DE102023202835A1 - Conduit device and conduit system for a vehicle and vehicle - Google Patents

Abstract

The invention relates to a line device (100) for conducting a fluid in a vehicle (400), wherein at least one first recess is formed on at least one first surface of the line device (100) in order to form a first channel, wherein the line device (100) can be arranged on a distributor device (200) and the distributor device (200) has at least one first and one second fluid interface (210) on a first distributor outer side of the distributor device (200), wherein the line device (100) can be arranged on the first distributor outer side in such a way that the first channel fluidically connects at least the first and second fluid interfaces (210) to one another.

Description

The invention relates to a line device and a line system for a vehicle and to a vehicle with such a line device and/or such a line system.

Vehicles have a coolant system for cooling and heating various units of the vehicle, by means of which a targeted fluid flow of a coolant to the various units is possible. For this purpose, the coolant system comprises a large number of coolant lines, valves for switching various coolant paths and one or more pumps for pumping the coolant. Such coolant systems also have a heat pump with heat exchangers, by means of which thermal energy can be exchanged between at least two coolant circuits of the coolant with different temperatures.

The valves and pumps have a large number of coolant interfaces in order to be able to switch the various coolant paths. In addition, lines are attached to the coolant interfaces, which are designed to guide the coolant to the various units and the heat pump. As a result, a complete structure of the coolant system is complex and time-consuming. In addition, installation space is required for the lines. Finally, maintaining this coolant system can prove to be time-consuming and costly, since if a line breaks and/or there is a leak, the corresponding line must first be identified in order to then replace it at great expense. Complex arrangements of the lines are often required, particularly when connecting the valves and pumps to the heat exchangers, which also increases the installation space for the connections of the valves, pumps and heat exchangers.

It is an object of the present invention to provide a piping device, a piping system and a vehicle that at least improves one or more of the aforementioned disadvantages. In particular, it is an object of the present invention to provide a space-saving piping device that already provides a corresponding fluid connection between the valves, pumps and heat exchangers at the manufacturer's site and reduces installation costs and maintenance costs.

The object is achieved according to a first aspect by a line device for conducting a fluid in a vehicle, wherein at least one first recess is formed on at least one first surface of the line device in order to form a first channel. The line device can be arranged on a distributor device, wherein the distributor device has at least one first and one second fluid interface on a first distributor outer side of the distributor device. The line device can be arranged on the first distributor outer side in such a way that the first channel fluidically connects at least the first and second fluid interfaces to one another.

The distributor device can have one or more valves and/or one or more pumps, each of which comprises fluid interfaces, in particular the first and second fluid interfaces. The fluid interfaces can in particular be designed to deliver and/or receive a fluid, in particular a cooling liquid. In order to connect these fluid interfaces to one another, the line device can be provided in which the first channel or several channels are already formed on the first surface. According to the present application, a channel can be understood as a recess or depression, which alone does not constitute a fluidically sealed connection between two fluid interfaces. Only by arranging the line device on the outside of the distributor can the first channel be covered at least in sections by the outside of the distributor, in particular a first distributor surface of the distributor device opposite the first surface. By covering it in this way, the channel can form a line in sections, in particular a fluidically sealed line. A line is characterized by a circumferential boundary along an intermediate line section, so that, for example, a fluid to be conducted by means of the line can only enter at a line inlet of the line and exit at a line outlet of the line. The intermediate line section connects the line inlet and the line outlet. The first and second fluid interfaces can be accommodated in the first channel, so that by arranging the line device on the distributor device by means of the channel, a fluidically sealing line can be formed between the first and second fluid interfaces. Alternatively or additionally, the fluid interfaces can be openings in the first distributor surface and the line device can be designed such that the openings face the first channel when the line device is arranged on the distributor device and are arranged at least partially overlapping with the first channel.

The at least one recess can be based on a predetermined arrangement of the two or more fluid interfaces and/or the dimensions solutions of the distributor device, in particular such that by means of the at least one channel the first and second fluid interfaces can be fluidically connected to one another when the line device is arranged on the distributor device.

A number of recesses, in particular channels and/or their arrangement, can be formed according to a number of fluid interfaces of the distributor device and/or their arrangement. Thus, a corresponding configuration for connecting the fluid interfaces can be provided during the manufacture of such a line device. This reduces the installation effort, susceptibility to errors during installation and maintenance effort. Furthermore, the space required for the connections of the fluid interfaces is also reduced, since no lines have to be connected. All that is required is the arrangement of the line device on the distributor device. In particular, with a plate-shaped design of the line device, a particularly space-saving connection of the fluid interfaces can be achieved.

