DE102022201308A1 - Temperature control arrangement, in particular for a vehicle seat of a motor vehicle - Google Patents

Abstract

The invention relates to a temperature control arrangement (1) with a base body (4) having an upper side (2) and an underside (3), comprising a base body material. The arrangement (1) comprises at least one thermoelectric device (5) arranged in or on the base body (4), which has a primary side (6) and a secondary side (7) and a plurality of thermoelectrically active elements (8) for heat transport between the primary side (6) and secondary side (7). The arrangement (1) comprises at least one heat-conducting device (9) arranged in the base body (4), comprising at least one heat-conducting element (10), preferably at least two heat-conducting elements, which are used for heat transport between the at least one thermoelectric device (5) and the upper side (2). and/or underside (3) of the base body (4). Furthermore, the arrangement (1) comprises at least one base body fluid path (20) guided through the base body (4) and opening into the top side (2) of the base body (4) for guiding air (L) from the top side (2) of the base body (4) to the bottom (3).

Description

The invention relates to a temperature control arrangement, in particular for a vehicle seat of a motor vehicle and a vehicle seat with such a temperature control arrangement.

Seat surfaces of vehicle seats in modern motor vehicles are often temperature-controlled using cooled or heated air. In such conventional temperature control arrangements, however, guiding the air to the seat surface or away from the seat surface usually proves to be technically relatively complex and therefore expensive to produce.

It is therefore an object of the present invention to show new ways in the development of technically simple and therefore inexpensive temperature control arrangements.

This object is solved by the subject matter of the independent patent claims. Preferred embodiments are subject matter of the dependent patent claims.

The basic idea of the invention is therefore to control the temperature of a surface, in particular of a vehicle seat, not exclusively - as explained above - with the help of air, but also to control the temperature with the help of a thermoelectric device, which has a mechanically flexible heat-conducting device with at least one heat-conducting element made of a heat-conducting material thermally connected to said surface. This material is particularly preferably a metal, so that the mechanically flexible heat-conducting element can be formed by metallic threads or metallic wires. The thermoelectric device forming the heat source or heat sink can thus be arranged at a distance from the temperature control arrangement, since the thermal coupling can take place via one or more such heat-conducting elements. If the surface to be temperature-controlled is a seat surface of a vehicle seat, the arrangement of the typically mechanically rigid thermoelectric device at a distance from the seat surface in conjunction with the mechanically flexible heat-conducting element can result in an undesirable reduction in seating comfort, as is the case with a direct arrangement of the thermoelectric device could occur on the seat surface can be counteracted.

Irrespective of this, the heat-conducting element presented here, which is essential to the invention, enables a flexible transition from a more punctiform heat source or heat sink—the thermoelectric device—towards surface cooling.

A temperature control arrangement according to the invention comprises a base body which has an upper side and an underside opposite the upper side. The base body comprises a preferably flexible base body material or consists of such a preferably flexible base body material. The arrangement also comprises at least one thermoelectric device arranged in or on the base body, which comprises a primary side and a secondary side and at least one thermoelectrically active element, preferably at least two thermoelectrically active elements, particularly preferably several thermoelectrically active elements, for heat transport between the primary side and the secondary side. In addition, the arrangement comprises at least one heat-conducting device arranged in the base body. A heat conducting device is preferably provided for each existing thermoelectric device. The at least one heat conducting device in turn comprises at least one mechanically flexible heat conducting element, preferably at least two heat conducting elements, particularly preferably a plurality of heat conducting elements, and is designed for heat transport between the associated thermoelectric device and the top and/or bottom of the base body. The thermally conductive element comprises a thermally conductive material or consists of a thermally conductive material. The material is preferably a metal.

For temperature control or cooling of the upper side of the base body, heat can thus first be transported from there by means of the heat conducting device to the primary side of the associated thermoelectric device.

If the thermoelectric device is arranged completely within the base body, the heat transported from the primary side to the secondary side can then be transported further to the underside of the base body by means of a further heat conducting device and released there to the surroundings of the base body.

If at least the secondary side of the thermoelectric device is arranged directly on the underside of the base body or even outside of the base body, the heat transported by the at least one thermoelectric device from the primary side to the secondary side of the thermoelectric device can be emitted from the secondary side directly to the surroundings of the secondary side and thus be discharged from the base body.

For additional temperature control or cooling of the upper side, the temperature control arrangement presented here includes, according to the invention, at least one guided through the base body and into the upper Side of the base body opening base body fluid path for guiding air from the top of the base body to the bottom or vice versa from the bottom to the top of the base body.

The thermoelectric device may be or may include a Peltier element. As already explained, such a Peltier element can comprise one, two or more thermoelectrically active elements, each made of a p-doped or n-doped semiconductor material such as bismuth telluride (Bi2Te3) or silicon germanium (SiGe). These thermoelectrically active elements can be electrically connected to one another—preferably electrically connected in series—in a conventional manner by electrically conductive bridges made of an electrical conductor, in particular a metal. Said metal bridges can then alternately form a hot side or a cold side of the Peltier element, ie in the present case the primary side or secondary side of the thermoelectric device. The Peltier element can expediently have two plates, each made of a ceramic, in particular an aluminum oxide ceramic, in the known manner, between which said thermoelectrically active elements are arranged, expediently soldered.

The Peltier element can expediently have a lateral area extension of between 10 mm×10 mm and 20 mm×20 mm. Of course, other dimensions are also conceivable in variants.

The exact structural or technical structure of the Peltier element is not the core of the present invention and is familiar to the relevant person skilled in the art, so that further explanations regarding the technical structure of the Peltier element are dispensed with.

