DE102021118790A1 - Cooling device for cooling at least one component of a motor vehicle and motor vehicle - Google Patents

Abstract

The invention relates to a cooling device (1) for cooling at least one component of a motor vehicle, with at least one partial area (2) through which a fluid can flow in a U-shape, with at least one inlet opening (9) through which the fluid can flow, through which the fluid can enter the partial area (2) can be introduced, and having at least one outlet opening (11) through which the fluid can flow, via which the fluid flowing through the partial area (2) can be discharged from the cooling device (1), wherein a fluid can flow through and is fluidically connected to the inlet opening ( 9) and the sub-area (2), connected to the first channel (12), which is arranged downstream of the inlet opening (9) and upstream of the sub-area (2) in the flow direction, and a fluid flow through which is fluidly connected to the sub-area (2) and the outlet opening (11) connected, second channel (13), which downstream of the portion (2) and upstream of the outlet opening (11) is arranged, and the channels (12, 13) ge Common walls (14) directly delimiting the channels (12, 13) are provided.

Description

The invention relates to a cooling device for cooling at least one component of a motor vehicle according to the preamble of patent claim 1. The invention also relates to a motor vehicle.

the DE 10 2007 043 231 A1 discloses an exhaust gas recirculation cooler apparatus having at least one cooling plate having an upper plate wall and a lower plate wall, the upper and lower plate walls defining a plurality of gas passages having a gas inlet at a first end of the cooling plate and a gas outlet at the first end of the cooling plate. Each passage directs gas flow between the inlet and the outlet and around a length of the panel, the panel being sealed so as to be gas-tight along a length of the panel and at a second end of the panel.

The object of the invention is to create a cooling device for cooling at least one component of a motor vehicle and a motor vehicle with such a cooling device, so that installation space, production costs and maintenance costs of the cooling device can be kept particularly low.

This object is achieved according to the invention by a cooling device for cooling at least one component of a motor vehicle having the features of patent claim 1 and by a motor vehicle with such a cooling device having the features of patent claim 9 . Advantageous configurations of the invention are the subject matter of the dependent patent claims and the description.

A first aspect of the invention relates to a cooling device for cooling at least one component of a motor vehicle. The motor vehicle is preferably designed as a motor vehicle, in particular as a passenger car, utility vehicle or truck, or as a passenger bus or motorcycle. The motor vehicle is preferably a battery electric vehicle (BEV) or a hybrid vehicle. The component is, for example, an electrical energy store of the motor vehicle, in particular a high-voltage store. The electrical energy store can be designed as a battery, for example. Alternatively, the component can be an electric machine of the motor vehicle or an internal combustion engine of the motor vehicle. The cooling device can in particular be referred to as a cooling module or as a cooler or be designed as a cooling module of the motor vehicle.

The cooling device has at least one partial area through which a fluid can flow in a U-shape. In other words, the fluid forms a U-shape as it flows through the partial area. This can in particular be understood to mean that a flow of the fluid, in particular streamlines, flow through the partial area in a U-shape. To put it another way, the partial area is at least partially U-shaped. Because the fluid flows or can flow through the partial area in a U-shape, the cooling device can be referred to in particular as a U-type cooler, a U-flow type cooler or as a U-flow type cooler.

The U-shaped flow or the U-shape of the partial area can be understood in particular to mean that the partial area has two legs through which the fluid can flow and one web through which the fluid can flow. The legs and the web are fluidly connected to one another. The legs are preferably arranged parallel to one another. The web is arranged between the legs in the direction of flow of the fluid flowing through the partial area, that is to say the fluid flows from a first of the legs via the web to the second of the legs.

The fluid can in particular be referred to as a coolant or be designed as a coolant. The fluid can be a liquid or a gas. The fluid is preferably water, which can in particular be referred to as cooling water.

For example, the component is arranged in the vicinity, in particular directly, on the cooling device, in particular on the partial area. As a result, the fluid can at least partially flow around the component or flow along the component. As a result, heat of the component can be dissipated from the component by means of the fluid and transferred to the fluid or absorbed by the fluid. This allows the component to be cooled by the fluid.

