OPERATING MEMBER WITH MOVABLY MOUNTED ACTUATING PART AND IMPROVED GUIDANCE MECHANISM FOR THE PARALLEL GUIDANCE OF THE ACTUATING PART

Abstract

The present disclosure relates to an operating member including: a support; an actuating part, which defines an actuating surface is mounted on the support by a mount to be movable relative to the support, by manual actuation against a resetting force, while carrying out an actuating movement from a rest position into a depressed position; a detector having at least one force sensor, wherein the detector is adapted to detect at least one position of the actuating part; wherein the mount includes a guidance mechanism having at least one pair of coupled levers, wherein the levers are each pivotably mounted on the support by a first pivot joint and on the actuating part—by a second pivot joint to cause a pivoting movement of the at least one pair of coupled levers by the actuating movement, wherein the guidance mechanism further includes at least one coupling rod.

Claims

1. An operating member, comprising: a support; an actuating part, which defines an actuating surface is mounted on the support by a mount to be movable relative to the support, by manual actuation against a resetting force, along an actuation direction while carrying out an actuating movement from a rest position into a depressed position; a detector having at least one force sensor, wherein the detector is adapted to detect at least one position of the actuating part; wherein the mount includes a guidance mechanism having at least one pair of coupled levers, wherein the at least one pair of coupled levers are each pivotably mounted, on the one hand, on the support by a first pivot joint defining at least one first pivot axis and, on the other hand, on the actuating part by a second pivot joint defining at least one second pivot axis, in order to cause in each case a pivoting movement of the at least one pair of coupled levers by the actuating movement, wherein the guidance mechanism further includes at least one coupling rod in order to couple the pivoting movement of the at least one pair of coupled levers; wherein the at least one coupling rod is fixed to the at least one pair of coupled levers in an articulated manner, in each case by a first flexure joint, while defining a joint axis, and at least one pivot joint among the first pivot joint and the second pivot joint of each lever of the at least one pair of coupled levers is configured as a second flexure joint.

2. The operating member according to claim 1, wherein the first flexure joint and the second flexure joint of the at least one pair of coupled levers of each pair are configured to cause the resetting force causing a reset into the rest position by their elastic deformation.

3. The operating member according to claim 1, wherein the mount has a component which is fixed to the support or the actuating part and which is integrally connected to the respective lever of the at least one pair of coupled levers in each case via the first pivot joint or the second pivot joint configured as the second flexure joint.

4. The operating member according to claim 1, wherein the mount includes an integrally formed molded part, which is manufactured in a thermal molding process.

5. The operating member according to claim 1, wherein the first pivot joint of the at least one pair of coupled levers is configured as a rotary joint, and the second pivot joint of the at least one pair of coupled levers—as the second flexure joint.

6. The operating member according to claim 1, wherein the at least one pair of the coupled levers are coupled to each other, by the coupling rod, in such a way that their direction of rotation is opposed to the pivoting movement about the at least one first pivot axis, respectively.

7. The operating member according to claim 1, wherein the at least one first pivot axis, the at least one second pivot axis, and the joint axis of each lever of the at least one pair of coupled levers respectively form an angled lever.

8. The operating member according to claim 1, wherein the at least one pair of the coupled levers are configured to match with respect to a dimension of a relative spacing between the associated at least one first pivot axis, the associated at least one second pivot axis, and the associated joint axis.

9. The operating member according to claim 1, wherein the guidance mechanism has a second pair of levers coupled by a second coupling rod.

10. The operating member according to claim 9, wherein a first pair of the at least one pair of coupled levers and the second pair of levers are connected by at least one of: a non-rotatably connection of the first pair of the at least one pair of coupled levers to a lever—of the second pair of levers,—and a non-rotatably connection of the coupling rod of the first pair of the at least one pair of coupled levers to the second coupling rod.

11. The operating member according to claim 1, wherein the actuating part passes through a stroke distance of less than 0.5 cm during the actuating movement from the rest position into the depressed position.

12. The operating member according to claim 1, wherein a maximum extent of the actuating surface corresponds to at least ten times a stroke distance.

13. The operating member according to claim 1, wherein the actuating part has at least one of: a touchpad and a touchscreen.

14. The operating member according to claim 1, wherein the detector has a capacitively detecting force sensor.

15. The operating member according to claim 1 is used in a motor vehicle.

16. The operating member according to claim 1, wherein the at least one position is the depressed position.

17. The operating member according to claim 1, wherein the actuating part passes through a stroke distance of less than 0.3 cm, during the actuating movement from the rest position into the depression position.

18. The operating member according to claim 10, wherein the first pair of the at least one pair of coupled levers and the second pair of levers are connected by a web.

Description

[0027] The disclosed embodiments are explained further with reference to the following Figures. The Figures are to be understood only as examples and each merely represent a preferred embodiment. In the Figures:

[0028] FIG. 1 shows a perspective view of an embodiment of the operating member 1 according to an embodiment,

[0029] FIG. 2 shows a perspective exploded view of the embodiment shown in FIG. 1 without the actuating part;

[0030] FIG. 3 shows a vertical section through the embodiment shown in FIG. 1;

[0031] FIG. 4 shows a side view of the mounting means 11, which is shown in FIG. 1 and produced as a molded part.

[0032] FIG. 1 shows an embodiment of the operating member 1 according to an embodiment. It serves for performing an operating input by means of a movable actuating part 2 within the context of a man-machine interface.

[0033] The operating member 1 according to the embodiment comprises a support 3. The term “support” denotes a component which is a part of a supporting structure or is indirectly or directly fixed, for example, to a motor vehicle component, such as a motor vehicle steering wheel. For example, the support 3 is formed from a plastic, a metal or a metallic alloy, such as ZAMAK, or combinations thereof.