It goes without saying, however, that the arrangement described here can have not only a single thermoelectric device or a single Peltier element, but also two or more thermoelectric devices or Peltier elements. If the temperature control arrangement comprises two or more thermoelectric devices, then according to the invention there is at least one heat conducting device for each thermoelectric device.

According to a preferred embodiment of the invention, the at least one base body fluid path is spatially separated from the at least one heat conducting device, preferably arranged at a distance from the at least one heat conducting element of the heat conducting device in the base body. In this way it can be ensured that the heat transport via the heat conducting device can take place independently and without interference from the heat transport of the air guided through the fluid path. As a result, this leads to improved efficiency with regard to the heat transport that can be achieved in the arrangement away from the upper side of the base body.

According to an advantageous development, the at least one base body fluid path, preferably by means of thermal insulation, is arranged thermally separated from the at least one heat conducting element of the heat conducting device in the base body. This also prevents unwanted thermal contact between the heat-conducting device and the fluid path.

The thermal insulation can particularly expediently be formed by an insulation layer, in particular made of a foam material, and—alternatively or additionally—by the material of the base body.

According to an advantageous development, the arrangement comprises a heat exchanger arranged at least in sections on the secondary side of the at least one thermoelectric device. This heat exchanger comprises at least one heat exchanger fluid path through which air can flow for the purpose of transferring heat between the thermoelectric device, in particular its secondary side, and the air. Said heat exchanger thereby allows an effective dissipation of the heat provided on the secondary side of the thermoelectric device. In particular, an undesired heating of the secondary side is counteracted in this way.

The at least base body fluid path expediently communicates fluidly with the heat exchanger fluid path. This allows the heat transported by the heat conducting device via the at least one thermoelectric device to its secondary side to be dissipated to the same medium that is also used for direct cooling of the upper side of the seat body, namely through the base body fluid path and then through the heat exchanger Fluid path guided air. This significantly increases the efficiency of the heat transport compared to conventional arrangements.

According to an advantageous development, the at least one base body fluid path opens out with an upper end facing away from the heat exchanger fluid path in an upper path opening arranged on the upper side of the base body. Air from the vicinity of the upper side can be introduced into the base body fluid path via this path opening. This leads to an effective cooling of the upper side of the base body. self rep It is also conceivable to provide warm air via the base body fluid path at the top if the top of the base body is to be heated.

According to a further advantageous development, the at least one base body fluid path opens out with an end facing away from the upper side in a lower path opening arranged on the underside of the base body. Air from the at least one base body fluid path can be introduced into the heat exchanger in a technically simple manner via this lower path opening. This makes it possible, without major technical effort, to use the air - as already mentioned - as a medium which also absorbs the heat provided by the heat exchanger.

The at least one heat conducting device is particularly expediently arranged/embedded in the material of the base body and surrounded directly by the base body material of the base body. In this way, the heat-conducting element of the heat-conducting device is protected from damage or even destruction. Furthermore, effective heat transport is ensured if a material with low thermal conductivity and/or heat capacity is selected as the base body material. The effect of this is that the heat is transported with little loss by means of the heat conducting device from the top side of the base body to the thermoelectric device and by means of this further to the bottom side of the base body. An undesired heating of the base body is thus counteracted.

The at least one base body fluid path is preferably realized by an air channel formed in the base body material of the base body. The provision of separate duct materials for delimiting the air duct can thus be dispensed with, because in this embodiment the base body material, ie for example an airtight foam, takes over this function. This variant is accompanied by not inconsiderable cost advantages in the production of the arrangement.

According to a further advantageous development, an additional heat conducting device for heat transport between the at least thermoelectric device and the air guided through the heat exchanger fluid path is arranged between the secondary side and the heat exchanger fluid path. This measure also improves the removal of heat from the top of the base body.

According to another advantageous development, a rib structure is arranged in the heat exchanger fluid path in the area of the secondary side of the thermoelectric device or the (additional) heat conducting device. This rib structure is set up to improve the heat transport between the air guided through the heat exchanger fluid path and the at least one thermoelectric device.

According to a further preferred embodiment, the arrangement can comprise a fan which communicates fluidically with the heat exchanger fluid path in order to draw in the air from the heat exchanger fluid path or from the base body fluid path. In this way, the air intake from the upper side of the base body can be improved and the cooling effect achieved can be increased.

A cover can expediently be arranged on the upper side of the base body. In this way, the top of the base body can be protected against dirt and damage or the like. If the temperature control arrangement is used to control the temperature of a vehicle seat, the cover can be a seat cover, in particular a leather cover or fabric cover. In this case, the cover is used to increase seating comfort. The covering can also function as a design element.

According to an advantageous development, the temperature control arrangement has two or more thermoelectric devices, with at least one heat-conducting device as described above being present for each thermoelectric device. In this way, even large-area temperature control arrangements can be effectively temperature controlled, in particular cooled.

The at least two thermoelectric devices can expediently be electrically connected to one another, preferably electrically connected in parallel or electrically connected in series. This simplifies the electrical wiring of the temperature control arrangement according to the invention and the electrical energization of the thermoelectric devices.

The at least one thermoelectric device particularly preferably comprises or is a Peltier element. Such Peltier elements are commercially available in various technical configurations, so that they can be selected by a person skilled in the art for the temperature control arrangement according to the invention in an application-specific manner and easily integrated into the arrangement.