The cooling device has at least one inlet opening through which the fluid can flow, via which the fluid can be introduced from an area surrounding the cooling device into the partial area. In other words, the inlet opening is arranged upstream of the partial area and is fluidically connected to the partial area, as a result of which the fluid can be supplied to the partial area via the inlet opening. The cooling device has at least one outlet opening through which the fluid can flow, via which the fluid flowing through the partial area is discharged from the cooling device, in particular to the environment exercise, can be removed. In other words, the outlet opening is arranged downstream of the partial area and is fluidically connected to the partial area, as a result of which the fluid from the partial area can be discharged from the cooling device via the outlet opening.

The inlet opening and the outlet opening can each be referred to as a connection, in particular a water connection. For example, a respective connection piece, referred to in particular as a connection piece or water connection piece, can be connected to the inlet opening and/or to the outlet opening. For example, the fluid can be introduced via the inlet opening into the cooling device via a connection piece which is fluidically connected to the inlet opening and is referred to in particular as an inlet connection piece. For example, the fluid can be discharged from the cooling device via the outlet opening and introduced into the outlet connection piece via a connection piece fluidically connected to the outlet opening and in particular referred to as an outlet connection piece. The respective connecting piece can be designed as a hose, for example.

In order to be able to keep installation space, production costs and maintenance costs of the cooling device particularly low, it is provided according to the invention that the cooling device has a first channel through which the fluid can flow and which is fluidically connected to the inlet opening and the partial area, which channel runs in the direction of flow of the cooling device fluid flowing through is arranged downstream of the inlet opening and upstream of the partial region. In other words, the fluid flowing through the inlet opening can be introduced into the partial area via the first channel. The cooling device has a second channel through which the fluid can flow and which is fluidically connected to the partial area, the inlet opening, the outlet opening and the first channel, which second channel is arranged in the flow direction of the fluid flowing through the cooling device downstream of the partial area and upstream of the outlet opening. In other words, the fluid introduced via the first channel into the partial area and flowing through the partial area can be guided via the second channel to the outlet opening, via which the fluid can be discharged from the second channel or from the cooling device. In addition, the cooling device has at least one wall which is common to the channels and directly delimits the channels at least partially, in particular jointly. In other words, the first channel and the second channel are directly delimited by the wall. In other words, the fluid flowing through the first channel flows directly along the wall and the fluid flowing through the second channel also flows directly along the wall.

The invention is based in particular on the following findings and considerations: In a conventional cooling device, it can usually be provided that the inlet opening and the outlet opening are particularly far apart from one another. For example, the inlet opening can be arranged in a lower area of the cooling device and the outlet opening can be arranged in an upper area of the cooling device, for example. When the cooling device is installed in the motor vehicle, the upper area can be arranged above the lower area in the vertical direction of the vehicle, with the cooling device assuming its installation position when the motor vehicle is in a fully assembled state. In a conventional cooling device, for example, it may be possible to arrange the inlet opening and the outlet opening particularly close to one another and thus, for example, to lead the inlet opening upwards by means of an additional component or to arrange it upwards, in particular in the upper area. The additional component can be, for example, an additional, in particular external, line element. This means that in a conventional cooling device, the inlet opening and the outlet opening or the respective connecting pieces can only be located in the immediate vicinity or in the upper area of one another by means of external line routing. As a result, the installation space of a conventional cooling device can be particularly increased. In addition, the inlet opening and the outlet opening or the respective connection pieces of a conventional cooling device can be particularly difficult or particularly difficult to access during production, for example assembly, or maintenance, for example servicing, of the conventional cooling device. As a result, the cost of manufacture, in particular assembly, and maintenance, in particular service, can be particularly increased in the case of a conventional cooling device.