The line device can be formed in one piece. The line device can comprise one or more metals and/or one or more plastics and/or consist of the one or more metals and/or the one or more plastics. The one or more metals can be aluminum and/or steel, in particular aluminum. The line device can be manufactured by means of a die-casting process, in particular a steel and/or aluminum die-casting process. The line device can be manufactured by means of a punching process, a milling process and/or a deep-drawing process of a metal body, in particular a metal plate and/or a plastic body. The metal body or the metal plate can consist of aluminum and/or steel or comprise aluminum and/or steel. The first channel, at least one further channel of the line device and/or at least one line of the line device can be formed by means of a punching process, a milling process and/or a deep-drawing process.

The line device can be arranged on the first distributor outer side in such a way that the first surface is opposite the first distributor surface. The first surface can in particular be designed to be complementary to the first distributor surface in sections in order to enable the channel to be sealed at least in sections by means of the distributor surface and the first and second fluid interfaces.

The first channel and/or each further channel can be designed such that when the line device is arranged on the distributor device, the first channel and/or each further channel can provide a fluidically sealing connection between the first and second fluid interfaces and/or further fluid interfaces.

Features relating to the first channel and the first recess may be embodied as features of further channels and further recesses.

The conduit device may have one or more apertures along one of the channels and/or one of the lines of the conduit device described below.

The first channel, in particular a channel depth and/or a channel width of the first channel running perpendicular to the channel depth, can be determined based on a target fluid flow and/or a target pressure of the fluid along the first channel in the arranged state. The fluid can flow along the first channel from the first fluid interface to the second fluid interface and/or vice versa, in particular depending on the switching of the valves. The channel depth can be formed parallel to a thickness direction defined below. In particular, the channel depth can characterize a depth of the recess relative to the first surface. The first channel can have a predetermined channel depth and/or a varying channel depth at least in sections. Additionally or alternatively, the first channel can have a predetermined channel width and/or varying channel width at least in sections, which extends along a longitudinal direction and/or width direction defined below. The channel width can run perpendicular to the channel width. The channel width can be 10 to 15 mm, in particular 12 mm. When arranging the line device on the distributor device, the first channel can form the line at least in sections. The line and/or each additional line and/or each additional channel of the line device can have a diameter of 10 to 15 mm, in particular 12 mm. Different sizes, dimensions and/or dimensions of the first and second fluid interfaces can be taken into account by means of the channel depth and/or the channel width. In particular, this makes it possible to fluidically connect several different fluid interfaces to the first channel. The target fluid flow and/or the target pressure can additionally or alternatively be controllable via the distributor device, in particular the one or more valves and/or the one or more pumps.

At least one second recess can be formed on the first surface of the line device in order to form a second channel. The distributor device can have at least one third fluid interface, wherein the line device can further be arranged on the first distributor outer side in such a way that the second channel fluidically connects at least the third fluid interface to the first channel. Consequently, a network of channels can be provided on the first surface in order to fluidically connect a plurality of fluid interfaces of the distributor device to one another.

The line device can further comprise at least one interface line, which has at least one line inlet and one line outlet on the first surface. An intermediate line section connecting the line inlet and the line outlet can be formed within the line device. The distributor device can have at least a fourth and a fifth fluid interface on the first distributor outside, wherein the line device can further be arranged on the first distributor outside such that the interface line fluidically connects the fourth and fifth fluid interfaces to one another. Accordingly, in addition to the first and/or second channel, a line can be provided which is formed at least in sections within the line device. The interface line can be characterized in that the interface line fluidically connects at least two fluid interfaces directly to one another.

The line device can further comprise at least one connecting line which is formed within the line device, in particular completely within the line device. The connecting line can be designed to fluidically connect the first channel, the second channel and/or the interface line and/or further channels and/or lines of the line device to one another.

The line device can further comprise at least one interface connection line, which has at least one line inlet on the first surface and a line outlet within the line device. The interface connection line can have an intermediate line section running from the line inlet to the line outlet, which is formed within the line device. The distributor device can have at least one sixth fluid interface on the first distributor outside, wherein the line device can further be arranged on the first distributor outside in such a way that the interface connection line fluidically connects the sixth fluid interface to the interface line and/or the connection line and/or at least one further line of the line device.

The line device can further comprise at least one supply line with at least one line inlet and one line outlet and an intermediate line section extending from the line inlet to the line outlet, which is formed within the line device. The line outlet of the supply line can be fluidically connected to a heat exchanger unit to be supplied with the fluid. The line inlet can be formed on the first surface or be fluidically connected to the first channel, the second channel, the interface line, the connecting line and/or the interface connecting line. The line device can further be arranged on the first distributor outside in such a way that the line inlet of the supply line fluidically connects a further fluid interface of the distributor device on the first distributor outside to the interface line and/or the connecting line and/or at least one further line of the line device.

