DE102022205266A1 - Holding device for a vehicle interior trim part - Google Patents

Abstract

A holding device for a vehicle interior trim part is proposed, the holding device comprising a base integrated in the vehicle interior trim part with a receptacle for reversibly partially receiving a carrier module, which is accommodated or receivable in the receptacle so as to be rotatable about an axis of rotation. The base and the carrier module each comprise at least two magnets, which are arranged in the base and in the carrier module such that the magnetic dipole vector of at least one of the respective at least two magnets is substantially antiparallel to the magnetic dipole vector of at least one other of the respective at least two magnets and in Essentially parallel to the axis of rotation. In a release position of the carrier module about the axis of rotation, the carrier module is arranged in the receptacle relative to the base in such a way that the base and the carrier module magnetically repel each other, and in a holding position of the carrier module about the axis of rotation, the carrier module is arranged in the receptacle relative to the base in such a way that that the base and the carrier module magnetically attract each other. Furthermore, the holding device comprises a locking mechanism for locking the carrier module in the holding position, wherein the locking mechanism comprises an actuating element for releasing the locking from the holding position.

Description

The present property right relates to a holding device for a vehicle interior trim part, in particular a holding device that is at least partially integrated into a vehicle interior trim part. The holding device can be designed to provide a modular, interchangeable arrangement of optionally retrofittable vehicle interior elements, such as cup holders, storage boxes or holders for cell phones and other mobile devices.

In the interior of a vehicle, there is a fundamental need to arrange or be able to arrange vehicle interior trim elements, in particular functional vehicle interior trim elements, such as cup holders, storage boxes or storage compartments or cell phones and other mobile devices. Typical elements of this type are known in the prior art as holders provided with suction cups, holders that can be attached to air outlet devices of the air conditioning system, but also as storage boxes or cup holders integrated into the interior lining.

However, the aforementioned elements known from the prior art have numerous disadvantages. For example, devices that are already integrated into the interior are fundamentally severely limited locally and functionally. Attachable mobile mounts can be more versatile, but are often unstable and therefore prone to rattling noises while driving. In addition, mobile holders can disrupt the vehicle ventilation as well as the overall aesthetic and/or tactile impression and can pose a safety risk due to their generally inadequate fastening stability. Furthermore, mobile holders in particular can rarely be attached easily or even with one hand.

In view of the aforementioned aspects, the present invention is based on the object of proposing an alternative and/or improved holding device which, on the one hand, represents a versatile functionality and, on the other hand, is particularly stable. A further object of the present invention may be to provide a particularly simple and modularly attachable holding device. In the present case, modular means that the holding device can provide various functional elements, such as drink holders, storage space or mobile devices, based on different and optionally easily interchangeable modules.

According to the invention, this object is achieved by a holding device with the features of the main claim. Possible configurations and further developments of this holding device result from the subclaims and the following description.

The proposed holding device for a vehicle interior trim part comprises a base integrated in the vehicle interior trim part with a receptacle for reversibly partially receiving a carrier module, which is accommodated or receivable in the receptacle so as to be rotatable about an axis of rotation. A base integrated into the vehicle interior trim part is to be understood as meaning a base which, when used as intended, is firmly integrated into the vehicle interior trim part and cannot be removed without being destroyed. This distinguishes such an integrated base from a detachably attached or attachable element, as is the case, for example, with mobile holding devices known from the prior art. In the present case, the carrier module represents a modular, optionally modularly interchangeable, and therefore reversibly detachable or attachable element. The carrier module can be set up to provide one or more of the functional elements mentioned above in a non-exhaustive list. According to the invention, the base and the carrier module each comprise at least two magnets, which are arranged in the base and in the carrier module in such a way that the magnetic dipole vector of at least one of the respective at least two magnets is substantially anti-parallel to the magnetic dipole vector of at least one other of the respective at least two magnets and runs essentially parallel to the axis of rotation. In a release position of the carrier module about the axis of rotation, the carrier module is arranged in the receptacle relative to the base in such a way that the base and the carrier module magnetically repel each other, and in a holding position of the carrier module about the axis of rotation, the carrier module is arranged in the receptacle relative to the base in such a way that that the base and the carrier module magnetically attract each other. Furthermore, the holding device comprises a locking mechanism for locking the carrier module in the holding position, wherein the locking mechanism comprises an actuating element for releasing the locking device from the holding position.