According to an advantageous development between the secondary side and the heat transmitter an additional heat conducting device, comprising at least one additional heat conducting element, to be arranged for heat transport between the at least one thermoelectric device and the heat exchanger. In this way, the thermal coupling between the heat exchanger and the thermoelectric device can be improved. The additional heat-conducting device can be designed in the same way as the previously explained (non-additional) heat-conducting device, so that the above explanations for the heat-conducting device also apply mutatis mutandis to the additional heat-conducting device.

According to a preferred embodiment, the at least one heat conducting device is surrounded directly by the base body material. Particularly preferably, the heat conducting device can be embedded in the base body material. If a material with low thermal conductivity and low heat capacity, such as a foam, is used as the base body material, this ensures that a large part of the heat absorbed from the top is effectively transported to the associated thermoelectric device and via this to the bottom from the base body is carried away.

According to a preferred embodiment, the at least one heat conducting device thermally connects the primary side of the thermoelectric device to the upper side of the base body. Alternatively or additionally, the heat conducting device can thermally connect the secondary side of the thermoelectric device to the underside of the base body. Depending on the position of the at least one thermoelectric device in the base body, in this embodiment the heat conducting device can also thermally connect the secondary side of the associated thermoelectric device to the underside of the base body if the thermoelectric device is arranged within the base body at a distance from its underside. In this way, heat can be effectively transported from the top to the bottom of the base body, regardless of the position of the thermoelectric device in or on the base body.

The at least one thermoelectric device is expediently arranged within the base body. This design requires particularly little space. As an alternative to this, however, the thermoelectric device can also be arranged outside of the base body. This design is particularly easily accessible for a worker, especially if, for example, repairs to the thermoelectric device should be necessary. It is also conceivable, in a further development, that at least one thermoelectric device is arranged inside the base body and at least one further thermoelectric device is arranged outside of the base body.

The at least one thermoelectric device is particularly preferably arranged within the base body at a distance from the upper side and/or from the underside of the base body. As an alternative to this, the thermoelectric device can be arranged on the upper side or underside of the base body. Depending on the application, the thermoelectric device can therefore be arranged at almost any position in or on the base body. This increases the flexibility when integrating further components into the base body that are not part of the arrangement according to the invention.

An embodiment in which a lateral extent of the upper element section along the upper side is greater than a lateral extent of the lower element section along the primary side of the thermoelectric device has proven to be particularly advantageous. In this way, a larger lateral extent of the top side of the base body can be thermally coupled to the primary side of the thermoelectric device, which has a smaller lateral extent.

According to a further preferred embodiment, the heat conducting device can taper from the upper side of the base body towards the at least one thermoelectric device. As a result, a greater lateral extension of the upper side of the base body can be thermally effectively coupled to the primary side of the thermoelectric device, which has a smaller lateral extension.

According to a preferred embodiment, the at least one heat conducting device extends at least with an upper end section over the entire upper side of the base body. In this way it is prevented that individual areas of the upper side cannot be covered by the desired temperature control.

According to another preferred embodiment, the at least one heat-conducting element of the at least one heat-conducting device is formed at least in sections by threads and/or wires, each made of a metal. Particularly preferably, the threads or wires can be twisted together at least in sections and/or fanned out in sections without twisting.

According to another preferred embodiment, the threads or wires of the at least one heat-conducting element of the at least one heat-conducting device can at least form a fabric in sections. In this case, the threads or wires form the warp and weft threads of this fabric. The entire at least one heat-conducting element can preferably be designed as a fabric. This particularly preferably applies to two or more or even all heat-conducting elements of the at least one heat-conducting device. In all variants, the design as a fabric enables a particularly homogeneous temperature control of the entire upper side of the base body.

According to an advantageous development, the fabric in a longitudinal section of the arrangement comprises an upper element section arranged on the upper side of the base body, which is connected via a middle element section extending through the base body to a lower element section of the fabric arranged on the underside of the base body.

According to an advantageous development, the fabric in a longitudinal section of the arrangement has a U-shaped geometry with two U-legs and a U-base connecting the two U-legs. In this further development, a first leg of the U comprises the upper section of the element and a second leg of the U comprises the lower section of the element and the base of the U comprises the middle section. Such a U-shaped geometry allows a space-saving thermal connection of the primary side of the thermoelectric device to the upper side of the base body.

According to another advantageous development, the fabric can have an H-shaped geometry with two H-legs and an H-base connecting the two H-legs in a longitudinal section of the arrangement. Such an H-shaped geometry enables the entire primary side of the thermoelectric device to be connected to the entire upper side of the base body over the entire surface via the heat-conducting device in a simple manner. Correspondingly, a planar thermal connection to the upper side of the base body is possible by means of the upper element section. Since the central element section requires only little installation space in the lateral direction, ie perpendicular to the heat transport direction, these areas of the base body are available for other applications or technical components.

The threads or wires particularly preferably extend without being twisted from the primary side of the thermoelectric device to the upper side of the base body.

The material of the base body can expediently be a foam or comprise a foam. Since foam is a flexible material, this makes it easier to integrate the various components, such as the thermoelectric device and heat-conducting device, into the base body.

Alternatively or additionally, the base body can comprise or be a support structure, preferably made of mechanically stiff support elements, particularly preferably made of mechanically stiff threads. In this variant, the heat-conducting element of the at least one heat-conducting device is arranged between the support structure or its support elements. In this way, high mechanical stability can be ensured for the base body, even if the heating element is designed to be mechanically flexible. The material of the support elements is expediently a plastic.

The invention also relates to a vehicle seat for a motor vehicle, comprising a seat bottom and a seat back. The vehicle seat also includes a previously explained temperature control arrangement according to the invention, wherein the base body is at least part of the seat bottom and/or the seat back. The advantages of the arrangement according to the invention explained above are therefore also transferred to the vehicle seat according to the invention.