The heat exchanger unit may be a unit of a heat pump, in particular of the vehicle. The heat exchanger unit may be one of a compressor, a condenser or an evaporator.

Consequently, by means of the interface line, the connecting line, the interface connecting line, the supply line and/or the first and/or second channels as well as further channels and/or lines of the line device, a predefined labyrinth of lines and channels can be provided, which replaces the individual lines used according to the prior art and connects the distributor device and the heat exchanger unit to one another in a particularly advantageous manner.

At least one third recess can be formed on at least one second surface of the line device, which is different from the first surface, in order to form a third channel. The distributor device can have at least one sixth fluid interface on a second distributor outer side of the distributor device, which is different from the first distributor outer side, wherein the line device can be arranged on the first distributor outer side and the second distributor outer side in such a way that the third channel fluidically connects at least the sixth fluid interface with the first channel, the second channel, the interface line and/or the connecting line. device. Accordingly, the distributor device can have a second distributor surface on the second distributor outer side and the second surface of the line device can be designed at least in sections such that, in the arranged state of the line device on the distributor device, it fluidically seals the third channel at least in sections and/or forms a line at least in sections.

Alternatively or additionally, the distributor device can have two or more fluid interfaces on the second distributor surface and the line device can have a fourth recess on the second surface to form a fourth channel. The line device can be arranged on the distributor device such that the fourth channel fluidically connects the two or more fluid interfaces on the second distributor surface. Alternatively or additionally, the line device can have at least one interface line, a connecting line, an interface connecting line and/or a supply line, which fluidically connect the fluid interfaces on the second distributor outside.

Consequently, the line device can be arranged on two or more distributor outer sides, in particular distributor surfaces of the distributor device, and fluidically connect corresponding fluid interfaces of the distributor device to one another.

The conduit device can be designed in the shape of a plate. In particular, the first surface can be arranged on a first side of the conduit device and a surface opposite the first surface can be arranged on a second side. The conduit device can have a predetermined plate thickness along the thickness direction, which extends perpendicular to the two surfaces. The channel depth can extend parallel to the thickness direction. The plate thickness can be smaller compared to a plate length and a plate width. The plate length can extend along the longitudinal direction and the plate width can extend along the width direction, wherein the longitudinal direction and the width direction extend perpendicular to one another. The longitudinal direction and the width direction can extend perpendicular to the thickness direction.

The line device can further comprise a plurality of channel plates that can be arranged on top of one another, in particular arranged on top of one another, with at least one first channel plate and one end channel plate. Each of the channel plates can have a first plate surface and a second plate surface opposite the first plate surface, and the first plate surface of the first channel plate can be the first surface. The first channel plate can have at least one first through-opening and/or a second through-opening. The plurality of channel plates, in particular the first channel plate and the end channel plate, can form the first recess, in particular the first channel, by means of the first through-opening and/or the second recess, in particular the second channel, by means of the second through-opening when arranged on top of one another.

At least one of the channel plates of the plurality of channel plates can be a channel plate that comprises steel, aluminum and/or a plastic or is made of steel, aluminum and/or a plastic. The at least one channel plate of the plurality of channel plates can be manufactured from a metal sheet or a plastic plate. The metal plate can be a steel and/or aluminum plate. The at least one channel plate of the plurality of channel plates can be formed by a or the punching process, a or the milling process and/or by a or the deep-drawing process. In particular, at least one opening of the at least one channel plate can be formed by the punching process, the milling process and/or the deep-drawing process.

The plurality of channel plates can at least partially have an identical length along the longitudinal direction, at least partially an identical width along the width direction and/or at least partially an identical thickness along the thickness direction. The plurality of channel plates can be arranged at least partially congruently with one another, so that they in particular completely overlap. The first and second plate surfaces of the plurality of channel plates can be arranged and/or aligned parallel to one another. The plurality of channel plates can be at least partially formed as one piece in order to form the line device at least partially as one piece, in particular completely. The end channel plate can be a continuous channel plate. By means of the end channel plate, the first and second through-openings can be delimited along the thickness direction on the second side of the first channel plate. The end channel plate can fluidically seal the first channel plate and/or a second channel plate described below and/or a channel plate of the plurality of channel plates opposite the end channel plate.

The plurality of channel plates may have at least the second channel plate with at least one third through-opening and the second channel plate can be arranged between the first channel plate and the end channel plate. Consequently, the plurality of channel plates can have one or more intermediate channel plates that can be arranged between the first channel plate and the end channel plate. The plurality of channel plates, in particular the first and second channel plates and the end channel plate, can form the connecting line in the arranged state by means of the third through-opening. Alternatively, the connecting line can be formed within the first channel plate and/or a further intermediate channel plate of the plurality of channel plates. Alternatively or additionally, further connecting lines can be formed that run within one or through several channel plates.