In contrast, a space-saving, in particular integral, solution can be achieved by means of the cooling device according to the invention in order to place the inlet opening and the outlet opening or, in particular, all the connecting pieces close to one another, for example in an upper region of the cooling device. By means of the two channels, the inlet opening and the outlet opening can be arranged close to one another or in the upper area of the cooling device. As a result, the inlet and outlet openings are related tion, the connection pieces for the production, in particular the assembly, and the maintenance, in particular the service, of the cooling device are particularly easily accessible. As a result, the production, in particular the assembly, and the maintenance, in particular the service, of the cooling device can be made particularly easier. In this way, the effort involved in manufacturing, in particular assembling, and maintaining, in particular servicing, the cooling device can be kept particularly low. Furthermore, the additional line element can be omitted in the cooling device according to the invention, ie the cooling device according to the invention does not have the additional line element. As a result, for example, the installation space of the cooling device can be kept particularly small. In addition, the number of parts in the cooling device can be kept particularly low, as a result of which, for example, the costs of the cooling device can be kept particularly low.

In a further embodiment, it is provided that the fluid can flow through the first channel at least predominantly, in particular completely, along the first flow direction and through the second channel at least predominantly, in particular completely, along the second flow direction. In other words, the first channel extends in its longitudinal direction along the first flow direction and the second channel extends in its longitudinal direction along the second flow direction. Expressed again in other words, the fluid flows through the first channel at least predominantly, in particular completely, in the first flow direction and the fluid flows through the second channel at least predominantly, in particular completely, in the second flow direction.

Provision is preferably made for the first direction of flow and the second direction of flow to run parallel to one another. In other words, the first channel extends in its longitudinal direction parallel to the longitudinal direction of the second channel. As a result, the fluid can be guided particularly advantageously from the inlet opening to the partial area via the first channel, and the fluid can be guided particularly advantageously from the partial area to the outlet opening via the second channel. For example, the inlet opening and the outlet opening can be arranged particularly advantageously, in particular in a particularly space-saving manner, in the upper region of the cooling device. The cooling device can thus be designed to be particularly space-saving, in particular the fluid can flow through it in a particularly brewing space-saving manner.

Flow can preferably flow through the first leg at least predominantly, in particular completely, along a third flow direction. In other words, the fluid in the partial area flows through the first leg at least predominantly, in particular completely, in the third flow direction. The web can preferably be flowed through at least predominantly, in particular completely, along a fourth flow direction. In other words, the fluid flows through the partial area in the web at least predominantly, in particular completely, in the fourth flow direction. Preferably, the second leg can be flowed through at least predominantly, in particular completely, along a fifth flow direction. In other words, the fluid flows through the partial area in the second leg at least predominantly, in particular completely, in the fifth flow direction.

The third and the fifth direction of flow are preferably parallel to one another, in particular parallel and in opposite directions. In other words, the third and fifth flow directions preferably run in opposite directions to one another. The fourth direction of flow preferably runs obliquely or perpendicularly to the third and to the fifth direction of flow. The first direction of flow and/or the second direction of flow preferably run obliquely or perpendicularly to the third and to the fifth direction of flow. In other words, the first channel and/or the second channel extend in its respective direction of longitudinal extent obliquely or perpendicularly to the respective direction of longitudinal extent of the legs.

The fourth direction of flow is preferably parallel to the first and/or to the second direction of flow, at least in a section of the web. The inlet opening is preferably directly fluidly connected to the first channel. The first channel is preferably directly fluidly connected to the partial area, in particular to the first leg. The first leg is preferably directly fluidly connected to the web. The web is preferably directly fluidly connected to the second leg. The partial area, in particular the second leg, is preferably directly fluidly connected to the second channel. The second channel is preferably directly fluidly connected to the outlet opening.

In a further embodiment, it is provided that the wall is arranged between the channels along a direction running perpendicularly to the first and the second flow direction. In other words, the channels are direct along the direction perpendicular to the first and second flow directions wherein the first channel is directly defined by the wall in a first direction along the direction and the second channel is directly defined by the wall in a second direction along the direction and opposite to the first direction. As a result, for example, the installation space of the cooling device can be kept particularly small.