The temperature control arrangement according to the invention presented above can not only, as described above, be installed in the seat bottom or in the seat back of a vehicle seat, but also—if present—in a headrest of the vehicle seat.

Provision of the temperature control arrangement according to the invention in other components of the motor vehicle is also conceivable. In particular, a center armrest, a door inner lining, a hand steering wheel and a vehicle roof, in particular a headliner, of the motor vehicle come into consideration for this purpose. A selector lever present in the vehicle interior for controlling the motor vehicle and a dashboard, in particular an instrument panel, can also be equipped with the temperature control arrangement according to the invention.

Furthermore, the temperature control arrangement according to the invention can be provided not only in a vehicle seat, but in principle in any seat, in particular for any means of transportation. In all of these variants, an arrangement of the temperature control arrangement on the seat bottom, on the backrest and on any headrest that is present is conceivable in a manner analogous to the vehicle seat.

A use of the temperature control arrangement according to the invention other than in vehicle applications is also conceivable. In particular, applications of the erfindungsge are conceivable moderate temperature control arrangement in the home and in buildings, preferably on a chair or on a handle, especially on a door or window handle.

Finally, an application of the temperature control arrangement according to the invention in building interiors is also conceivable, for example on a wall delimiting the respective interior at the side and on a ceiling delimiting the interior at the top. In particular, the temperature control arrangement can be arranged on or in wallpaper covering the wall.

Further important features and advantages of the invention result from the dependent claims, from the drawing and from the associated description of the figures with reference to the drawings.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description, with the same reference numbers referring to identical or similar or functionally identical components.

• 1 ein Beispiel einer erfindungsgemäßen Temperier-Anordnung;
• 2a-2k beispielhaft verschiedene Ausgestaltungsvarianten der erfindungswesentlichen Wärmeleiteinrichtung;
• 3a-3d beispielhaft Varianten der Anordnung der 1 unter Berücksichtigung der möglichen Ausgestaltung der Wärmeleiteinrichtung gemäß 2.

They show, each schematically:

• 1 an example of a temperature control arrangement according to the invention;
• 2a-2k examples of different design variants of the heat-conducting device that are essential to the invention;
• 3a-3d exemplary variants of the arrangement of 1 taking into account the possible design of the heat conducting device according to 2 .

1 shows a schematic representation of an example of a temperature control arrangement 1 according to the invention. This comprises a base body 4 having an upper side 2 and a lower side 3 and made of a flexible base body material. The upper side 2 faces the lower side 3 along a heat transport direction W. The heat transport direction W extends in the direction of a normal vector of a plane (not shown in the figures) which extends parallel to the upper side 2 and/or the lower side 3 .

Furthermore, the arrangement 1 comprises a thermoelectric device 5 arranged on the base body 4 and having a primary side 6 and a secondary side 7 and a plurality of thermoelectrically active elements (not shown) for transporting heat between the primary side 6 and the secondary side 7 . The primary side 6 faces the secondary side along the heat transport direction W. FIG. The primary side 6 faces the underside 3 .

The thermoelectric device 5 can be or comprise a Peltier element. Such a Peltier element can include said thermoelectrically active elements, for example made of a p-doped and n-doped semiconductor material such as bismuth telluride (Bi2Te3) or silicon germanium (SiGe) (in 1 not shown in detail). These thermoelectrically active elements can be electrically connected to one another in a conventional manner by electrically conductive conductor bridges made of an electrical conductor, in particular a metal. Said conductor bridges can then alternately form a hot side and a cold side of the Peltier element, in the present case the primary side 6 or secondary side 7 of the thermoelectric device 5.

Expediently, said Peltier element can have, in a known manner, two plates made of a ceramic, in particular an aluminum oxide ceramic, between which said thermoelectrically active elements and the conductor bridges can be arranged and expediently soldered.

Particularly expediently, the Peltier element can have a lateral extent of between 10 mm×10 mm and 20 mm×20 mm. Of course, other dimensions are also conceivable.

The detailed technical design of the Peltier element that can be used for the present invention is not the core of the present invention and is familiar to the relevant person skilled in the art, so that further explanations of the technical design of such a Peltier element are dispensed with.

It goes without saying that the arrangement described here can have not only a single thermoelectric device 5 or a single Peltier element, but can have two thermoelectric devices 5 and 5 or Peltier elements.

A heat-conducting device 9 of the arrangement 1 is also arranged in the base body 4 . If the arrangement 1 comprises two or more thermoelectric devices 5, then at least one individual heat-conducting device 9 is provided for each thermoelectric device 5. The heat-conducting device 9 comprises at least one mechanically flexible heat-conducting element 10, which is used for transporting heat between the thermoelectric device 5 and the Top 2 and / or bottom 3 of the base body 4 are set up. The heat is thus transported essentially along the heat transport direction W. The heat-conducting element 10 can also extend at an angle to the heat-conducting direction W.

The heat conducting device 9 is arranged in the base body material of the base body 4 or embedded in it and is therefore directly surrounded by this base body material. The material of the thermally conductive element 10 is expediently a thermally conductive material. A metal, for example copper, is preferably suitable for this purpose. The material of the base body 4 can preferably be a foam. Furthermore, the arrangement 1 in the example of 1 several base body fluid paths 20 each guided through the base body 4 and opening into the top side 2 of the base body 4 for conducting air L from the top side 2 of the base body 4 to its underside 3 or in the opposite direction, i.e. from the bottom 3 to the top 2.