The first channel plate can have a fourth and a fifth through-opening and the second channel plate can have a sixth through-opening. The plurality of channel plates, in particular the first channel plate, can form the line inlet and the line outlet of the interface line in the arranged state by means of the fourth and fifth through-openings. The plurality of channel plates, in particular the first and second channel plates and the end channel plate, can form the line intermediate section of the interface line in the arranged state by means of the sixth through-opening. Consequently, the line intermediate section of the interface line can be formed within the second channel plate. In the case of several channel plates, the line intermediate section of the interface line can extend through two or more channel plates and/or be formed by through-openings of the two or more channel plates.

If the plurality of channel plates comprises three or more channel plates, the intermediate line section of the interface line can run through at least one or more of the channel plates, in particular the intermediate channel plates. Consequently, the line inlets and outlets can be formed by the through openings of the first channel plate, while one or more through openings of the intermediate plates form the intermediate line section.

The first channel plate can have a sixth and a seventh through opening which form the line inlet and the line outlet of the interface line. The second channel plate and/or further channel plates, excluding the end channel plate, can have one or more through openings to form the line intermediate section of the interface line.

The first channel plate may have an eighth through-opening that forms the line inlet of the interface connection line. The second channel plate and/or one or more intermediate channel plates may have one or more through-openings to form the line intermediate section and the line outlet of the interface connection line. The line outlet of the interface connection line may be fluidically connected to the interface line.

The line inlet of the supply line can be formed by means of a through-opening of one of the plurality of channel plates. The line intermediate section can be formed by the same through-opening and/or by one or more further through-openings of the plurality of channel plates. Furthermore, the end channel plate can have a through-opening which forms the line outlet of the supply line.

Each of the plurality of channel plates may represent a line level and within each line level one or more channels and/or the lines mentioned above and below may be formed.

Additionally or alternatively, one or more channels, line inlets and/or line outlets can be formed on at least one further surface of the line device, in particular the plurality of channel plates, which is different from the first and/or second surface. This further surface can be a surface which extends parallel to the thickness direction.

Line inlets and line outlets can define respective end sections of a line. They can define a flow direction from the line inlet to the line outlet, whereby flow in the opposite direction may also be possible. This can depend in particular on a circuit of the valves and the pump.

The object is achieved according to a second aspect by a line system for a vehicle, comprising a line device according to the first aspect and at least one of a distributor device and a heat exchanger unit. A second surface of the line device, which is different from the first surface, can be arranged on the heat exchanger unit. The line device can be and/or form a wall, in particular an outer wall of the heat exchanger unit. The distributor device comprises one or more valves and/or one or more pumps and the valve(s) and/or the pump(s) have at least the first and second fluid interfaces, wherein the first and second fluid interfaces are arranged on the first distributor outer side. The line device can be arranged on the first distributor outer side such that the first channel fluidically connects at least the first and second fluid interfaces to one another.

Accordingly, a piping system is provided that provides a space-saving and low-installation fluidic connection between the piping device and the distribution device and/or the heat exchanger unit, which also has a low maintenance effort.

Previously described features of the conduit device according to the first aspect can be implemented as features of the conduit system according to the second aspect and vice versa.

The first and second surfaces of the conduit device, the distributor surfaces of the distributor device and/or a wall surface of the outer wall of the heat exchanger unit can be formed at least partially parallel to one another.

The distributor device can comprise at least one or more valve housings for accommodating the one or more valves and/or one or more pump housings for accommodating the one or more pumps. The pump housing or a pump housing of the multiple pump housings can each accommodate at least one pump. The valve housing or a valve housing of the multiple valve housings can each accommodate a single valve. The first distributor outer side can be an outer side of the valve housing(s) and/or the pump housing(s), wherein the valve housing(s) and/or the pump housing(s) are formed integrally with the conduit device. The fluid interfaces can be arranged at least partially on the first distributor outer side.

The valve housings and/or the valves may comprise one or more slide valves.

The distribution device may comprise two or more pumps, in particular two pumps. The two pumps may be accommodated in a single pump housing.

The valve housings and/or the pump housing(s) can be cylindrical in shape, at least in sections.

The conduit device may extend with a predetermined length along the longitudinal direction, with a predetermined width along the width direction and/or with a predetermined thickness along the thickness direction.

The outer surface of the first distributor outer side can extend at least in sections within a plane that is spanned by the longitudinal and width directions and is thus aligned perpendicular to the thickness direction. Accordingly, the distributor surface of the first distributor outer side can be aligned parallel to the first surface in the arranged state of the distributor device on the line device.

The fluid interfaces of the distributor device can be arranged at least partially on the outer surface of the first distributor outer side.