The proposed holding device allows a particularly stable attachment of the carrier module due to the base provided with a receptacle and the arrangement of the magnets in combination with the locking mechanism. Furthermore, the interaction according to the invention of the carrier module and base results in a particularly versatile, aesthetic as well as a haptically appealing, easy and intuitive holding device.

The magnets can be firmly integrated into the base and/or the carrier module. This means that an attraction or repulsion of the magnets, depending on the arrangement of the carrier module relative to the base, can necessarily lead to an immediate attraction or repulsion of the carrier module and base. By magnets arranged in such a way that their respective dipole vectors run anti-parallel to one another, it is meant in the present case that the respective dipole vectors point in opposite directions, that is to say the north and south poles of two corresponding magnets are arranged oppositely along the axis of rotation. When the carrier module is accommodated in the base's receptacle, the magnetic field strength of the magnets can cause the magnets to repel or attract each other, depending on the relative orientation of the carrier module around the axis of rotation. For example, two magnets with dipole vectors running parallel to each other, which are arranged in the base and in the carrier module and, for example in the holding position, aligned with one another along the axis of rotation, attract each other to the maximum and two magnets arranged in the base and in the carrier module abut each other , for example in the release position, magnets aligned with one another along the axis of rotation with dipole vectors running antiparallel to one another to the maximum. The arrangement and field strength of the magnets can be selected such that in the holding position, the base and carrier module can only be separated from one another with considerable effort, which can be applied by an individual, and in comparison, in the release position, with very little effort. The arrangement and field strength of the magnets can, for example, be selected such that in the release position the resulting magnetic repulsion is greater than or equal to a weight of the carrier module. The resulting maximum force measured when the carrier module is placed in the base as the vector sum of the weight of the carrier module and the magnetic force can be between 0 N and 10 N, for example between 0.4 N and 2 N, in the release position and in the Holding position between 0.5 N and 50 N, for example between 2 N and 20 N. Typically the holder can hold items weighing up to 2 kg.

The magnets can be permanent magnets and/or electromagnets. The magnets arranged in the carrier module can preferably be permanent magnets. The magnets arranged in the base can be permanent magnets, electromagnets or a mixture of both. In an exemplary embodiment, both the magnets arranged in the carrier module and in the base can be permanent magnets. Permanent magnets have the advantage over electromagnets that in the event of a power failure, for example due to an empty battery, the magnets retain their holding function. The magnets can be at least partially iron-containing magnets, for example neodymium-iron-boron magnets. This makes it possible to provide particularly cost-effective and/or compact magnets. Alternatively or additionally, the magnets can at least partially be plastic magnets. For example, magnets that can be produced using an injection molding process can be used.

The carrier module can comprise an insertion area which is essentially complementary to the receptacle for the partially rotatable arrangement of the carrier module in the receptacle. This makes it easier to pick up and position the carrier module and improves its pick-up stability. The carrier module can be accommodated or receivable in the receptacle in a translationally fixed manner radially to the axis of rotation. The receptacle can be designed as a recess. The carrier module can comprise a projection that is essentially complementary to the receptacle. The receptacle can be designed concentrically with the axis of rotation. The receptacle can be designed to continuously or interruptively rotate around the axis of rotation. If the receptacle is designed to be interrupted and circumferential, an insertion area formed on the carrier module should be designed such that rotation of the carrier module between at least one rotation and at least one release position is possible. Furthermore, the recording can run essentially along the axis of rotation. The maximum diameter of the receptacle measured radially to the axis of rotation can be between 0.5 cm and 20 cm, between 2 cm and 15 cm or between 4 cm and 8 cm. The maximum depth of the receptacle measured along the axis of rotation can be between 0.2 cm and 4 cm, between 0.4 cm and 2 cm or between 0.8 cm and 1.4 cm.