As 1 illustrated, the base body fluid paths 20 are spatially separated from the heat conducting device 9 and arranged at a distance from the heat conducting element 10 of the heat conducting device 9 in the base body 4 . Furthermore, the arrangement 1 comprises a heat exchanger 21 arranged in sections on the secondary side 7 of the thermoelectric device 5 for transferring heat between the thermoelectric device 5 and the air L. The heat exchanger 21 has a heat exchanger fluid path 22 through which air L can flow.

In addition, the base body fluid paths 20 can be arranged in the base body 4 by means of thermal insulation, thermally separated from the heat conducting elements 10 of the heat conducting device 9 . It can be formed by the material of the base body, ie a foam. As an alternative to this - especially if the material of the base body 4 is not foam, the thermal insulation can be formed by a thermal insulation layer (not shown in the figures), preferably made of a foam or another material, in particular with a lower thermal conductivity than the material of the base body be.

The base body fluid paths 20 communicate according to FIG 1 all fluidly connected to the heat exchanger fluid path 22. The base body fluid paths 20 can each be realized by an air duct 28 formed in the material of the base body 4. In this case, the air ducts 28 or the base body fluid paths 20 are delimited directly by the material of the base body 4--for example said foam. The base body fluid paths 20 each open with an upper end 23 facing away from the heat exchanger fluid path 20 in a respective upper path opening 24 arranged on the top side 2 of the base body 4, via which air L from the environment 25 of the top side 2 into the respective base body fluid path 20 can be introduced or sucked in. The base body fluid paths 20 open with a common lower end 26 facing away from the upper side 2 in a lower path opening 27 arranged on the underside 3 of the base body 4, via which air L is transported from the base body fluid paths 20 into the respective heat exchanger fluid path 22 can be. As already mentioned, the air can also be transported in the opposite direction, ie from the lower path opening 27 into the upper path openings 24 .

As 1 can also be seen, between the secondary side 7 of the thermoelectric device 5 and the heat exchanger fluid path 22 of the heat exchanger 21, an additional heat conducting device 29 for heat transport between the thermoelectric device 5 and the air L guided through the heat exchanger fluid path 22 can be arranged. The additional heat-conducting device 29 can be constructed in exactly the same way as the heat-conducting device 9 in the base body 4 and can thus comprise a plurality of heat-conducting elements 30 . The above explanations for the heat-conducting device 9 therefore also apply, mutatis mutandis, to the additional heat-conducting device 29. Optionally, such an additional heat-conducting device 29 can be provided for each heat-conducting device 9 present in the base body 4.

In the heat exchanger fluid path 22, a rib structure (not shown) can also be arranged in the area of the secondary side 7 of the thermoelectric device 5 or the additional heat conducting device 29 to improve the heat transport between the air L guided through the heat exchanger fluid path 22 and the thermoelectric device 5 .

In the example scenario, the arrangement 1 also includes a blower 31 which communicates fluidly with the heat exchanger fluid path 22 in order to suck in the air L from the heat exchanger fluid path 22 or from the base body fluid path 20 . The blower 31 can expediently be arranged downstream of the heat exchanger 21 .

A covering 8 can expediently be arranged on the upper side 2 of the base body 4 . In this way, the top 2 of the base body 4 can be protected against dirt and damage or the like. The covering 8 can comprise one or more cover layers. For example, a two-layer construction is conceivable Build with a top layer of leather and a bottom layer of foam.

the 2a until 2k show various possible configurations for the heat-conducting device 9 with the heat-conducting element(s) 10.

the 2a until 2k show the base body 4 with the thermoelectric device 5 in a roughly schematic and greatly simplified representation and in a longitudinal section along the heat transport direction W. The different variants can be combined with one another where this makes sense. If two or more heat conducting devices 9 are provided (not shown in the figures), they can be designed identically or also differently according to the different variants.

In the example of 2a until 2e the heat-conducting elements 10 are formed by wires 12 or threads, each made of a metal.

In the example of 2a For example, the single heat-conducting device 9 comprises only a single heat-conducting element 10 made from wires or threads twisted together. In this case, a lateral extension of the heat-conducting element 10 along the top side 2 is greater than a lateral extension of the same heat-conducting element 10 along the primary side 6 of the thermoelectric device 5. In this way, a larger lateral extension of the top side 2 of the base body 4 can be thermally connected to the smaller lateral extension having primary side 6 of the thermoelectric device 5 are coupled.

In the example of 2 B includes the heat conducting 9 example, not only a single heat conducting element 10, but two adjacent heat conducting elements 10, each heat conducting element 10 as above with reference to 2a explained can be formed. The two heat-conducting elements 10 can be arranged at a distance from one another. It goes without saying that in developments of the example, the heat-conducting device 9 can also have three or more such heat-conducting elements 10 .

In the example of 2a and 2 B the two heat-conducting elements 10 extend essentially along the heat transport direction W and thus realize the shortest possible connection between the top 2 and bottom 3 of the base body 4.

2c shows a variant of the example 2a , In which the - only - heat conducting element 10 at a - preferably acute - angle α relative to the heat transport direction W of the thermoelectric device 5 to the top 2 extends. Such an angular arrangement makes it possible to thermally connect the thermoelectric device 5 via the heat conducting device 9 to any lateral area of the upper side 2, in principle.

Of course, a combination of the example of 2c with that of 2 B imaginable.