The distributor device can have a front surface with further fluid interfaces on a front side of the distributor device, wherein the front surface is oriented differently to the distributor surface of the first distributor outer side, in particular perpendicular to it. Accordingly, the line device can be designed in such a way that fluid interfaces on the front side can also be fluidically connected to one or more channels and/or lines, as previously described with regard to the first distributor outer side. For example, the line device can have an L-shaped form for this purpose.

The line system can further comprise at least one covering device that can be arranged on the first surface of the line device and is designed to cover the line device at least in sections, in particular such that the line device can be arranged on the first distributor outside and the first channel fluidically connects at least the first and second fluid interfaces to one another in the arranged state. The covering device can have one, in particular two, through openings for the first and second fluid interfaces. The two through openings can be arranged based on the arrangement of the first recess, in particular the first channel, and designed such that the two through openings fluidically connect the first and second fluid interfaces to the first channel. The covering device can be plate-shaped. The covering device can be designed to form the first channel as a line by covering this section at least in sections. The covering device can further be designed to cover the second and each further recess at least in sections and can additionally or alternatively have further through openings for the respective channels and fluid interfaces.

The outer wall of the heat exchanger unit can extend at least in sections along the width and length direction. The outer wall of the heat exchanger unit can be and/or form an outer surface of the heat exchanger unit at least in sections.

The covering device can further comprise one or more fluid interface connections. The fluid interface connections can be arranged and designed such that they can accommodate the first and second fluid interfaces and/or can be fluidically connected to them. The fluid interface connections can extend away from the covering device. The fluid interface connections can be designed in the form of elevations.

Accordingly, the piping system can comprise the heat exchanger unit, wherein the piping device forms an outer wall and/or at least partially a housing of the heat exchanger unit.

The piping device, the distribution device, the heat exchanger unit and/or the covering device can be formed in one piece.

The object is achieved according to a third aspect by a vehicle comprising a line device according to the first aspect and/or a line system according to the second aspect.

The vehicle can comprise a semi-automatic, in particular a fully automatic transmission. The vehicle can be an at least partially autonomous and/or at least partially electrically driven vehicle. The vehicle can comprise a heat pump with the heat exchanger unit.

• 1 eine Draufsicht auf eine Leitungsvorrichtung mit vier Kanalplatten;
• 2 eine seitliche Ansicht der Kanalplatten;
• 3 eine Draufsicht einer Verteilervorrichtung mit einer Pumpe und drei Ventilen;
• 4 eine seitliche Ansicht der an der Verteilervorrichtung angeordneten Leitungsvorrichtung;
• 5 zeigt eine Draufsicht der an der Verteilervorrichtung angeordneten Leitungsvorrichtung;
• 6 eine seitliche Ansicht eines Leitungssystems; und
• 7 ein Fahrzeug mit einem Leitungssystem.

Preferred embodiments are explained using the accompanying figures. They show:

• 1 a plan view of a duct device with four channel plates;
• 2 a side view of the channel plates;
• 3 a plan view of a distribution device with a pump and three valves;
• 4 a side view of the line device arranged on the distribution device;
• 5 shows a plan view of the line device arranged on the distributor device;
• 6 a side view of a piping system; and
• 7 a vehicle with a piping system.

In the figures, identical or essentially functionally identical or similar elements are designated by the same reference numerals. The proportions shown in the figures serve primarily to facilitate understanding of the invention and do not restrict the invention to these.

1 shows a plan view of first to fourth channel plates 110-140 of a line device 100 for conducting a fluid in a vehicle 400. The fourth channel plate 140 can be an end channel plate. The line device 100 is described below in the form of the one arranged on top of the other, in particular according to 2 arranged channel plates 110-140. However, the line device 100 is not limited to this form. The plate-shaped design of the line device 100 can represent an advantageous embodiment of the line device 100.

The first to fourth channel plates 110-140 each have first and second plate surfaces, wherein in the 1 the first plate surface of the channel plates 111-140 is visible and the second plate surface is opposite the first plate surface. The first and second plate surfaces each extend in planes which are spanned by a width in a width direction BR and a length in a longitudinal direction LR. The width direction BR runs perpendicular to the longitudinal direction LR. Furthermore, the first to fourth channel plates 110-140, as in 2 has a predetermined thickness along a thickness direction DR which is perpendicular to the width direction BR and the longitudinal direction LR.

The first channel plate 110 has through holes 111-115, wherein the through holes 111 to 113 are connected to each other. The through holes 114, 115 are square, but are not limited to this. The through hole 111 extends with a predetermined length along the longitudinal direction LR and has a predetermined width along the width direction BR, which is smaller than the predetermined length. The through holes 112, 113 extend with a predetermined width along the width direction BR and a predetermined length along the longitudinal direction, wherein the predetermined width is greater than the predetermined length. According to the 1 the through holes 111-113 can form a double-T shape. The predetermined width of the through hole 111 is smaller than the predetermined width of the through holes 112, 113 and the predetermined length of the through hole 111 is greater than the predetermined length of the through holes openings 112, 113. The through openings 111 to 113 can alternatively be defined as a single through opening.