If the receptacle is designed, for example, as a recess, the base can comprise a cover element for at least partially covering the receptacle. This allows the overall aesthetic and haptic impression of the base to be improved, especially if no carrier module is arranged in or on the base. This can also prevent dirt from accumulating in the recess. The cover element can comprise a pretensioning device which is designed to pretension the cover element into a covering position such that the cover element ends in the area of the recess with the base and optionally ends flush with the base. So For example, one or more springs can be provided which bias the cover element in the direction of the cover position. Furthermore, one or more stopper elements can be provided which hold the covering element in the covering position against the preloading force of the pretensioning device. The biasing device can bias the cover element along the axis of rotation in the direction of the covering position. Your pretensioning force can be set up in such a way that in the holding position the pretensioning force is smaller than the magnetic attraction between the base and the carrier module. Furthermore, the pretensioning force can be set up in such a way that the cover element can be easily pressed into the recess, in particular with the carrier module, by a user.

The base and/or the carrier module can comprise more than two magnets with dipole vectors running parallel to the axis of rotation, which are arranged in such a way that at least one further holding position and/or a further release position of the carrier module is provided about the axis of rotation into which the carrier module can be rotated . For example, magnets in the base and the carrier module can be arranged and aligned according to their dipole vector in such a way that at least one further holding position and/or release position is provided. As a result, the carrier module in the receptacle can be aligned in several predetermined positions for its attachment or removal and, for example, rotated into these.

In one exemplary embodiment, the base and the carrier module can each comprise 2n magnets, each with n dipole vectors running parallel and n antiparallel to them. The 2n magnets each can be arranged in such a way that n release positions and n holding positions are provided, with the n release positions and the n holding positions optionally being provided alternately around the axis of rotation. In other words, the carrier module can then be continuously rotated between different release and holding positions. For example, eight magnets can be provided in the base and in the carrier module, so that four release positions and four holding positions of the carrier module are provided. In principle, the magnets arranged in the base and/or the carrier module can be pairs of opposing magnets with the same dipole vector orientation. The magnets can each be arranged concentrically around the axis of rotation. In the circumferential direction around the axis of rotation, the magnets of the base and/or the carrier module can be arranged alternately with opposite dipole vector orientations. In other words, magnets immediately adjacent to one another in the circumferential direction of the axis of rotation, which are each arranged in the base and/or in the carrier module, can have dipole vectors running in opposite directions. The magnets can be evenly distributed along the circumference around the axis of rotation. The magnets in the base and the magnets in the carrier module can be arranged in such a way that when the carrier module is received in the base, the respective magnets can be aligned with one another depending on the rotational position of the carrier module about the axis of rotation. Then the magnets arranged in the carrier module with the same dipole vector orientation can be aligned with corresponding magnets of the base of the same and in a release position opposite to the magnets of the carrier module or in a holding position compared to the magnets of the carrier module also with the same dipole vector orientation.

The locking mechanism may include a hook mechanism disposed in the carrier module. The hook mechanism can comprise at least one hook, which is designed to engage in a form-fitting manner in at least one corresponding engagement notch formed in the receptacle in the holding position or optionally in at least one of several holding positions in such a way that the carrier module is non-rotatable about the axis of rotation and/or is locked in translation along the axis of rotation. In other words, it can be provided for each holding position that the hook mechanism locks into the receptacle via one or more hooks with engagement notches corresponding to the hooks. A hook can positively engage in a corresponding engagement notch along the circumferential direction and/or along the longitudinal direction of the rotation axis. The at least one hook can extend in the radial direction with respect to the axis of rotation. Analogously, the at least one engagement notch can also extend in the radial direction with respect to the axis of rotation.

