WO2024008224A1 - Operating assembly with a context-dependent rotary knob - Google Patents

Abstract

The invention relates to an operating assembly with a context-dependent rotary knob (1), which is rotatably mounted on a display surface (2), wherein the rotary knob (1) is coupled to a rotary knob damping device (5) in order to generate haptic perceptions on the rotary knob (1). The invention additionally relates to a vehicle comprising the operating assembly.

Description

Operating arrangement with a context-related rotary knob

The present invention relates to an operating arrangement with a context-related rotary knob which is rotatably mounted on a display surface. The invention further relates to a vehicle with at least one operating arrangement.

Such an operating arrangement with a rotary knob or knob for selecting operating and/or control functions is well known. By turning the rotary knob, operating and/or control functions can be selected that are assigned to a rotation angle range of the rotary knob.

For example, a context-related rotary knob is known from US 10 031 592 B2. The rotary knob is rotatably mounted on a display surface and can select the contexts arranged on the display surface in accordance with the rotation angle ranges of the rotary knob.

The present invention is based on the object of improving or expanding the operating arrangement described above in terms of its functionality.

This object is achieved according to the invention by the features of patent claims 1 and 12, respectively. Advantageous and claimed further developments result from the subclaims and the description as well as the drawings.

An operating arrangement with a context-related or context-based rotary knob is therefore proposed, which is mounted on any display surface or on any display. In order to expand the functionality of the rotary knob, it is provided that the rotary knob is coupled to a rotary knob damper device for generating haptic perceptions on the rotary knob.

In this way, an operating arrangement is realized with a context-related rotary knob, on which a variable haptic can advantageously also be generated in order to provide the operator with corresponding haptic feedback during operation. This is in addition to the context-based functionality an additional advantageous feature in the proposed operating arrangement.

In order to transfer the haptic perceptions to the rotary knob during operation in a structurally simple and cost-effective manner, the proposed operating arrangement provides that the rotary knob is connected to the electromechanical damper device via at least one gear device or the like. As a result, in order to generate the haptic perceptions, a corresponding torque for damping the rotary movement can be transmitted from the damper device to the rotary knob.

Various types of transmission are conceivable as a transmission device. A particularly simply constructed transmission device can be implemented using a single-stage or multi-stage spur gear stage or the like. For this purpose, for example, the rotary knob can be connected to a first spur gear and the damper device can be connected to a second spur gear, so that a generated damping can be transferred to the rotary knob via the spur gears meshing with one another.

For a structurally simple storage of the rotary knob on the display surface, it is provided that the rotary knob is mounted in a bearing bush or the like. In this way, a corresponding rotation of the rotary knob on the display surface can be realized in order to activate predetermined operating and / or control functions by rotating the rotary knob, which are assigned to predetermined rotation angle ranges of the rotary knob on the display surface.

When using a bearing bush, it is advisable that the rotary knob mounted in the bearing bush has a cover and in this way forms an interior or a housing space, the gear device being arranged in this interior between the bearing bush and the cover.

It is possible that the damper device is also housed in the housing. However, a space-saving solution provides for the damper device is housed below the display surface, as there is sufficient installation space available in this area.

In order to realize a connection between the damper device and the rotary knob via the gear device or spur gear stage in such embodiments, the proposed operating arrangement provides that a connecting shaft or the like between the second spur gear of the spur gear stage and the damper device through a through hole, a breakthrough or the like is shown in the display area. In this way, the damping generated by the damper device can be transmitted via the connecting shaft to the spur gear stage and ultimately to the rotary knob.

Preferably, the rotary knob can be arranged centrally on the display surface, for example. However, it is also conceivable that the rotary knob is assigned to an edge region of the display area in order to avoid a breakthrough through the display area.

In order to further improve the functionality of the operating arrangement, a so-called touch display or the like can preferably be used as the display surface, which can also be controlled by buttons or touches.

Particularly preferred when choosing the electromagnetic damper device is a damper device that functions on a magnetorheological basis. For example, the damper device can comprise a magnetorheological fluid or the like. A magnetorheological fluid (MRF), for example, is a fluid or a suspension with magnetically polarizable particles that are finely dispersed in a carrier liquid. The magnetorheological fluid solidifies when a magnetic field is applied because the particles are polarized and form chains in the direction of the field lines. Due to the alignment of the particles, the liquid becomes thicker or more viscous as the field strength increases, so that the viscosity of the magnetorheological liquid can be changed quickly and reversibly in a magnetic field. Through the use of magnetorheological If you see liquid in the damper device, the desired damping can advantageously be achieved simply and cost-effectively.

The object on which the invention is based is also achieved by a vehicle with at least one operating arrangement described above. This results in the advantages already described and other advantages. For example, the operating arrangement can be arranged in the cockpit area of a vehicle in order to carry out certain functions and controls in a context-related manner using the rotary knob or rotary knob.

The present invention is explained further below with reference to the drawings.

Show it:

Figure 1 shows an enlarged sectional view through a possible embodiment variant of an operating arrangement according to the invention along a section line according to Figure 2;

Figure 2 shows a top view of a display surface with a gear device of the operating arrangement designed as a spur gear stage; and

Figure 3 shows a top view of the display surface with an adhesive surface for rotatable mounting of an operating or rotary knob of the operating arrangement.

1 to 3 show various views of an operating arrangement according to the invention, shown only as an example, for example for installation in a vehicle.