In a further embodiment, the wall is designed in one piece. In other words, the wall comprises only one component, that is to say the wall is not formed by a plurality of components which are formed separately from one another and are connected to one another. As a result, for example, manufacturing costs for the cooling device can be kept particularly low. Thus, for example, the costs of the cooling device can be kept particularly low.

In a further refinement, the cooling device has at least one first line element which at least partially delimits the first channel. In other words, the first line element is designed as a channel wall for the first channel that at least partially directly delimits the first channel. The cooling device has a second line element which is formed separately from the first line element and is connected to the first line element, in particular fluidically and mechanically, and which at least partially directly delimits the second channel. In other words, the second line element is designed as a channel wall that at least partially directly delimits the second channel for the second channel. The fluid or the flow can be guided particularly advantageously through the respective channel by means of the line elements.

For example, the line elements are connected or joined together by means of welding, in particular vibration welding. Alternatively, the first line element and the second line element can be formed together in one piece. In other words, the line elements can be designed as an integral component, with the integral component comprising only one component and not a plurality of components which are configured separately from one another and are connected to one another. Thus, for example, the flow of the fluid can be guided in the first channel and the second channel in the integral component.

For example, the first line element and the partial area and/or the second line element and the partial area can be formed together in one piece. In other words, the first line element and the partial area and/or the second line element and the partial area can be designed as an integral component. The flow of the fluid in the cooling device can thus be guided by means of the respective integral component.

In a further embodiment, it is provided that the second line element has the wall. In other words, the second line element includes the wall, whereas the first line element does not include the wall. In other words, the second channel is at least partially directly delimited by the second line element and the first channel is at least partially directly delimited by the first line element and the second line element. In this case, the second channel is preferably not directly delimited by the first line element. As a result, for example, the installation space and the number of parts in the cooling device can be kept particularly small.

In a further embodiment, it is provided that the inlet opening extends in a first plane and the outlet opening extends in a second plane running obliquely or perpendicularly to the first plane. In other words, the fluid can flow through the inlet opening in a first flow direction and the fluid can flow through the outlet opening in a second flow direction, the first flow direction running obliquely or perpendicularly to the second flow direction. As a result, the fluid can be introduced into the cooling device particularly advantageously via the inlet opening and discharged from the cooling device particularly advantageously via the outlet opening. In this case, for example, the installation space of the cooling device can be kept particularly small. In addition, for example, the cost of manufacturing and maintaining the cooling device can be kept particularly low.

The inlet opening is preferably arranged close to the outlet opening or in, in particular in the immediate vicinity of, the outlet opening.

A second aspect of the invention relates to a motor vehicle which has a cooling device according to the invention according to the first aspect of the invention. Advantages and advantageous configurations of the first aspect of the invention are to be regarded as advantages and advantageous configurations of the second aspect of the invention and vice versa. The motor vehicle according to the invention is preferably designed as a motor vehicle, in particular as a passenger car, commercial vehicle or truck, or as a passenger bus or motorcycle.

The motor vehicle can be embodied, for example, as an electric, in particular battery-electric, motor vehicle. This can in particular be understood to mean that the motor vehicle has at least one electric machine, by means of which the motor vehicle can be driven. The motor vehicle can be designed as a hybrid vehicle, for example. This can be understood in particular as meaning that the motor vehicle has the electric machine and has an internal combustion engine, it being possible for the motor vehicle to be driven by means of the electric machine and/or by means of the internal combustion engine.

At least one component of the motor vehicle can be cooled by means of the cooling device. For example, the electric machine of the motor vehicle can be designed as the component. For example, an energy store, in particular an electrical energy store, can be designed as the component. The energy store is provided, for example, to supply the electrical machine with energy, in particular electrical energy. For example, the energy store can be a battery. The component can be designed as a fuel cell, for example. The fuel cell can be designed, for example, to supply the electrical machine of the motor vehicle with electrical energy. For example, the component can be the internal combustion engine.