The hook mechanism can be preloaded. For example, the hook mechanism can be biased in such a way that when the at least one hook and the at least one engagement notch are aligned, the hook automatically engages into the engagement notch, wherein the actuating element for releasing the locking mechanism can be actuated against the biasing force of the hook mechanism. The hook mechanism may include a hook biasing device for biasing the at least one hook. The hook pretensioning device can be positively connected to the carrier module and the at least one hook and can optionally be set up to move the hook radially to bias the direction away from the axis of rotation.

The hook mechanism may include at least a pair of opposing hooks. The at least one pair of opposing hooks may be connected to each other by the hook biasing device. The hooks can be designed in such a way that when the carrier module is arranged in the receptacle, the pairs of opposite hooks are arranged concentrically with the axis of rotation. Alternatively, an odd number of hooks is also possible, for example only one hook, but preferably several hooks, which are arranged, for example, concentrically with the axis of rotation when the carrier module is arranged in the receptacle. The actuating element can extend in the radial direction with respect to the axis of rotation. The actuating element can comprise at least two opposing actuating members. Each of the actuators may extend in the radial direction with respect to the axis of rotation. The actuators can be connected to the hooks. The actuators can be formed in one piece with the hooks. For example, two actuators can be arranged opposite one another and each be formed in one piece with two opposing hooks. The respective hooks can then be released from the engagement notches by squeezing the corresponding actuating members. For example, the actuators may be arranged such that they are aligned in a holding position with the corresponding hooks along an engagement direction of the hooks in respective engagement notches. Alternatively or additionally, two opposing actuators can be rotated about the axis of rotation relative to two opposing hooks, for example rotated by 90°. Each of the aforementioned aspects of the hook or locking mechanism can improve the stability of the attachment of the carrier module in the receptacle and/or the handling of the locking mechanism.

It can be provided that in one or more holding positions opposite actuators and/or opposite hooks are aligned with two opposite magnets with the same dipole vector orientation. This makes it easier to intuitively lock the carrier module into the respective holding position. Two opposing actuators of the actuating element can be arranged and designed in such a way that they can be operated with one hand. The maximum external distance between two opposing actuators can be between 1 cm and 15 cm, for example between 5 cm and 10 cm.

The base can include a charging device for providing a recharge current for a battery that is accommodated or removable in the carrier module. The charging device can be set up to provide the recharge current wirelessly, for example inductively. This makes it possible to recharge any power-consuming device that is accommodated or receivable in the carrier module.

The magnets and/or the receptacle and/or the actuating element and/or the loading device can/can be arranged concentrically with the axis of rotation. As a result, the holding device can be made particularly compact. Accordingly, it can be provided that in the radial direction away from the axis of rotation, if necessary, first the loading device, then the magnets, then the receptacle and then the actuating element is arranged.

The carrier module can be a modularly interchangeable element for the modularly interchangeable arrangement of retrofittable vehicle interior elements, such as cup holders, storage boxes or holders for sound systems, cameras, cell phones and other mobile devices. It can be provided that a vehicle trim part or a vehicle trim generally comprises several of the bases described above. As a result, different modular carrier modules can be attached or attached to a variety of locations on a vehicle. The base can include decorative elements, in particular lighting elements, for example to identify the base and the various holding positions and/or release positions.

Several embodiments have been disclosed herein. Other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description showing and describing an exemplary embodiment of the invention. Accordingly, the drawings and detailed description are to be considered as illustrative and not restrictive. Recurring features are given the same reference numbers in the description of the figures.

• 1 eine perspektivische schematische Darstellung einer Ausführungsform einer erfindungsgemäßen Haltevorrichtung,
• 2 eine schematische Schnittdarstellung der Haltevorrichtung aus 1 entlang der Rotationsachse, wobei das Trägermodul in einer Halteposition angeordnet ist,
• 3 eine schematische Draufsicht auf die Basis der Haltevorrichtung aus 1, sowie
• 4 eine perspektivische schematische Detailansicht des Hakenmechanismus der Haltevorrichtung aus 1.