The proposed operating arrangement includes a context-related rotary knob 1, which is rotatably mounted on a display surface 2. The display surface 2 is preferably designed as a touch display. By turning the rotary knob 1, predetermined operating and/or control functions can be activated in the vehicle, the predetermined rotation angle ranges 3 of the rotary knob 1 are assigned to the display surface 2. A corresponding context 4 can be assigned to each rotation angle range 3.

In order to further improve the functionality of the operating arrangement, it is provided that the rotary knob 1 is coupled to a rotary actuator damper device 5 for generating haptic perceptions on the rotary knob 1. To transmit the damping, the rotary knob 1 is connected to the electromechanical damper device 5 via a gear device. A simple or n-fold or n-stage transmission can be used as the transmission device. In the embodiment variant shown, for example, a single-stage spur gear stage is used.

In this way, an operating arrangement is realized with a context-based rotary knob 1, which is connected to an electromechanical damper device 5 by means of a mechanical connection and can therefore generate variable haptics for the operator by correspondingly damping the rotary movement of the rotary knob 1.

As can be seen, for example, from Figures 1 and 2, the spur gear stage comprises a first spur gear 6 and a second spur gear 7, which are in engagement with one another. The first spur gear 6 is connected to the rotary knob 1 and the second spur gear 7 is connected to the damper device 5.

In order to rotatably mount the rotary knob 1 on the display surface 2, a bearing bush 8 or the like is provided, which is fastened on the display surface 2. As can be seen, for example, from FIG. 3, an approximately annular adhesive surface 9 is provided on the display surface 2 for this purpose. As a result, the bearing bushing 8 is fastened to the display surface 2 by means of the adhesive surface 9 and rotatably supports the rotary knob 1 on the display surface 2. The rotary knob 1, which is rotatably mounted in the bearing bushing 8, has a cover 10, in the interior formed between the bearing bushing 8 and the cover 10 accommodates the transmission device or the two spur gears 6, 7 of the spur gear stage. When the rotary knob 1 is turned by an operator, the first spur gear 6, which is firmly connected to the rotary knob 1, is also set in rotation, as a result of which the second spur gear 7, which meshes with the first spur gear 6, is also set in rotation. Since the second spur gear 7 is connected in a rotationally fixed manner to the damper device 5, for example via a connecting shaft 11, the damper device 5 is also rotated. As soon as a corresponding damping can be applied by the damper device 5, this braking torque is transmitted to the rotary knob 1 via the spur gear stage in order to generate a corresponding haptic perception for the operator on the rotary knob 1.

For example, if the proposed operating arrangement is provided on the edge of the display area 2, the damper device 5 can be arranged outside the display area 2.

However, it is also possible to accommodate the damper device 5 virtually concealed below the display surface 2, as is shown in the embodiment variant shown. In this case, the connecting shaft 11 is guided, for example, through an opening 12 or the like in the display surface 2. The breakthrough 12 is indicated, for example, in FIG. 1 or in FIG. 3.

It is particularly advantageous if a damper device 5 that functions on a magnetorheological basis is used as the damper device 5. In this case, the rotational movement of the connecting shaft 11 is braked accordingly by a magnetorheological fluid in the damper device 5 by applying a magnetic field. Other damper devices 5 can also be used.

Reference number rotary knob or rotary switch Display area or touch display Angle of rotation range Context Damper device First spur gear Second spur gear Bearing bush Annular adhesive surface Cover Connecting shaft Breakthrough or through hole

Claims

Patent claims

1 . Operating arrangement with a context-related rotary knob (1) which is rotatably mounted on a display surface (2), characterized in that the rotary knob (1) is coupled to a rotary knob damper device (5) for generating haptic perceptions on the rotary knob (1). .

2. Operating arrangement according to claim 1, characterized in that the rotary knob (1) is connected to the electromechanical damper device (5) via at least one gear device.

3. Operating arrangement according to claim 2, characterized in that the transmission device is designed as a spur gear stage with a first spur gear (6) and a second spur gear (7), the spur gears (6, 7) being in engagement with one another and the first spur gear ( 6) the spur gear stage is connected to the rotary knob (1) and the second spur gear (7) of the spur gear stage is connected to the damper device (5).

4. Operating arrangement according to one of the preceding claims, characterized in that a bearing bush (8) for rotatably supporting the rotary knob (1) is attached to the display surface (2).

5. Operating arrangement according to claim 4, characterized in that the rotary knob (1) mounted in the bearing bushing (8) has a cover (10), the gear device being arranged in the interior formed between the bearing bushing (8) and the cover (10).

6. Operating arrangement according to one of the preceding claims, characterized in that the damper device (5) is arranged below the display surface (2).

7. Operating arrangement according to one of claims 3 to 6, characterized in that a connecting shaft (11) between the second spur gear (7) of the spur gear stage and the damper device (5) is guided through an opening (12) in the display surface (2).

8. Operating arrangement according to one of the preceding claims, characterized in that the rotary knob (1) is assigned to the edge region of the display surface (2).

9. Operating arrangement according to one of the preceding claims, characterized in that a touch display is provided as the display surface (2).

10. Operating arrangement according to one of the preceding claims, characterized in that a damper device (5) functioning on a magnetrheological basis is provided.

11. Operating arrangement according to one of the preceding claims, characterized in that by turning the rotary knob (1) predetermined operating and / or control functions can be activated, which are assigned to predetermined rotation angle ranges (3) of the rotary knob (1) on the display surface (2). , whereby each rotation angle range (3) is assigned a corresponding context (4).

12. Vehicle with at least one operating arrangement according to one of the preceding claims.