DE102016209829A1 - Device for force simulation on an actuating element of a vehicle and electrically actuated clutch system - Google Patents

Abstract

The invention relates to a device for force simulation on an actuating element (2) of a vehicle, which conveys a haptic feedback via a predetermined force-displacement behavior, comprising a holder (4) for pivotally mounting the actuating element (2) on the vehicle, the Holder (4) along an actuating path between a non-actuation position and an actuating position about a pivot axis (5) is pivotally mounted and acts on the restoring force of a return spring (6) in the direction of its non-actuation position, and at least one friction element (9), during pivoting of the Operating element (2) along the actuation path against an arcuate friction surface (10) rubs, wherein the friction element (9) against the friction surface (10) is spring-loaded. The friction surface (10) has at least one cam (13), wherein the friction surface (10) and the friction element (9) move relative to each other upon actuation of the actuating element (2) along the actuation path such that the friction element (9) runs along the arcuate friction surface (10) moves at least on or over the cam (13). The invention further relates to an electrically actuated clutch system for vehicles with such a device for force simulation on an actuating element.

Description

The present invention relates to a device for force simulation on an actuating element of a vehicle, preferably a pedal force simulator, according to the preamble of claim 1 and an electrically actuated clutch system according to the preamble of claim 10.

In the drive train of a motor vehicle, for example a passenger vehicle or the like, as well as in motorcycles there is a friction clutch, which serves both as a starting element and as a switching element. To actuate the clutch by the driver of the vehicle hydraulically actuated clutches have prevailed in the past.

In such a clutch actuation system, an actuator in the form of, for example, the driver-operated clutch pedal or, in the case of a motorcycle, a clutch lever is provided, wherein the driver of the vehicle actuates the clutch pedal to open the clutch with the foot or the motorcycle with the clutch lever the hand pulls in the direction of the handlebar handle. Here, a hydraulic fluid is displaced by the clutch master cylinder, whereby a hydraulic pressure is generated, which in turn is used by the clutch slave cylinder to open the clutch.

From the prior art, it is already known to implement the specifications of a driver electronically, for example, so-called "brake-by-wire", "drive-by-wire" or "clutch-by-wire", that is, the electronic implementation a driver's brake request, a load request or a clutch request specified by the driver with a gas actuation element, without a mechanical connection between a brake actuation element (eg brake pedal), a gas actuation element (eg accelerator pedal) or a clutch actuation element (eg clutch pedal) with its associated actuator, that is, a vehicle brake system, a load control member of a vehicle drive unit or a vehicle clutch consists. For this purpose, the driver specification is received only by means of a position sensor on the corresponding actuator, then further processed, for example by an electronic control device and finally implemented by a suitable actuator, which is powered by auxiliary energy. Since the actuating element only supplies an electrical signal, suitable measures are to be provided on the actuating element, for example the brake pedal, accelerator pedal and / or clutch pedal, with the aid of which a normal operating feeling for the driver is generated during actuation of the actuating element.

For example, from the US 2007/0234842 A1 an electronically controllable accelerator pedal of a vehicle with kickdown function known, which gives a driver a haptic feedback via a predetermined force-displacement behavior. For this purpose, the accelerator pedal is pivotally mounted on the vehicle, wherein with the accelerator pedal, a friction element is connected, which rubs when pivoting the accelerator pedal against an arcuate, first friction surface. Further, a second friction surface is provided, which connects to the first friction surface via a Reibflächenstufe whose overcoming by the friction requires a higher force on the accelerator pedal, whereby the driver is given a haptic feedback in the activation of the kickdown function.

In the DE 101 05 265 A1 a restoring device for pedals of a motor vehicle is described in which the pedal is fixed via a spring element pivotally mounted on a vehicle body. A friction element is also connected to the pedal, which rubs along a friction surface provided on the body when the pedal is actuated.

From the DE 10 2012 217 541 A1 is a clutch pedal device with a rotatably mounted clutch pedal and means for generating a predetermined course of the pedal force on the pedal travel known. The progression of the pedal force over the pedal travel also includes a section of negative slope after a positive slope section. The means for generating the predetermined force-displacement curve provide that the pedal arm acts on an acted upon by a counter force, rotatably mounted lever arm and is moved on actuation of the clutch pedal on a contour of the lever arm.

The DE 10 2011 075 603 A1 describes an accelerator pedal unit for motor vehicles, wherein a brought about by a corresponding actuation force change in position of the pedal plate against its initial position against a restoring force of a return spring to increase the driving force of a motor and with decreasing actuating force, the restoring force of the return spring, the pedal plate in the direction of its initial position. There are further provided means which generate a hysteresis of the pedal characteristic, wherein the means are designed as a friction element and cooperating with the friction friction surface. The friction element is spring-loaded against the friction surface. The friction surface is connected to the pedal plate and is rotated relative to the friction element upon actuation of the pedal plate.