Show it

• 1 a perspective schematic representation of an embodiment of a holding device according to the invention,
• 2 a schematic sectional view of the holding device 1 along the axis of rotation, with the carrier module being arranged in a holding position,
• 3 a schematic top view of the base of the holding device 1 , as well as
• 4 a perspective schematic detailed view of the hook mechanism of the holding device 1 .

The 1 until 4 show a possible embodiment of a holding device 1 according to the invention. In the following, recurring features are described once for all figures.

The 1 and 2 show a holding device 1 for a vehicle interior trim part, which includes a base 10 integrated in the vehicle interior trim part (not shown) with a receptacle 15 for reversibly partially receiving a carrier module 30, which is rotatably accommodated or receivable in the receptacle 15 about an axis of rotation R. In the exemplary embodiment shown, the base 10 and the carrier module 30 each comprise eight magnets 11a, 11b, 31a, 31b, which are arranged in the base 10 and in the carrier module 30 in such a way that the magnetic dipole vector of four of the respective eight magnets 11a, 31a runs essentially antiparallel to the magnetic dipole vector of the four other of the respective eight magnets 11b, 31b and essentially parallel to the axis of rotation R. The different orientation of the dipole vectors is indicated by crosses, cf. 1 and 3 . In one of four possible release positions of the carrier module 30 about the axis of rotation R, the carrier module 30 is arranged in the receptacle 15 relative to the base 10 in such a way that the base 10 and the carrier module 30 magnetically repel each other and in one of four possible holding positions of the carrier module 30 around the axis of rotation, the carrier module 30 is arranged in the receptacle 15 relative to the base 10 in such a way that the base 10 and the carrier module 30 magnetically attract each other. According to the invention, however, only two magnets 11a, 11b, 31a, 31b arranged in the base 10 and the carrier module 30 and accordingly only one release and only one holding position are possible. Furthermore, the holding device 1 shown comprises a locking mechanism 40 for locking the carrier module 30 in at least one and preferably in all of the four holding positions possible here, the locking mechanism 40 comprising an actuating element 45 for releasing the locking from the respective holding position.

The magnets 11a, 11b, 31a, 31b are firmly integrated into the base 10 and the carrier module 30, the magnets 11a, 11b being firmly integrated into the base 10 and the magnets 31a, 31b being firmly integrated into the carrier module 30. The arrangement and field strength of the magnets 11a, 11b, 31a, 31b can be selected in such a way that in each of the possible holding positions, the base 10 and the carrier module 30 only require considerable effort, albeit one that can be applied by an individual, and in comparison to this in each of the possible release positions can be separated from each other with very little effort. The arrangement and field strength of the magnets 11a, 11b, 31a, 31b can, for example, be selected such that in each of the possible release positions the resulting magnetic repulsion is greater than or equal to a weight of the carrier module 30. The resulting maximum force measured when the carrier module 30 is accommodated in the receptacle 15 of the base 10 as the vector sum of the weight of the carrier module 30 and the magnetic force can be between 0 N and 10 N, for example between 0.4 N and 2, in each of the possible release positions N, and in each of the possible holding positions between 0.5 N and 50 N, for example between 2 N and 20 N. In the present exemplary embodiment, both the magnets 11a, 11b, 31a, 31b arranged in the carrier module 30 and in the base 10 are permanent magnets. Alternatively, the magnets 11a, 11b arranged in the base 10 can be at least partially electromagnets. The magnets 11a, 11b, 31a, 31b can be at least partially iron-containing magnets, for example neodymium-iron-boron magnets. Alternatively or additionally, the magnets 11a, 11b, 31a, 31b can at least partially be plastic magnets.