For example, the inlet opening and the outlet opening are arranged in the installation position of the cooling device in the motor vehicle in the vertical direction of the vehicle in an upper region of the cooling device. The cooling device assumes its installed position in the motor vehicle when the motor vehicle is in a completely manufactured state. For example, the inlet opening and the outlet opening can be arranged on the same side of the cooling device, the side being an upper side of the cooling device pointing upwards in the vertical direction of the vehicle.

Further features of the invention result from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description and the features and combinations of features mentioned below in the description of the figures and/or shown alone in the figures can be used not only in the combination specified in each case, but also in other combinations or on their own.

• 1 eine schematische und perspektivische Teilansicht einer erfindungsgemäßen Kühleinrichtung; und
• 2 eine schematische Teilschnittansicht einer erfindungsgemäßen Kühleinrichtung; und
• 3 eine schematische und perspektivische Teilansicht einer Kühleinrichtung gemäß dem Stand der Technik; und
• 4 eine schematische Perspektivansicht zweier Leitungselemente einer erfindungsgemäßen Kühleinrichtung; und
• 5 eine schematische Perspektivansicht zweier Leitungselemente einer erfindungsgemäßen Kühleinrichtung aus einem anderen Blickwinkel als in 4.

The invention will now be explained in more detail using a preferred exemplary embodiment and with reference to the drawings. Show it:

• 1 a schematic and perspective partial view of a cooling device according to the invention; and
• 2 a schematic partial sectional view of a cooling device according to the invention; and
• 3 a schematic and perspective partial view of a cooling device according to the prior art; and
• 4 a schematic perspective view of two line elements of a cooling device according to the invention; and
• 5 a schematic perspective view of two line elements of a cooling device according to the invention from a different perspective than in FIG 4 .

Elements that are the same or have the same function are provided with the same reference symbols in the figures.

1 shows a cooling device 1 for cooling at least one component of a motor vehicle in a schematic and perspective partial view. The component can be, for example, an electrical energy store, in particular a battery, an electrical machine or an internal combustion engine of the motor vehicle.

2 shows the cooling device 1 in a schematic partial sectional view. The cooling device 1 has at least one partial area 2 through which a fluid can flow in a U-shape. The partial area 2 has two legs 3 , 4 and a web 5 . The legs 3, 4 and the web 5 are fluidically connected to one another. A first of the legs 3 is arranged upstream of the web 5 in the direction of flow of the fluid flowing through the partial area 2 . The second of the legs 4 is arranged downstream of the web 5 in the direction of flow of the fluid flowing through the partial area 2 . The partial area 2 is at least partially, in particular directly, delimited by a partial area wall 6 . A first wall area 7 of the partial area wall 6 delimits the first leg 3 and the second leg 4 at least partially, in particular directly. A second wall area 8 of the partial area wall 6 delimits the web 5 at least partially, in particular directly. in the in 2 In the exemplary embodiment shown, the second wall region 8 delimits the legs 3, 4 at least partially, in particular directly. The first leg 3 is fluidically connected to the web 5 via a through-opening 8a arranged in the second wall region 8 . The web 5 is spaced apart from the first through-opening 8a and arranged in the second wall region 8, second passage passage opening 8b fluidly connected to the second leg 4.

The cooling device 1 has at least one inlet opening 9 through which the fluid can flow, via which the fluid can be introduced from an environment 10 of the cooling device 1 into the partial region 2 , in particular into the first leg 3 . The cooling device 1 has at least one outlet opening 11 through which the fluid can flow and which is at a distance from the inlet opening 9 and via which the fluid flowing through the partial area 2 can be discharged from the cooling device 1 to the environment 10 .

In order to be able to keep installation space, production costs and maintenance costs of the cooling device 1 particularly low, it is provided that the cooling device 1 has a first channel 12 through which the fluid can flow and which is fluidically connected to the inlet opening 9 and the partial area 2, which in Flow direction of the fluid flowing through the cooling device 1 is arranged downstream of the inlet opening 9 and upstream of the partial region 2, in particular the first leg 3. The first channel 12 is fluidically connected to the first leg 3 . The cooling device 1 has a second channel 13 through which the fluid can flow and which is fluidically connected to the partial area 2, the inlet opening 9, the outlet opening 11 and the first channel 12, which in the direction of flow of the fluid flowing through the cooling device 1 is downstream of the partial area 2, in particular of the second leg 4 and upstream of the outlet opening 11 . The second channel 13 is fluidically connected to the second leg 4 . The channels 12, 13 are spaced from each other. The cooling device 1 has a wall 14 which is common to the channels 12, 13 and directly delimits the channels 12, 13 in each case at least partially, in particular jointly.

