WO2023246963A1 - Trackball operating device - Google Patents

Abstract

The invention relates to a trackball operating device having an operable ball (2), which is freely guided in a housing (3) in a rotatable manner in all directions of rotation, wherein predefined operating and/or control functions are allocated to the directions of rotation of the ball (2), wherein allocated to the ball (2) are at least one first rotation damper (5) and a second rotation damper (6) for generating haptic perceptions for a user in relation to the directions of rotation of the ball (2) and wherein the rotational axis (7) of the first rotation damper (5) and the rotational axis (8) of the second rotation damper (6) are aligned approximately perpendicularly to one another. The invention also relates to a vehicle having the trackball operating device.

Description

T rackball control device

The present invention relates to a trackball operating device with an operable ball or with an operable ball, which is guided in a housing so that it can rotate freely in all rotation directions, with the rotation movements or the rotation directions of the ball or the sphere being subject to predetermined operating conditions. and/or control functions are assigned.

Such trackball operating devices are used as input devices in computers.

For example, from the document DE 10 2019 213 858 A1 a haptic operating device for a vehicle with a roller-shaped base body is known, which is rotatably mounted about a shaft. An electronics unit and a rotating unit are assigned to the base body. The electronic unit includes a sensor system with which a corresponding touch or operation of the base body can be detected. The rotary unit is intended to enable a rotary movement of the base body around the shaft and thus to set a corresponding rotary characteristic that can be detected by the operator. As a result, a haptic perception can be generated around the axis of rotation on the rotary actuator.

The present invention is based on the object of proposing a trackball operating device described above, which enables haptic perception in all rotational directions in trackball operating devices in a simple and cost-effective design.

This object is achieved according to the invention by the features of patent claim 1 or 7, with advantageous and claimed developments resulting from the subclaims and the description as well as the drawings.

Thus, a trackball or trackball operating device with an operable ball or an operable ball is proposed, which is free in all rotational directions or rotational movements in a housing

1

Confirmation copy| is rotatably guided, with predetermined operating and / or control functions being assigned to the rotation directions of the ball or sphere. In order to realize a haptic perception in all directions of rotation of the ball or sphere in a structurally simple and cost-effective manner in the operating device, it is provided that the ball or sphere is provided with at least a first rotation damper and a second rotation damper to generate haptic perceptions for the operator are assigned to all directions of rotation of the ball or sphere, the rotation axes of the first rotation damper and the second rotation damper being aligned approximately perpendicularly or orthogonally to one another.

In this way, in the proposed haptic operating device, corresponding haptic braking moments can be generated in all directions of rotation of the ball or sphere via the two rotation dampers, so that a desired haptic perception of the ball is achieved regardless of the operating movement of the ball or sphere applied by the operator or can be transferred to the ball.

The transmission of the braking torque to dampen the rotational movements or the rotational movement of the ball can be transmitted from the rotational dampers to the ball in various ways. A structurally simple and cost-effective option provides that the first rotation damper has a first friction wheel or the like that is rotatably mounted about the axis of rotation and the second rotation damper has a second friction wheel or the like that is rotatable about the axis of rotation, the friction wheels each being in connection with the surface of the ball stand.

By choosing the material of the surface of the friction wheels, a desired frictional contact between the respective friction wheel and the surface of the ball can be ensured, so that a corresponding braking torque can be transferred to the ball via the friction wheels of the rotation damper to generate haptic perceptions in all directions of rotation of the ball. Because the rotation axis of the friction wheels are arranged approximately perpendicular to one another and are in contact with the surface of the ball, a braking torque or braking force component acting in the X direction based on a coordinate system is transmitted to the ball via the first friction wheel of the first rotation damper, while a braking torque or braking force component acting in the Y direction based on the coordinate system is transmitted to the ball via the second friction wheel of the second rotation damper. The two braking torque components in the X and Y directions result in a braking torque that can act in any direction of rotation.

The use of rotation dampers that function on a magnetrheological basis is particularly preferred. For example, the rotation damper 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. By using the magnetorheological fluid in the rotation damper, a desired damping of the rotational movements of the ball in all directions of rotation can advantageously be achieved simply and cost-effectively.

In order to further optimize the operation of the proposed trackball operating device, it is provided that at least one spring-loaded compensating wheel or the like is assigned to the ball.

The object on which the invention is based is also achieved by a vehicle with at least one trackball operating device described above. This results in the advantages already described and other advantages. For example, the trackball operating device can be arranged in the cockpit area of a vehicle in order to carry out certain functions and regulations via the ball of the operating device in the vehicle.