The carrier module 30 includes an insertion area 35 designed to be complementary to the receptacle 15 for the partially rotatable arrangement of the carrier module 30 in the receptacle 15. The carrier module 30 is received or receivable in the receptacle 15 in a translationally fixed manner radially to the axis of rotation R. The receptacle 15 is designed as a recess. The insertion area 35 of the carrier module 30 is designed as a projection. The receptacle 15 is designed to be concentric with the axis of rotation R and to run continuously around it. Alternatively, the receptacle 15 can be designed to run around the axis of rotation R in an interrupted manner. Furthermore, the receptacle 15 runs along the rotation axis R. The maximum diameter of the receptacle 15 measured radially to the rotation axis R can be between 0.5 cm and 20 cm, between 2 cm and 15 cm or between 4 cm and 8 cm. The maximum depth of the receptacle 15 measured along the axis of rotation R can be between 0.2 cm and 4 cm, between 0.4 cm and 2 cm or between 0.8 cm and 1.4 cm.

The base 10 comprises a cover element 20 for at least partially covering the receptacle 15. The cover element 20 comprises a biasing device 21, which is designed to bias the cover element 20 into a covering position such that the cover element 20 is in the area of Recess 15 is flush with base 10, cf. 1 and 3 . Furthermore, a stopper element 22 - which runs in the circumferential direction of the cover element 20 in the exemplary embodiment shown - is provided and is designed to hold the cover element 20 in the covering position against the pretensioning force of the pretensioning device 21. The biasing device 21 tensions the cover element 20 along the rotation axis R in the direction of the covering position. Your biasing force can be set up in such a way that in the holding position the biasing force is smaller than the magnetic attraction between the base 10 and the carrier module 30. Furthermore, the pretensioning force can be set up in such a way that the cover element 20 can be easily pressed into the recess 15, in particular with the carrier module 30, by a user.

As described above, according to the exemplary embodiment shown, the base 10 and the carrier module 30 comprise more than two magnets 11a, 11b, 31a, 31b with dipole vectors running parallel to the axis of rotation R, which are arranged such that more than one holding position and more than one release position of the carrier module 30 is provided about the rotation axis R, into which the carrier module 30 can be rotated. In principle, the base 10 and the carrier module 30 can each comprise 2n magnets 11a, 11b, 31a, 31b, each with n dipole vectors running parallel and n anti-parallel to them. The 2n magnets 11a, 11b, 31a, 31b can be arranged in such a way that n release positions and n holding positions are provided. The four release positions and four holding positions shown in the present embodiment are provided alternately around the rotation axis R. The magnets 11a, 11b, 31a, 31b arranged in the base 10 and the carrier module 30 are pairs of opposing magnets 11a, 11b, 31a, 31b with the same dipole vector orientation, cf. 2 and 3 . The magnets 11a, 11b, 31a, 31b are each arranged concentrically around the axis of rotation R. In the circumferential direction around the axis of rotation R, the magnets 11a, 11b, 31a, 31b of the base 10 and the carrier module 30 are arranged alternately with opposite dipole vector orientation. The magnets 11a, 11b, 31a, 31b are evenly distributed along the circumference around the rotation axis R. The magnets 11a, 11b in the base 10 and the magnets 31a, 31b in the carrier module 30 are arranged in such a way that when the carrier module 30 is received in the base 10, the respective magnets 11a, 11b depending on the rotational position of the carrier module 30 about the axis of rotation R , 31a, 31b can be aligned with one another. Thus, the magnets 31a or 31b arranged in the carrier module 30 with the same dipole vector orientation are aligned with corresponding magnets 11a or 11b of the base 10 and in one of the four possible release positions compared to the magnets 31b or 31a of the carrier module 30 opposite or in one of the four possible holding positions compared to the magnets 31a and 31b of the carrier module 30 are also aligned with the same dipole vector orientation.