In the installation position of the cooling device 1 in the motor vehicle, the inlet opening 9 and the outlet opening 11 are arranged in the vertical direction 15 of the vehicle in an upper region 16 of the cooling device 1 . The upper area 16 can be understood in particular as at least an upper half of the cooling device 1 or a highest point or highest area of the cooling device 1 . For example, the upper area 16 can be understood as an area which corresponds to at least 50 percent, in particular 70, 80 or 90 percent, of an overall height of the cooling device 1 .

3 shows a schematic and perspective partial view of a conventional cooling device 1a, which differs in particular from that in FIGS 1 and 2 cooling device 1 shown differs in that the 3 The cooling device 1a shown does not include the wall 14 and the channels 12, 13. In order to be able to arrange the inlet opening 9 and the outlet opening 11 in the upper region 16 of the cooling device 1a in the conventional cooling device 1a, an external line element 17 is provided which fluidly connects the partial region 2 and the inlet opening 9 to one another. In contrast, the in the 1 and 2 The cooling device 1 shown has the channels 12, 13 directly delimited by the wall 14. This allows the in the 1 and 2 Cooling device 1 shown, the external line element 17 is omitted. As a result, the installation space of the cooling device 1 can be kept particularly small. In addition, the effort involved in manufacturing, in particular assembling, and maintaining, in particular servicing, the cooling device 1 can be kept particularly low. For example, accessibility of the cooling device 1 during assembly or during maintenance or service can be particularly improved.

At the in the 1 and 2 The cooling device 1 shown can flow through the first channel 12 along a first flow direction 18 and the second channel 13 can flow through the fluid along a second flow direction 19 . The fluid can flow through the first leg 3 in a third flow direction 20 . The fluid can flow through web 5 in a fourth flow direction 21 . The fluid can flow through the second leg 4 in a fifth flow direction 22 .

The first and second flow directions 18, 19 preferably run parallel, in particular opposite, to one another. As a result, the fluid can be introduced particularly advantageously from the inlet opening 9 via the first channel 12 into the partial area 2, in particular the first leg 3, and the fluid can be introduced particularly advantageously from the partial area 2, in particular the second leg 4, via the second channel 13 and the outlet opening 11 are discharged from the cooling device 1. The installation space of the cooling device 1 and the production costs and the maintenance costs of the cooling device 1 can be kept particularly low. The third flow direction 20 and the fifth flow direction 22 run parallel to one another, with the third flow direction 20 and the fifth flow direction 22 running opposite to one another. The fourth direction of flow 21 runs obliquely or perpendicularly to the third direction of flow 20 and to the fifth direction of flow 22. The first direction of flow 18 and the second direction of flow 19 preferably run parallel to the fourth direction of flow 21. The first direction of flow 18 is preferably opposite to the fourth direction of flow 21 and the second Flow direction 19 is preferably in the same direction as the fourth Flow direction 21, that is, the second flow direction 19 and the fourth flow direction 21 run in the same direction.

The fluid is introduced into the first channel 12 from the environment 10 via the inlet opening 9 . The fluid flowing through the first channel 12 in the first flow direction 18 is discharged from the first channel 12 and introduced into the first leg 3 . The fluid flowing through the first leg 3 in the third flow direction 20 is discharged from the first leg 3 and introduced into the web 5 . The fluid flowing through the web 5 in the fourth flow direction 21 is discharged from the web 5 and introduced into the second leg 4 . The fluid flowing through the second leg in the fifth flow direction 22 is discharged from the second leg 4 and introduced into the second channel 13 . The fluid flowing through the second channel 13 in the second flow direction 19 is discharged via the outlet opening 11 from the second channel 13 or the cooling device 1 and introduced into the environment 10 .