The WO 2015/165451 A1 discloses a device for force simulation on an actuator of a vehicle with a piston-cylinder unit. A working piston is connected via a piston rod to the actuating element, which moves the piston axially within the cylinder. A resistance element projects perpendicularly to the direction of movement of the piston into which the piston is moved in a frictional manner as a function of the position of the actuating element.

From the EP 2 896 539 A2 a system for pedal force simulation for a clutch actuation system is known in which the pedal is actuated with a pedal force and is operatively connected to a, in a housing against a restoring force of a return spring axially displaceable piston. The position of the pedal is detected by a sensor and forwarded to the actuator actuating the clutch. The piston is operatively connected to at least one further resilient element, which provides a hysteresis with increasing and decreasing force curve.

Furthermore, the describes DE 11 2012 001 380 T5 an electronic clutch assembly that provides a realistic pedal feel, with the resistance on the clutch pedal rising to the release point of the clutch and the resistance on the clutch pedal decreasing after the release point of the clutch. For this purpose, a both rotatable and compressible tensioning device is provided between a clutch pedal arm and a Pedalarmhalterung.

From the DE 10 2007 018 962 A1 Furthermore, a stationary clutch pedal for a motor vehicle is known, which comprises a position sensor, on the basis of whose signals a clutch provided in the vehicle drive train is electronically controlled and actuated accordingly by means of an auxiliary energy-supplied actuator. There are provided on the clutch pedal engaging spring elements for generating a pedal force characteristic that reproduces the noticeable pedal force for the driver via the pedal travel, so that the pedal force characteristic starting from the neutral position of the clutch pedal shows a first steadily increasing course of the actuating force to a maximum force and then thereto in a degressive course passes, wherein an over-center spring is provided for generating this pedal force characteristic in addition to a pressure pedal moving the clutch pedal in its neutral position. Further, a speed-dependent damper is mounted between the clutch pedal and the pedal block.

A later attachable to a pedal device damper unit to impart a more natural pedaling feeling is in the US 2014/0217658 A1 disclosed. The damper unit is mounted below the pedal arm and rotated by the operation of the pedal arm, which in turn generates a torque acting on the pedal arm.

The EP 1 645 769 A2 describes a device for actuating a clutch via an actuating lever wherein the actuating lever acts on a clutch master cylinder, via which the force acting on a clutch slave cylinder to disengage the clutch can be controlled. Between the actuating lever and the clutch master cylinder, a transmission for generating a variable over the actuating travel of the actuating lever transmission ratio of the power transmission path is arranged.

Against this background, the present invention has for its object to provide a device for force simulation on an actuating element of a vehicle, which gives the actuation actuating user, for example a driver, the same feeling as when the actuating element for actuating a mechanically connected thereto For example, hydraulic plant would be used. In addition, the device should be easy to manufacture and compact build. Furthermore, an electrically operated clutch system of a vehicle with the same advantageous properties to be shown.

This object is achieved by a device for force simulation with the features of claim 1 and by an electrically actuated clutch system with the features of claim 10. Further particularly advantageous embodiments of the invention disclose the respective subclaims.

It should be noted that the features listed individually in the following description can be combined with one another in any technically meaningful manner and show further embodiments of the invention. The description additionally characterizes and specifies the invention, in particular in connection with the figures.

According to the invention, a device for force simulation on an actuating element of a vehicle, which conveys a haptic feedback via a predetermined force-displacement behavior, comprises a holder for the pivotable attachment of the actuating element to the vehicle. The actuator, such as an operating lever or a pedal, is mounted on the support along an actuation path between a non-actuation position and an actuation position Swiveling axis pivotally mounted. On the actuating element also acts a restoring force of a return spring in the direction of its non-actuating position. Furthermore, at least one friction element is provided, which rubs against an arcuate friction surface along the actuating path during pivoting of the actuating element. The friction element is also spring-loaded against the friction surface. According to the invention, the friction surface comprises at least one cam, wherein upon actuation of the actuating element along the actuation path the friction surface and the friction element move relative to each other such that the friction element moves along the arcuate friction surface at least on or over the cam.

In this case, a cam is understood in particular to be a substantially rounded projection on the otherwise flat and arcuate friction surface. In particular, such a cam preferably has a rising flank, a maximum and a falling flank with respect to the friction surface, so that the cam results in an increase in or on the friction surface.