2 shows the exemplary holding device 1 in a holding position of the carrier 30, the cover element 20 being pressed into the receptacle 15 and the locking mechanism 40 being locked with the receptacle 15. The locking mechanism 40 includes a hook mechanism 42 which is arranged in the carrier module 30. A detailed view of the hook mechanism 42 is shown in 4 shown. The hook mechanism 42 shown comprises two hooks 43, each of which is designed to engage in a form-fitting manner in each of the four possible holding positions in two corresponding out of a total of eight engagement notches 41 formed in the receptacle 15 in such a way that the carrier module 30 is non-rotatable about the axis of rotation R and is locked in translation along the rotation axis R. The hooks 43 engage positively in the corresponding engagement notches 41 along the circumferential direction and along the longitudinal direction of the rotation axis R. The hooks 43 and engagement notches 41 extend in the radial direction with respect to the rotation axis R.

The hook mechanism 42 is biased in such a way that when the two hooks 43 are aligned with two of the eight corresponding engagement notches 41 in one of the four possible holding positions, the hooks 43 automatically snap into these engagement notches 41, the actuating element 45 being used to release the locking mechanism 40 against the biasing force the hook mechanism 42 can be actuated. The hook mechanism 42 includes a hook pretensioning device 44 for pretensioning the hooks 43. The hook pretensioning device 44 is positively connected to the carrier module 30 and the hooks 43 and is designed to pretension the hooks 43 in a direction pointing radially away from the axis of rotation R. The hook mechanism 42 includes two opposing hooks 43 which are connected to one another by the hook biasing device 44. The hooks 43 are designed in such a way that when the carrier module 30 is arranged in the receptacle 15, the two opposing hooks 43 are arranged concentrically with the axis of rotation R. Alternatively, more than one pair of opposing hooks 43 or an odd number of hooks 43 can be provided, which are arranged, for example, concentrically with the axis of rotation R when the carrier module 30 is arranged in the receptacle 15.

The actuator 45 comprises two opposing actuators which extend in the radial direction with respect to the axis of rotation R. The actuators are connected to the hooks 43 and are formed in one piece with them. The hooks 43 can thus be released from corresponding engagement notches 41 by pressing the two actuating members together. The actuators are arranged such that they are aligned in a holding position with the hooks 43 along an engagement direction of the hooks 43 in the respective engagement notches 41. Alternatively or additionally, two opposing actuators can be rotated about the rotation axis R relative to two opposing hooks 43, for example rotated by 90 °. In the exemplary embodiment shown here, the opposing actuators and opposing hooks 43 are aligned in each of the holding positions with two opposing magnets 11a, 31a or 11b, 31b of the same dipole vector orientation. The actuating members of the actuating element 45 are arranged and designed in such a way that they can be operated with one hand. The maximum external distance between the opposing actuators can be between 1 cm and 15 cm, for example between 5 cm and 10 cm.

The base 10 includes a charging device 50 for providing a recharge current for a battery that is accommodated or receivable in the carrier module 30. The charging device 50 can be set up to provide the recharging current wirelessly, for example inductively.

The magnets 11a, 11b, 31a, 31b, the receptacle 15, the actuating element 45 and the loading device 50 are arranged concentrically with the axis of rotation R. In the radial direction away from the axis of rotation R, first the loading device 50, then the magnets 11a, 11b, 31a, 31b, then the receptacle 15 and finally the actuating element 45 are arranged.

The carrier module 30 can be a modularly interchangeable element for the modularly interchangeable arrangement of retrofittable vehicle interior elements, such as cup holders, storage boxes or holders for cell phones and other mobile devices. It can be provided that a vehicle trim part or a vehicle trim generally includes several of the bases 10 described above. The base 10 can include decorative elements, in particular lighting elements, for example to identify the base and the various holding positions and/or release positions.