In a further embodiment, it is provided that the wall 14 is arranged between the channels 12 , 13 along a direction 23 running perpendicularly to the first and the second flow direction 18 , 19 . In other words, the first channel 12 is directly delimited by the wall 14 in a first direction 24 and the second channel 13 is directly delimited by the wall in a second direction 25, the first and the second direction 24, 25 each being along the Go towards 23. The first and the second direction 24, 25 run in opposite directions to one another. As a result, the installation space of the cooling device 1 can be kept particularly small.

4 and 5 show in respective schematic perspective views a first line element 26 of the cooling device 1 and a separately formed from the first line element 26, second line element 27 of the cooling device 1. The line elements 26, 27 are fluidically and mechanically connected to each other. The first line element 26 at least partially directly delimits the first channel 12 . The second line element 27 at least partially directly delimits the second channel 13 . The second line element 27 has the wall 14 . Accordingly, the first channel 12 is at least partially delimited directly by the first line element 26 and the second line element 27 and the second channel 13 is at least partially delimited by the second line element 27 and not directly delimited by the first line element 26 .

In the in the 4 and 5 shown embodiment, a side 28 of the first line element 26 facing the second line element 27 is open. This can in particular be understood to mean that no channel wall directly delimiting the fluid flowing through the first line element 26 is provided on the side 28 of the first line element 26 . The second line element 27 has a third passage opening 29 through which the fluid can flow, via which the first channel 12 and the partial region 2, in particular the first leg 3, are connected to one another fluidically, in particular directly. The fluid flowing through the first channel 12 can be discharged from the first channel 12 via the side 28 of the first line element 26 and the third passage opening 29 and introduced into the partial region 2 , in particular the first leg 3 . The second line element 27 has a fourth through-opening 30 through which the fluid can flow and which is spaced apart from the third through-opening 29 and via which the partial region 2, in particular the second leg 4, is fluidly connected, in particular directly, to the second channel 13. The fluid flowing through the partial area 2, in particular the second leg 4, can be discharged via the fourth passage opening 30 from the partial area 2, in particular the second leg 4, and introduced into the second channel 13.

The cooling device 1 or a, in particular lateral, water tank of the cooling device 1 is or is divided into two halves 31 , 32 by means of the second line element 27 . A first of the halves 31 includes the first channel 12 and the second of the halves 32 includes the second channel 13 and the partial area 2. This allows an internal fluid flow or water flow in the cooling device 1 or the water tank can be implemented.

The wall 14 is preferably formed in one piece. The second line element 27 is preferably designed in one piece. The first line element 26 is preferably formed in one piece. For example, the two line elements 26, 27 can be connected to one another by means of welding, in particular vibration welding.

The second line element 27 and the partial area wall 6 can be formed together in one piece or formed separately from one another and connected to one another. This can in particular be understood to mean that the second line element 27 and/or the first wall area 7 and/or the second wall area 8 can be formed together in one piece or can each be formed separately from one another.

In a further embodiment, it is provided that the inlet opening 9 extends in a first plane 33 and the outlet opening 11 in a second plane 34 that runs obliquely or perpendicularly to the first plane 33 . In other words, the fluid can flow through the inlet opening 9 in a first flow direction 35 and the fluid can flow through the outlet opening 11 from a second flow direction 36, with the first flow direction 35 running obliquely or perpendicularly to the second flow direction 36. The first flow direction 35 runs perpendicularly to the first plane 33 and the second flow direction 36 runs perpendicularly to the second plane 34. As a result, the fluid can be introduced particularly advantageously via the inlet opening 9 into the cooling device 1 and the fluid can particularly advantageously be introduced via the outlet opening 11 be discharged from the cooling device 1. For example, the installation space of the cooling device 1 can be kept particularly small.