The second channel plate 120 has two through openings 121, 122, wherein the two through openings 121, 122 have a length and a width that corresponds to a length and a width of the through openings 114, 115.

The through openings 111-115, 121, 122, 131 are shown as examples and are not restricted to this shape. The through openings 111-115, 121, 122, 131, in particular the inner contours of the through openings 111-115, 121, 122, 131 can alternatively or additionally be designed to be arcuate at least in sections. The through openings 121, 122 are arranged in such a way that when the first channel plate 110 is arranged on the second channel plate 120, they are at least partially, in particular completely, congruent with the through openings 114, 115.

Furthermore, the third channel plate 130 has a further through-opening 131, which has the same width as the through-openings 114, 115. Furthermore, the through-opening 131 has a length which, when the first channel plate 110 is arranged on the second channel plate 120, corresponds to at least a length of a connection along the longitudinal direction from the through-opening 114 to the through-opening 115.

By arranging the first and second channel plates 110, 120 on top of each other, the through openings 111-113 form first to third channels which are fluidically connected to each other.

The through openings 111-115, 121, 122, 131 can be milled, punched out and/or drilled. Alternatively or additionally, the through openings 111-115, 121, 122, 131 can be formed during manufacture of the channel plates 110-140.

2 shows a side view and the arrangement of the channel plates 110-140 according to the arrows shown, such that they completely overlap. The arrangement creates an overall body of the line device 100. The channel plates 110-140 can be welded to one another or can already be manufactured as one piece.

By arranging the channel plates 110-140 on top of one another, the through openings 114, 115 can form an interface line with the through openings 121, 122 and the through opening 131. The interface line is characterized in that a line inlet and a line outlet are formed on the first plate surface of the first channel plate 110, here through the through openings 114, 115 of the first channel plate 110 and the through openings 121, 122 of the second channel plate 120. An intermediate line section, which fluidically connects the line inlet and the line outlet, is formed by the through opening 131.

The line device 100 may further comprise at least one connecting line (not shown). The connecting line may be formed within the line device 100, for example in the form of a through-opening in the third channel plate 130. The connecting line is characterized in that it provides a fluidic connection between one or more channels and/or one or more lines of the line device 100, such as the interface line.

Furthermore, the line device 100 can comprise at least one interface connection line (not shown). The interface connection line has a line inlet on the first surface. The line inlet of the interface connection line can be designed in the form of a through-opening of the first channel plate 110. The remaining part of the interface connection line is designed within the line device 100, comprising a line outlet and an intermediate line section connecting the line inlet and the line outlet of the interface connection line. The line outlet can be fluidically connected to at least one interface line and/or connection line of the line device 100.

Furthermore, the line device 100 can comprise at least one supply line. A line outlet of the supply line can be fluidically connected to a heat exchanger unit 300 described below, in particular one or more fluid interfaces of the heat exchanger unit 300. An intermediate line section of the supply line connecting a line inlet and the line outlet can be formed within the line device 100. For example, the line inlet of the supply line can be fluidically connected to an interface line and/or a channel of the line device 100. Alternatively, the line inlet of the supply line can be formed on the first surface and can be fluidically connected to a fluid interface 210.

By means of the channels, the interface line, the connecting line, the interface connection Complex line systems can be provided by combining the power line and the supply line, which can be arranged on the distributor device 100 in a space-efficient and simple manner. The design of the through-openings for the channels and lines of the line device 100 can be prefabricated as required.

3 shows a top view of a distributor device 200 with a pump housing P and first to third valve housings V1-V3. The pump housing P comprises two pumps which are designed to pump the fluid, in particular a cooling liquid. The first to third valve housings V1-V3 each comprise a valve, in particular a slide valve. Furthermore, the pump housing P has two fluid interfaces 210 and each of the first to third valve housings V1-V3 has four fluid interfaces 210. By means of the plurality of fluid interfaces 210, fluid flows within the housings P, V1-V3 can be switched such that the fluid flows in and/or out through one or more fluid interfaces 210.

Advantageously, the 3 shown distributor outer side has the fluid interfaces 210 on and/or on a first distributor surface of the first distributor outer side, wherein the first distributor surface has a width along the width direction and a length along the longitudinal direction. Alternatively or additionally, the distributor device 200 can have at least one or more distributor outer sides that are different from the first distributor outer side. The shown embodiment of the arrangement of the line device 100 on the distributor device 200, as in 4 shown, shows a fluidic connection of several fluid interfaces 210 of the distributor outside of the 3 However, in the case of an at least partially different design of the line device 100, further fluid interfaces located on the further distributor outer surface(s) and/or distributor outer sides can be fluidically connected.