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

Show it:

Figure 1 shows a schematic view of a possible embodiment variant of a trackball operating device according to the invention in a housing in a vehicle;

Figure 2 shows a schematic detailed view of the trackball operating device according to the invention.

In Figures 1 and 2, various views of a trackball operating device according to the invention are shown schematically in a vehicle 1, for example.

The trackball operating device comprises a ball 2 that can be operated by an operator and is freely rotatable in all directions of rotation in a housing 3. For this purpose, a spherical shell-shaped ball guide 4 is provided in the housing 3. The directions of rotation of the ball 2 are assigned predetermined operating and/or control functions, which can be detected in the usual way by a detection device (not shown).

In order to ensure structurally simple haptic perceptions in all directions of rotation of the ball 2 in the trackball operating device, it is provided that the ball 2 is provided with a first rotation damper 5 and a second rotation damper 6 for generating haptic perceptions for the operator in relation to all directions of rotation of the ball 2 are assigned, wherein the axis of rotation 7 of the first rotary damper 5 and the axis of rotation 8 of the second rotary damper 6 are aligned approximately perpendicularly or orthogonally to one another. The The two axes of rotation 7 and 8 are indicated in Figure 2 by dashed lines which form a right angle.

2, the first rotary damper 5 has a first friction wheel 9 rotatably mounted about the axis of rotation 7 and the second rotary damper 6 has a second friction wheel 10 rotatably mounted about the axis of rotation 8, the friction wheels 9, 10 each being connected to the surface of the Ball 2 is in frictional contact, so that a corresponding braking torque can be transferred to the ball 2 via the friction wheels 9, 10 to generate haptic perceptions in all directions of rotation and can therefore be perceived by the operator.

Furthermore, a coordinate system with the axes in the X, Y and Z directions is shown in FIG. With respect to this coordinate system, a braking torque or braking force component acting in the Braking torque or braking force component acting in the Y direction can be transferred to the ball 2. The interaction of the braking components in the

Furthermore, it can be seen from Figure 2 that the ball 2 guided in the spherical shell-shaped ball guide 4 is assigned a spring-loaded compensating friction wheel 11. The spring-loaded compensating friction wheel 11 is mounted on the housing side and is in frictional contact with the surface of the ball 2 in order to optimally carry out the rotational movements of the ball 2 applied by the operator. reference symbol

1 vehicle 2 ball or sphere

3 housings

4 spherical shell-shaped ball guides

5 first rotation damper (X direction) 6 second rotation damper (Y direction)

7 Axis of rotation of the first rotation damper 8 Axis of rotation of the second rotation damper

9 first friction wheel 10 second friction wheel

11 Compensating friction wheel X X axis in the Y coordinate system Y axis in the Z coordinate system Z axis in the coordinate system

Claims

Patent claims

1. Trackball operating device with an operable ball (2), which is freely rotatable in all directions of rotation in a housing (3), with the directions of rotation of the ball (2) being assigned predetermined operating and / or control functions, characterized in that At least one first rotation damper (5) and a second rotation damper (6) are assigned to the ball (2) for generating haptic perceptions for an operator based on all directions of rotation of the ball (2), the axis of rotation (7) of the first rotation damper (5 ) and the axis of rotation (8) of the second rotation damper (6) are aligned approximately perpendicular to one another.

2. Trackball operating device according to claim 1, characterized in that the first rotation damper (5) has a first friction wheel (9) rotatably mounted about its axis of rotation (7) and the second rotary damper (6) has a second rotatably mounted about its axis of rotation (8). Have a friction wheel (10), the friction wheels (9, 10) each being in operative connection with the surface of the ball (2).

3. Trackball operating device according to claim 2, characterized in that a corresponding braking torque or a corresponding braking force is applied to the ball (2) via the friction wheels (9, 10) of the rotation damper (5, 6) to generate haptic perceptions for the operator is transferable.

4. Trackball operating device according to claim 2 or 3, characterized in that a braking torque or braking force component acting in the X direction based on a coordinate system can be transferred to the ball (2) via the first friction wheel (9) of the first rotation damper (5). and that a braking torque or braking force component acting in the Y direction based on the coordinate system can be transferred to the ball (2) via the second friction wheel (10) of the second rotation damper (6).

5. Trackball operating device according to one of the preceding claims, characterized in that rotation dampers (5, 6) functioning on a magnetorheological basis are provided.

6. Trackball operating device according to one of the preceding claims, characterized in that the ball (2) is assigned at least one spring-loaded compensating friction wheel (11).

7. Vehicle (1) with at least one trackball operating device according to one of the preceding claims.