In 1 and in 3 a second partial area 37 formed separately from the partial area 2 and through which the fluid can flow is shown. For example, the cooling device 1 can include the second partial area 37 . Alternatively, the second partial area 37 can be a partial area of a second cooling device that is configured separately from the cooling device 1 . The second partial area 37 has an opening 38 through which the fluid can flow, via which the fluid can be introduced from the surroundings 10 into the second partial area 37 and/or can be discharged from the second partial area 37, in particular to the surroundings 10.

It is also possible for the fluid to flow through the cooling device 1 in the opposite direction. This can in particular be understood to mean that the inlet opening 9 acts as an outlet and that the outlet opening 11 acts as an inlet. That is, the fluid can be discharged from the environment 10 via the outlet opening 11 and introduced into the second channel 13, wherein the fluid flowing through the second channel 13 can be discharged from the second channel 13 and into the partial region 2, in particular the second Leg 4 can be initiated. The fluid flowing through the partial area 2 can be discharged from the partial area 2, in particular the first leg 3, and introduced into the first channel 12, the fluid flowing through the first channel 12 being discharged via the inlet opening 9 from the cooling device 1, in particular the first channel 12, can be discharged and introduced into the environment 10.

Reference List

1

cooling device

1a

conventional cooling device

2

subarea

3

first leg

4

second leg

5

web

6

partition wall

7

first wall area

8th

second wall area

8a

first passage opening

8b

second passage opening

9

intake port

10

vicinity

11

exhaust port

12

first channel

13

two channel

14

wall

15

vehicle elevation

16

upper area

17

external line element

18

first direction of flow

19

second direction of flow

20

third direction of flow

21

fourth flow direction

22

fifth flow direction

23

Direction

24

first direction

25

second direction

26

first line element

27

second line element

28

Page

29

third passage opening

30

fourth through hole

31

first half

32

second half

33

first floor

34

second level

35

first flow direction

36

second flow direction

37

second section

38

opening

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102007043231 A1 [0002]

Claims (9)

Cooling device (1) for cooling at least one component of a motor vehicle, with at least one partial area (2) through which a fluid can flow in a U-shape, with at least one inlet opening (9) through which the fluid can flow, via which the fluid can be introduced into the partial area (2). and having at least one outlet opening (11) through which the fluid can flow, via which the fluid flowing through the partial area (2) can be removed from the cooling device (1), characterized by : - an outlet opening through which the fluid can flow and which is fluidically connected to the inlet opening (9 ) and the first channel (12) connected to the partial area (2), which is arranged downstream of the inlet opening (9) and upstream of the partial area (2) in the direction of flow of the fluid flowing through the cooling device (1), - a fluidic channel through which the fluid can flow second channel (13) connected to the partial area (2), the outlet opening (11) and the first channel (12), which in the direction of flow of the cooling device (1 ) fluid flowing through is arranged downstream of the partial region (2) and upstream of the outlet opening (11), and - a wall (14) common to the channels (12, 13) and at least partially directly delimiting the channels (12, 13). Cooling device (1) after claim 1 , characterized in that a first of the channels (12) along a first flow direction (18) and the second channel (13) along a second flow direction (19) can be flowed through by the fluid. Cooling device (1) after claim 2 , characterized in that the directions of flow (18, 19) run parallel to one another. Cooling device (1) after claim 2 or 3 , characterized in that the wall (14) is arranged between the channels (12, 13) along a direction (23) running perpendicularly to the flow directions (18, 19). Cooling device (1) according to one of the preceding claims, characterized in that the wall (14) is constructed in one piece. Cooling device (1) according to one of the preceding claims, characterized by: - A first line element (26) which at least partially directly delimits the first channel (12), and - A second line element (27) which is formed separately from the first line element (26) and is connected to the first line element (26) and at least partially directly delimits the second channel (13). Cooling device (1) after claim 6 , characterized in that the second line element (27) has the wall (14). Cooling device (1) according to one of the preceding claims, characterized in that the inlet opening (9) is in a first plane (33) and the outlet opening (11) is in a second plane ( 34) extends. Motor vehicle with a cooling device (1) according to one of the preceding claims.

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