4 shows a side view and the line device 100 arranged on the distributor device 100. As in the 4 As shown, the distributor device 200 has a predetermined thickness along the thickness direction DR. Furthermore, in the 4 shown that the first distributor surface is advantageously parallel to the first plate surface. Accordingly, a fluidic seal can be provided by arranging the first plate surface on the first distributor surface. The fluid can flow between one or more of the fluidically connected fluid interfaces 210 only through the through openings 111-115, 121, 122, 131.

5 shows a top view of the line device 100 arranged on the distributor device 200, wherein the through openings 111-115, 131 within the overall structure of the distributor device 200 and the line device 100 are indicated by dashed lines. The fluid interfaces 210 are indicated by dotted lines.

As in the 5 As shown, the line device 100 can be arranged on the distributor device 200 such that the through openings 111-113, 114, 115 are located opposite predetermined fluid interfaces 210 of the distributor device 200. The 5 The column of fluid interfaces 210 on the right is only partially opposite the through openings 111, 115. The fluid interfaces 210 arranged between a first and a last row of the fluid interfaces 210 of the third valve housing V3 are fluidically sealed by the first channel plate 110. Consequently, not all fluid interfaces 210 have to be connected. Depending on requirements, two or more fluid interfaces 210 can be fluidically connected. The through openings 121, 122 are in the 5 not shown, since they overlap with the through openings 114, 115 in the plan view.

As from the 5 As can be seen, several channels and lines can be formed by means of the through openings 111-115, 131 (121, 122 not shown) of the first to third channel plates 110-130. In particular, the through openings 111-113 form respective channels by being arranged on the second channel plate 120. Furthermore, these channels are formed into lines at least in sections by arranging the line device 100 on the distributor device 200, since the channels on the first plate surface of the first channel plate 110 are spatially delimited by the opposite first distributor surface.

Accordingly, the line device 100 can be used to provide lines for fluidically connecting a large number of fluid interfaces 210 in a particularly space-saving and simple manner.

6 shows a side view of a line system with the line device 100, the distributor device 200 and a heat exchanger unit 300. The heat exchanger unit 300 can be a unit of a heat pump, in particular of a vehicle 400. The heat exchanger unit 300 can be a compressor. For this purpose, the line device 100 can form a wall, in particular an outer wall of the compressor 300 or can be arranged on an outer surface of the compressor 300. By means of the 6 The arrangement shown can be a particularly space-saving and easy connection of the distribution device 200 to the compressor 300.

The line device 100 can additionally comprise a covering device (not shown). The covering device can at least partially cover the line device 100, in particular the first channel plate 110. The covering device can be designed to cover the first surface of the line device 100 in such a way that the channel or channels, in particular the through openings 111-115 of the first channel plate 110, are at least partially covered. Accordingly, the through openings 111-115 can be fluidically sealed at least in sections by means of the covering device and/or form lines. The covering device can further have two or more openings which are designed so that when the line device 100 is arranged on the distributor device 200, the respective fluid interfaces 210 to be fluidically connected can be fluidically connected to the respective channels of the line device 100, in particular the through openings 111-115.

7 shows a vehicle 400, in particular with a fully automatic transmission, comprising a line device 100, a distributor device 200 and a heat exchanger unit 300 for regulating and switching a fluid flow of a fluid for heating and/or cooling one or more units of the vehicle 400.

reference sign

100

line device

110

first channel plate

111-115

through holes of the first channel plate

120

second channel plate

121, 122

through holes of the second channel plate

130

third channel plate

131

through hole of the third channel plate

140

end channel plate

BR

latitude direction

DR

thickness direction

LR

longitudinal direction

200

distribution device

210

fluid interfaces

P

pump housing

V1

first valve housing

V2

second valve housing

V3

third valve housing

300

heat exchanger unit

400

vehicle

Claims (15)