[0034] Further, an actuating part 2 is provided, which has an actuating surface 10 facing towards the operator B, for the operator B to carry out an operating input. An actuating operating input is understood to be an actuation, particularly with a simultaneous contact, by the operator B, which goes beyond a contact, during which the operator B applies an actuating force acting perpendicularly on the actuating surface 10, in order to cause a displacement of the actuating part 2, which follows the actuating force, against a resetting force. In this case, a depressed position is understood to be the maximum possible final position of the actuating part 2, wherein the maximum stroke distance of the actuating part 2, which results from the displacement from the rest position shown in FIG. 1 into the depressed position, is referred as a stroke distance and is less than 0.3 cm.

[0035] Detection means 9 for detecting at least one position, such as the depressed position, of the actuating part 2 are also provided. Here, this is a capacitive force sensor. The latter is configured for capacitively detecting the relative displacement between the actuating 2 part and the support 3, by a determination of a change in measuring capacitance between an electrode fixed to the actuating part 2 and an electrode fixed to the support 3.

[0036] Further, mounting means 11 are provided in order to enable the above-described movability of the actuating part 2 relative to the support 3. According to the embodiment, these mounting means 11 comprise a guidance mechanism 4 for the parallel guidance of the actuating part 3. A parallel guidance is understood to mean that the actuating part 2 undergoes a substantially translational displacement during actuation and that thus, the actuating surface 10 is, for example, displaced along the actuation direction R while maintaining its orientation in space if possible.

[0037] The guidance mechanism 4 comprises two pairs of coupled levers 5, 6 or 5′, 6′, wherein the levers 5, 6; 5′, 6′ are each, on the one hand, mounted on the support 3 and, on the other hand, on the actuating part 2 so as to be pivotable about an associated pivot axis S.sub.1 or S.sub.2, in order to cause in each case a pivoting movement of the levers 5, 6; 5′ 6′ by means of the actuating movement. Due to the perspective view and the masking resulting therefrom, FIG. 1 does not show the mounting means 11 in their entirety. However, the structure of the second pair is identical to that of the first pair, which becomes clear from the detailed view of the further Figures. The guidance mechanism 4 moreover comprises at least one coupling rod 7, 7′ for coupling the pivoting movement of the levers 5, 6; 5′, 6′.

[0038] In this case, the coupling rod 7, 7′ is fixed to the levers 5, 6; 5′, 6′ in an articulated manner, in each case by means of a first flexure joint 16, while defining a joint axis G. In this case, the coupling rod 7, 7′ provides a connection between the levers 5, 6; 5′, 6′ of one pair that can be subjected to tensile and compressive loads and that serves for transmitting the rotary movement about the first pivot axis S.sub.1 from one lever 5, 5′ to the respective other lever 6, 6′ of the pair, wherein the directions of rotation of the levers 5, 6 or 5′, 6′ of a pair are in each case opposite. Due to the fact that the coupling rod 7, 7′ and the levers 5, 6; 5′, 6′ are connected via a first flexure joint 16, the mechanical play of the parallel guidance is minimized. “Lost motion” is avoided. In addition, the parallel guidance can be realized to be free of noise. In order to save constructional space, the first pivot axes S.sub.1 of the levers 5, 6; 5′, 6′ of the guidance mechanism 4, in the rest position of the actuating part 2, are disposed in a common imaginary plane E, which is inclined to the actuating surface 10, as is most apparent from FIG. 3. As FIG. 2 shows, the first pivot joints 13, 14, with which the levers 5, 6; 5′, 6′ are rotatably mounted on the support 3, are configured as rotary joints and have a pin 14 each, which reaches into a correspondingly disposed pin accommodating portion 13 of a bearing support formed on the support 3, thus defining the first pivot axes S.sub.1. In order to enable the lever 5, 6; 5′, 6′ to pivot relative to the actuating part 2, the second pivot joint 18 is provided, which is configured as a first flexure joint.

[0039] The resetting force for resetting the actuating part 2 into the rest position is caused exclusively by the elastic deformation of the first flexure joint 16 and the second pivot joints 18 configured as second flexure joints. The pivot axes S.sub.1, S.sub.2 and the joint axis G of each lever 5, 6; 5′, 6′ each form an angled lever, wherein the axes are disposed on the corners of an imaginary triangle, which has the same shape for all levers 5, 6; 5′, 6′. In other words, the dimension of the relative spacing between the associated first and second pivot axes S.sub.1, S.sub.2 and the associated joint axis (G) is configured to match for all levers 5, 6; 5′, 6′.

[0040] As becomes apparent from FIG. 4, the mounting means 11 are configured as a molded part which is manufactured by a thermal molding process in a molding tool. These mounting means 11 comprise a plate-shaped component 15 that serves for attachment to the actuating part 2 on the side thereof facing away from the actuating surface 10, and the guidance mechanism 4 consisting of levers 5, 6; 5′, 6′, coupling rods 7, 7′, the second pivot joint 18, the pin 14 of the first pivot joint 13, 14 as well as the first flexure joints 16, all of which are formed from a thermoplastic material. The flexure joint 16 is in each case the result of a weakening of the material provided in the transitional region between the respective lever 5, 6; 5′, 6′ and the coupling rod 7, 7′, e.g., with respect to the cross section of the respective coupling rod 7, 7′, a constricted portion. Due to its location, the weakened-material portion provides for a locally pronounced elastic compliance with resetting properties, and thus a resetting flexibility of the coupling rod 7, 7′ in the region of the coupling rod 7, 7′ adjacent to the respective lever 5, 6; 5′, 6′. This also applies, mutatis mutandis, for the second pivot joints 18 configured as a second flexure joint, which are in each case provided between the component 15 and the associated lever 5, 6; 5′, 6′.