Since, during the actuation of the actuating element along the actuation path between the non-actuation position and the actuation position, the friction element rubs against the friction surface, is spring-loaded against the latter and moves at least over the cam, preferably beyond, there results a frictional force profile dependent on the actuation angle of the actuation element. In combination with the restoring force of the return spring, which changes linearly with the actuation angle of the actuation element, the actuation element as a whole has a reaction force which substantially corresponds to the reaction force that an operator of the actuation element would feel when using a conventional, for example, hydraulic system the operation would be mechanically coupled.

Since the friction surface according to the invention also extends arcuately curved, the device according to the invention can build more compact than would be the case with a linearly extending friction surface. In particular, in the case according to the invention, either the at least one friction element can thus be moved along the curved friction surface in a circular path with the friction surface resting relative to the holder, or the curved friction surface can be rotated past the friction element, in which case Friction element in the direction of movement of the friction surface could rest on the bracket.

According to an advantageous embodiment of the invention, the at least one friction element on the holder with respect to the arcuate friction surface is resiliently mounted radially movable and the friction surface is connected to the actuating element on the holder superimposed, rotatable about the pivot axis, rotatably connected to the actuator axle. Accordingly, the friction surface rotates upon actuation of the actuating element along the actuation path about the pivot axis. This provides a compactly constructed and easy to manufacture device, since the at least one friction element must be supported only radially to the curved friction surface and biased by a spring element against the friction surface on the holder while the friction surface due to the actuation of the actuating element about the pivot axis on the friction element is turned over.

A still further advantageous embodiment of the invention provides that each have a friction surface and at least one friction element are arranged at each axial end of the axle. This makes it possible to double in a simple and compact manner during operation of the actuator acting on this frictional force or reduce the contact force at the same Gesamtreibkraft between each spring-loaded friction and the respective friction surface, so as to minimize wear of the friction and thus the life and increase durability of the device according to the invention.

As already explained above, the friction surface according to the present invention is arcuately curved. In a particularly advantageous embodiment of the invention, the friction surface may be curved in accordance with a circular arc. However, for example, it may also be elliptical, parabolic, hyperbolic and the like curved.

According to an advantageous embodiment of the invention, the friction surface is formed by an outer peripheral surface of a cam disk forming at least one circular sector or by an inner peripheral surface of a cam ring forming at least one circular arc. In the first case, the at least one friction element is resiliently biased radially from the outside against the outer peripheral surface of the cam disk. In the second case, the at least one friction element is resiliently biased radially from the inside against the inner peripheral surface of the cam ring. In both cases, both the cam and the cam ring can be rotatably mounted on the holder of the actuating element and rotated as a result of the actuation of the actuating element, so that they rotate past the corresponding, at least one friction element, or the respective, at least one Friction member may be rotatably mounted around the cam or within the cam ring on the holder of the actuating element and move along as a result of the actuation of the actuating element on the provided by the cam or the cam ring friction surface.

According to yet another advantageous embodiment of the invention, at least two friction elements are provided and the friction surface is formed as a completely circumferential cylinder jacket surface on which at least two diametrically arranged cams are arranged. Here, the friction elements are also arranged so diametrically and each associated with a cam that move upon actuation of the actuating element along the actuation path, the friction surface and each friction such relative to each other, that in each case a friction along the friction surface at least on or over its associated cam emotional. As a result, it is possible in a simple and compact manner to increase the frictional force acting on the actuation element during this operation, or to reduce the contact force with the same total frictional force between each spring-loaded frictional element and the frictional surface so as to minimize wear of the frictional elements and thus the service life and durability to increase the device according to the invention.

A further advantageous embodiment of the invention provides that the side of the friction element facing the friction surface has a contour that is concave with respect to the friction surface. In this way, the side of the at least one friction element facing the friction surface can be substantially adapted to the shape of the cam of the friction surface, so that a more controllable force curve of the friction between the friction element and the friction surface results, if the friction element acts on the cam or moved over it.

Likewise, during the actuation of the actuating element, the force profile of the friction between the at least one friction element and the friction surface can be improved in particular in the course of the movement of the friction element on or over the cam of the friction surface, in accordance with a still further advantageous embodiment with respect to the direction of movement of the friction element Reibelements to the friction surface defined front and / or back of the friction element is provided on the friction surface facing side of the friction element, each with a chamfer. The bevel or chamfer of the friction element on its front and / or rear side allows adaptation to the slope of the rising or falling edge of the cam of the friction surface and thus better control of the frictional force generated on the friction element.

According to a further advantageous embodiment of the invention, at least one plate spring is provided per friction element, which biases the friction element radially relative to the friction surface.

According to a further advantageous embodiment of the invention, the return spring may be a linearly actuated spring element, for example a helical spring. This can be arranged for example in the case of a clutch pedal as an actuating element at the location of the clutch master cylinder of a conventional hydraulic clutch actuator, so that overall results in a compact design of the device according to the invention.