In the example of 2d includes the heat-conducting device 9 in turn only a single heat-conducting element 10. In the example of 2d the heat-conducting element 10 is divided into a first element section 11a and a second element section 11b with respect to the heat transport direction W. The two element sections 11a, 11b merge into one another in the direction W of heat transport. The first element portion 11a faces the primary side 6 of the thermoelectric device 5 . The second element section 11 b faces the upper side 2 of the base body 4 . In the first element section 11a, the wires or threads 12 are twisted together. In the second element section 11b, the wires or threads are not twisted together, but fanned out towards the upper side 2 without twisting. By dividing the thermally conductive element 10 in sections into the fanned-out second elemental section 11b and a first elemental section 11a of the wires 12 or threads twisted together, a tapering of the thermally conductive element 10 from the upper side 2 to the underside 3 is realized. In this way, a greater lateral extension of the top side 2 of the base body 4 can be thermally effectively coupled to the primary side 6 of the thermoelectric device 5, which has a smaller lateral extension. Also in the example of 2d - as well as in the examples of 2a until 2c - A lateral extent of the heat-conducting element 10 along the top side 2 is therefore greater than a lateral extent of the same heat-conducting element 10 along the primary side 6 of the thermoelectric device 5.

2e shows a variant of the example 2d . In the example of 2e is opposite to the example of 2d the heat-conducting element 10 is not formed by fanned out threads or wires 12 that are not twisted together, but by a fabric 13 made of the threads or wires 12. The threads or wires 12 form the warp and weft threads (in 2e not shown) of the fabric 13 at least partially.

The heat conducting device 9 thus includes in the example 2e a first element section 11a, in which the heat-conducting element 10 is formed as twisted threads and/or wires 12, and a second element section 11b, in which the heat-conducting element 10 are designed as a fabric 13 . The threads or wires 12 twisted in the first element section 11a thus merge into the warp and weft threads of the fabric 13 towards the upper side 2 . Such a fabric 13 arranged in the area of the upper side 2 allows a particularly homogeneous temperature control of the upper side 2. Alternatively, the fabric 13 with its warp and weft threads can also be formed separately from the heat-conducting element 10 and be thermally conductively connected to it. A suitable material connection, in particular an adhesive connection or a welded connection, can be used for this purpose.

Also the examples of 2c until 2e can use the example of 2 B be combined, ie it is possible even in the examples of 2c until 2e to provide a heat conducting device 9 associated with a respective thermoelectric device 5, each having two or more heat conducting elements 10.

the 2f until 2i show further examples in which the heat conducting element 10 is formed by fabric 13 made of threads or wires 12, which thus form the warp or weft threads (not shown) of the fabric 13.

In the example of 2f In the longitudinal section of the arrangement 1 shown, the fabric 13 along the heat transport direction W comprises an upper element section 14o arranged on the upper side 2 of the base body 4, which has a central element section 14m extending through the base body 4 with an element section 14m arranged on the underside 3 of the base body 4 lower element portion 14u of the fabric 13 is connected.

As 2f illustrated, the upper element section 14o extends laterally, that is to say perpendicularly to the heat transport direction W, over the top side 2 of the base body 4 . Correspondingly, the lower element section 14u extends laterally across the primary side 6 of the thermoelectric device 5 . The central element section 14m connects the upper element section 14o to the lower element section 14u and extends thereto along the heat transport direction W. The fabric 13 thus has an H-shaped geometry in the longitudinal section shown with two H-legs 16a, 16b and one of the two H- legs connecting H-base 16c. The upper element section 14o forms a first H-leg 16a, the lower element section 14u forms a second H-leg 16b. The middle element section 14m forms the H base 16c.

The H-shaped geometry shown allows an effective connection of the entire primary side 6 of the thermoelectric device 5 via the heat conducting device 9 to the entire upper side 2 of the base body 4. Using the upper element section 14o, a planar thermal connection to the upper side 2 of the base body 4 is accordingly possible . Since the central element section 14m requires only little installation space in the lateral direction, i.e. perpendicular to the heat transport direction W, these areas of the base body 4 are available for other applications or technical components, in particular for the 1 Base body fluid paths 20 shown are available.

the 2g shows a variant of the example 2f . In the example of 2g the tissue 13 in the longitudinal section shown does not have an H-shaped geometry as in the example in FIG 2f , but a U-shaped geometry. This means that the fabric 13 has, as shown, two U-legs 15a, 15b and a U-base 15c connecting the two U-legs 15a, 15b. In a manner analogous to the H-shaped geometry of the 2 forms in the example 2g a first U-leg 15a the upper element section 14o and a second U-leg 15b the lower element section 14u. Said U-base 15c forms the central element section 14m. Also said U-shaped geometry allows a space-saving thermal connection of the primary side 6 with the top 2, in an analogous manner, for example 2f .

the 2h shows another variant of the examples 2f and 2g . Also in the example of 2h the heat-conducting element 10 of the heat-conducting device 9 is formed by a fabric 13, with the wires or threads 12 of the heat-conducting element 10 forming the warp and weft threads of the fabric.

As 2h can be seen, the upper element portion 14o of the fabric 13 extends only partially over the top 2 of the base body 4 away. Likewise, the lower element section 14u only partially extends over the primary side 6 of the thermoelectric device 5 . With respect to a lateral direction LR perpendicular to the heat transport direction W, the upper element section 14o and the lower element section 14u of the fabric 13 made of the threads or wires 12 are arranged on opposite end sections 37a, 37b of the upper side 2 and lower side 3, respectively. The middle panel portion 14m is disposed at an obtuse angle β to both the top panel portion 14o and the bottom panel portion 14u. by means of the in 2h In the variant shown, lateral sections of the top side 2 and the bottom side 3 lying opposite one another in relation to the lateral direction LR can be effectively thermally connected to one another.

the 2i shows a simplified variant of the examples according to FIG 2f until 2h . Also in the example of 2i the heat-conducting element 10 of the heat-conducting device 9 comprises a fabric 13 made of warp and weft threads, which are formed by the wires or threads 12 of the heat-conducting element 10 . In the example of 2i is contrary to the example 2f until 2a the thermoelectric device 5 is arranged within the base body 4, specifically in the area of the upper side 2 of the base body. This enables a simplified construction of the fabric 13 since the central element section 14m and the lower element section 14u can be omitted.