Conduit device (100) for conducting a fluid in a vehicle (400), wherein at least one first recess is formed on at least one first surface of the conduit device (100) in order to form a first channel, wherein the conduit device (100) can be arranged on a distributor device (200) and the distributor device (200) has at least one first and one second fluid interface (210) on a first distributor outer side of the distributor device (200), wherein the conduit device (100) can be arranged on the first distributor outer side in such a way that the first channel fluidically connects at least the first and second fluid interfaces (210) to one another. Line device (100) according to Claim 1 , wherein the first channel, in particular a channel depth and/or a channel width running perpendicular to the channel depth, are determined based on a desired fluid flow and/or a desired pressure of the fluid along the first channel in the arranged state. Conduit device (100) according to one of the preceding claims, wherein at least one second recess is formed on the first surface of the conduit device (100) in order to form a second channel, wherein the distributor device (200) has at least one third fluid interface (210), wherein the conduit device (100) can further be arranged on the first distributor outer side in such a way that the second channel fluidically connects at least the third fluid interface (210) to the first channel. Conduit device (100) according to one of the preceding claims, further comprising: at least one interface line, which has at least one line inlet and one line outlet on the first surface, wherein an intermediate line section connecting the line inlet and the line outlet is formed within the conduit device, wherein the distributor device (200) has at least a fourth and a fifth fluid interface (210), wherein the conduit device (100) can further be arranged on the first distributor outside such that the interface line has the fourth and fifth Fluid interfaces (210) fluidically interconnected. Conduit device (100) according to one of the preceding claims, further comprising: at least one connecting line formed within the conduit device (100), wherein the connecting line is designed to fluidically connect the first channel, the second channel and/or the interface line to one another. Conduit device (100) according to one of the preceding claims, further comprising: at least one interface connection line having at least one line inlet on the first surface and one line outlet within the conduit device (100), wherein the distributor device has at least one sixth fluid interface (210), wherein the conduit device (100) can further be arranged on the first distributor outside such that the interface connection line fluidically connects the sixth fluid interface to the interface line and/or the connection line. Conduit device (100) according to one of the preceding claims, further comprising: at least one supply line with at least one line inlet and one line outlet and an intermediate line section extending from the line inlet to the line outlet, which is formed within the conduit device (100), wherein the line outlet of the supply line is fluidically connectable to a heat exchanger unit (300) to be supplied with the fluid, wherein the line inlet is formed on the first surface or is fluidically connected to the first channel, the second channel, the interface line, the connecting line and/or the interface connecting line. Conduit device (100) according to one of the preceding claims, wherein the conduit device (100) is plate-shaped. Conduit device (100) according to one of the preceding claims, further comprising: a plurality of channel plates (110-140) which can be arranged on top of one another, with at least one first channel plate (110) and one end channel plate (140), wherein each of the channel plates (110-140) has a first plate surface and a second plate surface opposite the first plate surface and the first plate surface of the first channel plate (110) is the first surface, wherein the first channel plate (110) has at least one first through-opening (111) and/or a second through-opening (112, 113), wherein the plurality of channel plates (110-140), in particular the first channel plate (110) and the end channel plate (140), in a state arranged on top of one another, form the first recess, in particular the first channel, by means of the first through-opening (111) and/or the second recess, in particular the form a second channel. Line device (100) according to claim 9 , wherein the plurality of channel plates (110-140) has at least one second channel plate (120) with at least one third through-opening and the second channel plate (120) can be arranged between the first channel plate (110) and the end channel plate (140), wherein the plurality of channel plates (110-140), in particular the first and second channel plates (110, 120) and the end channel plate (140) in the arranged state form the connecting line by means of the third through-opening. Line device (100) according to claim 9 or 10 , wherein the first channel plate (110) has a fourth and a fifth through-opening and the second channel plate (120) has a sixth through-opening, wherein the plurality of channel plates (110-140), in particular the first channel plate (110), in the arranged state, form the line inlet and the line outlet of the interface line by means of the fourth and fifth through-openings, wherein the plurality of channel plates (110-140), in particular the first and second channel plates (110, 120) and the end channel plate (140), in the arranged state, form the line intermediate section of the interface line by means of the sixth through-opening. Line system for a vehicle (400), comprising: a line device (100) according to one of the preceding claims; at least one of a distributor device (200) and a heat exchanger unit (300), wherein a second surface of the line device (100) different from the first surface can be arranged on the heat exchanger unit (300), wherein the distributor device (200) comprises one or more valves and/or one or more pumps and the valve(s) and/or the pump(s) have at least the first and second fluid interfaces (210), wherein the first and second fluid interfaces (210) are arranged on the first distributor outside, wherein the line device (100) is arranged on the first distributor outer side, such that the first channel fluidically connects at least the first and second fluid interfaces (210) with one another. piping system according to claim 12 , further comprising: a covering device which can be arranged on the first surface of the line device (100) and is designed to cover the line device (100) at least in sections, in particular such that the line device (100) can be arranged on the first distributor outer side and the first channel fluidically connects at least the first and second fluid interfaces to one another. Pipe system according to one of the Claims 12 or 13 , wherein the line device (100), the distributor device (200), the heat exchanger unit (300) and/or the cover device are formed in one piece. Vehicle (400) comprising a line device (100) according to one of the Claims 1 until 11 and/or a piping system according to one of the Claims 12 until 14 .

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