Claims (10)

Holding device (1) for a vehicle interior trim part, the holding device (1) comprising a base (10) integrated in the vehicle interior trim part with a receptacle (15) for reversibly partially receiving a carrier module (30), which can be rotated about an axis of rotation (R) in the receptacle (15) is recorded or receivable, whereby the base (10) and the carrier module (30) each comprise at least two magnets (11a, 11b, 31a, 31b), which are arranged in the base (10) and in the carrier module (30) in such a way that the magnetic dipole vector is at least one of the respective at least two magnets (11a, 11b, 31a, 31b) runs substantially antiparallel to the magnetic dipole vector of at least one other of the respective at least two magnets (11a, 11b, 31a, 31b) and substantially parallel to the axis of rotation (R), wherein in a release position of the carrier module (30) about the axis of rotation (R), the carrier module (30) is arranged in the receptacle (15) relative to the base (10) in such a way that the base (10) and the carrier module (30) magnetically repel each other and in a holding position of the carrier module (30) about the axis of rotation (R), the carrier module (30) is arranged in the receptacle (15) relative to the base (10) in such a way that the base (10) and the carrier module (30) are magnetic to one another put on, and where the holding device (1) further comprises a locking mechanism (40) for locking the carrier module (30) in the holding position, wherein the locking mechanism (40) comprises an actuating element (45) for releasing the locking from the holding position. Holding device (1). Claim 1 , wherein the receptacle (15) is designed as a recess and the base (10) comprises a cover element (20) for at least partially covering the receptacle (15), the cover element (20) optionally comprising a biasing device (21) which is set up for this purpose The cover element (20) is to be biased into a covering position in such a way that the cover element (20) ends in the area of the recess with the base (10) and optionally ends flush with the base (10). Holding device (1). Claim 2 , wherein the biasing device (21) biases the cover element (20) along the axis of rotation (R) in the direction of the covering position and optionally its biasing force is set up such that in the holding position the biasing force is smaller than the magnetic attraction between the base (10) and the Carrier module (30). Holding device (1) according to one of the preceding claims, wherein the base (10) and / or the carrier module (30) comprise more than two magnets (11a, 11b, 31a, 31b) with dipole vectors running parallel to the axis of rotation (R), which are such are arranged so that at least one further holding position and/or one further release position of the carrier module (30) is provided about the axis of rotation (R), into which the carrier module (30) can be rotated. Holding device (1). Claim 4 , wherein the base (10) and the carrier module (30) each comprise 2n magnets (11a, 11b, 31a, 31b), each with n parallel and n anti-parallel dipole vectors, the 2n magnets (11a, 11b, 31a, 31b ) are arranged such that n release positions and n holding positions are provided, the n release positions and the n holding positions optionally being provided alternately around the rotation axis (R). Holding device (1) according to one of the preceding claims, wherein the locking mechanism (40) comprises a hook mechanism (42) which is arranged in the carrier module (30) and comprises at least one hook (43) which is designed to be in the holding position or optionally to engage positively in at least one corresponding engagement notch (41) formed in the receptacle (15) in at least one of several holding positions in such a way that the carrier module (30) is rotationally fixed around the rotation axis (R) and/or translationally fixed along the rotation axis (R ) is locked. Holding device (1). Claim 6 , wherein the hook mechanism (42) is biased in such a way that when the at least one hook (43) and the at least one engagement notch (41) are aligned, the hook (43) snaps into the engagement notch (41), the actuating element (45) for Loosening the locking mechanism (40) can be actuated against the biasing force of the hook mechanism (42). Holding device (1) according to one of the preceding claims, wherein the base (10) comprises a charging device (50) for providing a recharging current for a battery accommodated or receivable in the carrier module (30), the charging device (50) optionally being wireless, for example inductive , providing the recharging current is set up. Holding device (1) according to one of the preceding claims, wherein the magnets (11a, 11b, 31a, 31b) and/or the receptacle (15) and/or the actuating element (45) and/or the loading device (50) are concentric with the axis of rotation (R) are/is arranged. Holding device (1) according to one of the preceding claims, wherein the carrier module (30) is a modularly interchangeable element for the modularly interchangeable arrangement of retrofittable vehicle interior elements, such as cup holders, storage boxes or holders for cell phones and other mobile devices.

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