The fabric 13 is in the example 2i arranged exclusively in the area of the upper side 2 and extends along the lateral direction LR over the entire upper side 2 of time. The heat-conducting element 10 or fabric 13 touches the primary side 6 of the thermoelectric device 5 with its fabric underside 13u in the region of a lateral contact section 13k.

the 2y and 2k show two further embodiment variants of the heat-conducting device 9, in which the heat-conducting element 10 has threads or wires 12 which are arranged without twisting and at a distance from one another. In both examples, the wires extend from the primary side 6 of the thermoelectric device 5, which is arranged outside the base body 4 on its underside 3, through the base body 4 to the top side 2 of the base body 4.

In the example of 2y the individual threads or wires 12 extend essentially along the heat transport direction W. In contrast, the heat conducting device 9 or the heat conducting element 9 formed by the threads 12 tapers in the longitudinal section shown from the top 2 of the base body 4 to the primary side 6 of the thermoelectric device 5 or to the underside 3 of the base body 4 - in the example of 2y and 2k the bottom 3 and the primary side 6 fall together - down. As a result, in the example of 2k a larger lateral area of the upper side 2 of the base body 4 is thermally connected to the primary side 6 of the thermoelectric device 5 via the heat conducting device 9 than in the example of FIG 2y .

In both variants, i.e. both in the example of 2y as well as in the example of 2k , In addition to the threads 12 in the base body 4, a support structure 18 made of metallic threads 19 is arranged. In contrast to the threads 12 of the heat-conducting device 9, these metallic threads 19 are not used for heat transfer, but for mechanical reinforcement of the base body 4. For this purpose, the metallic threads 19 of the support structure 18 form a so-called spacer fabric. The support structure 18 expediently extends along the heat transport direction W and also laterally across the entire base body 4 .

Based on the rough schematic representation of 3a until 3d Below are different variants of the example 1 explained, which differ from one another in particular with regard to preferred positions of the thermoelectric device 5 in or on the base body 4 .

The configuration of the explained below 3a until 3b can, as far as makes sense, with those of 2a until 2k be combined.

In the example of 3a the thermoelectric device 5 is arranged outside of the base body 4 and is arranged with its primary side 6 lying against its underside 3 . The thermoelectric device 5 is arranged with its primary side 6 without a gap on the underside 3 of the base body. In other words, the primary 6 and the bottom 3 fall in 3a together.

The already based on the 1 The additional heat-conducting device 29 explained with additional heat-conducting elements 30 is arranged between the secondary side 7 of the thermoelectric device 5 and the heat exchanger fluid path 22 of the heat exchanger 21 . Like the thermoelectric device 5 , the additional heat-conducting device 29 is arranged outside of the base body 4 and at a distance from the base body 4 .

The variant of 3b differs from the example of 3a in that the thermoelectric device 5 is arranged inside the base body 4 .

In the example of 3b the underside 3 of the base body 4 and the secondary side 7 of the thermoelectric device 5 coincide. In the example of 3b the additional heat-conducting device 29 with the additional heat-conducting elements 30 rests on the underside 3 of the base body 4 and thus also on the secondary side 7 of the thermoelectric device. The additional heat conducting device 29 is also in the example 3b as in the example 3a arranged outside of the base body 4 .

In the 3c The variant shown differs from the example 3b is that the thermoelectric device 5 is arranged within the base body 4, both at a distance from the top 2 and the bottom 3. In the example of 3c is also the one in the 3a and 3b shown additional heat conducting device 29 not necessary. In contrast, in the example 3c the heat conducting device 9 is designed with two heat conducting elements 10 in such a way that one of the two heat conducting elements 10 thermally connects the primary side 6 of the thermoelectric device 5 to the upper side 2 of the base body 4 and the other heat conducting element 10 thermally connects the secondary side 7 of the thermoelectric device 5 to the underside 3 of the Base body 4 connects. In the example of 3c the heat exchanger 21 rests with the heat exchanger fluid path 22 on the underside 3 of the base body 4 so that the secondary side 7 of the thermoelectric device 5 is thermally connected to the heat exchanger 21 via the heat conducting device 9 .

In the example of 3d is the thermoelectric device 5 also within the base body 4, but contrary to the example 3c arranged adjacent to the top 2 of the base body 4 . The primary side 6 of the thermoelectric device 5 and the top 2 of the base body 4 thus fall in the example 3d together.

In the example of 3d connects the heat conducting device 9 with the heat conducting element 10, the secondary side 7 of the thermoelectric device 5 with the underside 3 of the base body 4. Also in the example of 3d is the heat exchanger 21 - in an analogous manner, for example 3c - With the heat exchanger fluid path 22 on the underside 3 of the base body 4, so that the secondary side 7 of the thermoelectric device 5 is thermally connected to the heat exchanger 22 via the heat conducting device 9. In the example of 3d the heat conducting device 9 connects the secondary side 7 of the thermoelectric device 5 to the underside 3 of the base body 4 and thus also to the heat exchanger 21.

