the flow region 4a, and project into the cavity 3. In this example embodiment, the second flow guide structure 13b is formed in an undulating manner and integrally—stamped, for example—on the plate surface 4, and expediently projects into the cavity 3. The flow guide structures 13a and 13b guide and mix the first medium M1 at the plate 1, and the heat exchange can thereby be intensified. In addition, the separation shaping 11 is formed zonally on the second flow structure 13b, so that an unimpeded throughflow of the first medium M1 is prevented at the separation shaping 11.
It shall be understood that plates for the second medium M2 can be configured in an identical manner. At the plate 1 shown here, however, the second medium M2 does not flow, and is delivered through a feed channel 15a of the first throughflow opening 9a and a discharge channel 15b of the second throughflow opening 9b into a cavity of a next plate, as is indicated here and further by arrows.
In summary, in the stacked plate heat exchanger 2 according to the invention, the flow cross-section in the respective plate 1 can be adapted to the aggregate state of the respective through-flowing medium M1 and M2. Thereby, the output- and pressure ratio in the stacked plate heat exchanger 2 can be optimized, and the volume of the respective medium M1 and M2 available for the heat exchange can be utilized optimally.
Number | Date | Country | Kind |
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102018200809.4 | Jan 2018 | DE | national |
Number | Name | Date | Kind |
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5172759 | Shimoya | Dec 1992 | A |
5735343 | Kajikawa et al. | Apr 1998 | A |
20150233650 | Blomgren | Aug 2015 | A1 |
Number | Date | Country |
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10 2012 107 381 | May 2014 | DE |
Entry |
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English abstract for DE-10 2012 107 381. |
Number | Date | Country | |
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20190219313 A1 | Jul 2019 | US |