In the example of 3c the heat conducting device 9 connects both the top 2 of the base body 4 to the primary side 6 of the thermoelectric device 9 and the secondary side 7 of the thermoelectric device 5 to the bottom 3 of the base body 4 and thus also to the heat exchanger 21. In the example of 3b connects the heat conducting device 9, the top 2 of the base body 4 with the primary side 6 of the thermoelectric device 5. In the example of 3a the heat conducting device 9 connects the upper side 2 of the base body 4 to the underside 3 of the base body 4 and thus also to the primary side 6 of the thermoelectric device 5.

Claims (17)

Temperature control arrangement (1), in particular for a vehicle seat of a motor vehicle, - With a base body (4) having an upper side (2) and an underside (3), comprising a preferably flexible base body material or consisting of a preferably flexible base body material; - having at least one thermoelectric device (5) arranged in or on the base body (4), which has a primary side (6) and a secondary side (7) and at least one thermoelectrically active element (8), preferably at least two thermoelectrically active elements (8), particularly preferably comprises a plurality of thermoelectrically active elements (8) for transporting heat between the primary side (6) and the secondary side (7); - with at least one heat-conducting device (9) arranged in the base body (4), comprising at least one mechanically flexible heat-conducting element (10), comprising a heat-conducting material or consisting of a heat-conducting material, particularly preferably a metal, the heat-conducting device (9) for heat transport between the at least one thermoelectric device (5) and the top (2) and/or bottom (3) of the base body (4) is formed; - With at least one through the base body (4) guided and in the top (2) of the base body (4) opening base body fluid path (20) for discharging a fluid, in particular air (L), from the top (2) of the base body ( 4), preferably to the underside (3) of the base body (4). Tempering arrangement according to claim 1 , characterized in that the at least one base body fluid path (20) is arranged spatially separated from the at least one heat conducting device (9), preferably at a distance from the at least one heat conducting element (10) of the heat conducting device (9), in the base body (4). Tempering arrangement according to claim 1 or 2 , characterized in that the at least one base body fluid path (20), preferably by means of thermal insulation, thermally separated from the at least one heat conducting element (10) of the heat conducting device (9) is arranged in the base body (4). Tempering arrangement according to claim 3 , characterized in that the thermal insulation is formed by a thermal insulation layer, in particular made of a foam, the thermal conductivity of the material of the thermal insulation being preferably smaller than the thermal conductivity of the material of the base body. Temperature control arrangement according to one of the preceding claims, characterized in that the arrangement (1) at least in sections on the secondary side (7) of the at least one thermoelectric device (5) arranged heat exchanger (21), which comprises at least one heat exchanger fluid path (22) through which air (L) can flow for transferring heat between the secondary side (7) of the thermoelectric device ( 5) and the air (L); or/and that the at least base body fluid path (20) communicates fluidly with the heat exchanger fluid path (22). Temperature control arrangement according to one of the preceding claims, characterized in that the at least one base body fluid path (20) with an upper end (23) facing away from the heat exchanger fluid path (20) in a on the upper side (2) of the base body (4) arranged upper path opening (24) opens, via which air (L) from the environment (25) of the upper side in the base body fluid path (20) can be introduced; or/and that the at least one base body fluid path (20) opens with a lower end (26) facing away from the upper side (2) in a lower path opening (27) arranged on the underside (7) of the base body (4), via which Air (L) can be introduced from the at least one base body fluid path (20) into the heat exchanger fluid path (22). Temperature control arrangement according to one of the preceding claims, characterized in that the at least one heat conducting device (9) is arranged/embedded in the base body material of the base body (4) and/or is directly surrounded by this base body material. Temperature control arrangement according to one of the preceding claims, characterized in that the at least one base body fluid path (20) is realized by an air duct (28) present in the base body material of the base body (4). Temperature control arrangement according to one of the preceding claims, characterized in that between the secondary side (7) and the heat exchanger fluid path (22) an additional heat conducting device (29) for heat transport between the at least one thermoelectric device (5) and through the heat exchanger Fluid path (22) guided air (L) is arranged. Temperature control arrangement according to one of the preceding claims, characterized in that in the heat exchanger fluid path (22) in the area of the secondary side (7) of the at least one thermoelectric device (5) or the additional heat conducting device (29) a rib structure to improve the heat transport between the air guided through the heat exchanger fluid path (22) and the at least one thermoelectric device (5). Temperature control arrangement according to one of the preceding claims, characterized in that the arrangement (1) comprises a fan (31) which is used to suck in the air (L) from the heat exchanger fluid path (22) or from the base body fluid path (20 ) communicates fluidly with the heat exchanger fluid path (22). Temperature control arrangement according to one of the preceding claims, characterized in that a cover layer (8) is arranged on the upper side (2) of the base body (4). Temperature control arrangement according to one of the preceding claims, characterized in that the temperature control arrangement (1) has two or more thermoelectric devices (5), a heat conducting device (8) being present for each thermoelectric device (5). Tempering arrangement according to Claim 13 , characterized in that the at least two thermoelectric devices (5), preferably electrically connected in parallel or electrically connected in series, are electrically connected to one another. Temperature control arrangement according to one of the preceding claims, characterized in that the at least one thermoelectric device (5) comprises or is a Peltier element. Tempering arrangement according to one of claims 3 until 15 , characterized in that between the secondary side (7) and the heat exchanger (21) an additional heat conducting device (29), comprising at least one additional heat conducting element (30), for heat transport between the at least one thermoelectric device (5) and the heat exchanger (21) is arranged. vehicle seat for a motor vehicle, - With a temperature control arrangement (1) according to any one of the preceding claims, - With a seat bottom and a seat back; - Wherein the base body is at least part of the seat bottom and/or the seat back.

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