The device according to the invention for force simulation on the actuating element is preferably a pedal force simulator of a motor vehicle.

In accordance with another aspect of the invention, there is provided an electrically actuated clutch system for vehicles that includes an actuator, such as a clutch pedal or a clutch lever, provided with a force simulation device on the actuator. Here, the operating position of the actuating element is detected by a sensor unit and electrically transmitted to a control unit, which is in operative connection with a clutch of the vehicle in order to actuate it by means of a suitable actuator. The device for force simulation is designed according to one of the previously described embodiments. Further embodiments of the electrically actuated clutch system, their effects and advantages are directly apparent from the above description of the device according to the invention for force simulation on the actuating element, which can be applied mutatis mutandis to the invention, electrically actuated clutch system.

Further features and advantages of the invention will become apparent from the following description of a non-limiting embodiment of the invention, which will be explained in more detail below with reference to the drawings. In these drawings show schematically:

1 3 a perspective side view of a device for force simulation on an actuating element of a vehicle according to an embodiment of the invention from the right,

2 a perspective side view of the device 1 from the left,

3 an enlarged, side cutaway view of the device 1 in the area of the pivot axis, and

4 Force-displacement curves to explain the operation of the device 1 ,

In the different figures, equivalent parts are always provided with the same reference numerals with respect to their function, so that these are usually described only once.

1 represents a perspective side view of a device 1 for force simulation on an actuator 2 a vehicle (not shown) according to an embodiment of the invention from the right and 2 a perspective side view of the device 1 from the left. As 1 it can be seen, is the actuator 2 the illustrated embodiment, a pedal arm 2 , which at a free end a pedal plate 3 for actuating the pedal arm 2 by a driver of the vehicle with his foot (not shown). At the in 1 illustrated embodiment of the device according to the invention 1 it is the actuating element 2 in particular, a clutch pedal for electrically actuating a clutch system of the vehicle.

At its end opposite the free end of the pedal arm 2 is the actuator 2 swiveling with a bracket 4 connected. The holder 4 serves to attach the actuator 2 on the vehicle, for example, by being able to fix it to, for example, a body part of the vehicle.

The actuator 2 or the pedal arm 2 is on the bracket 4 along an actuation path between a non-actuation position, in which the actuation element 2 is not actuated and is in its neutral position, and an actuating position in which the actuating element 2 is depressed to a pivot axis 5 pivoted.

Furthermore acts on the actuator 2 a restoring force of a return spring 6 towards his inactive position. Advantageously, the return spring 6 in the illustrated embodiment of the device according to the invention 1 a linearly actuable return spring 6 such as, for example, a compression spring extending axially substantially in a straight line (eg helical spring). This is at the in 1 shown device 1 arranged at the same location at which would be arranged in a conventional hydraulic clutch system, the clutch master cylinder. Thus, in an electrically actuated clutch system no longer required space for the clutch master cylinder in an advantageous manner to the arrangement of the return spring 6 be used, resulting in a compact design of the device 1 allows.

As already mentioned above, it is in the actuator 2 of in 1 illustrated embodiment of the device 1 a clutch pedal for electrically actuating a clutch system of the vehicle. For this purpose, the operating position of the actuating element 2 from a sensor unit 7 detected and electrically to a control unit 8th passed, which is in operative connection with a clutch of the vehicle (not shown), these by means of a suitable actuator (also not shown) corresponding to the operating position of the actuating element 2 to press.

Like that 1 and 2 can be seen, are on both the right and on the left side of the pivot bearing of the actuator 2 on the bracket 4 four friction elements each 9 concentric and circumferentially equally distributed, that is diametrically, about the pivot axis 5 arranged. The friction elements 9 are against an arcuate friction surface 10 spring-loaded. When pivoting the actuating element 2 around the pivot axis 5 rub the friction elements 9 on the friction surface 10 due to a relative movement between the friction elements 9 and the friction surface 10 ,

More detailed is the arrangement and design of the friction elements 9 and the friction surface 10 in the in 3 shown lateral cutout view in the region of the pivot axis 5 shown. 3 it can be seen that concentric to the pivot axis 5 one around the pivot axis 5 rotatable axle bolt 11 on the bracket 4 is stored. At the axle bolt 11 is the actuator 2 rotatably connected, so that the axle bolt 11 upon actuation of the actuator 2 in the holder 4 around the pivot axis 5 rotates. Furthermore, the friction surface 10 non-rotatably with the axle bolt 11 connected so that the friction surface 10 upon actuation of the actuator 2 with the axle bolt 11 also around the swivel axis 5 rotates.

At the in 3 illustrated embodiment of the device according to the invention 1 is further to realize that the friction surface 10 from an outer circumferential surface of a cam in the side view forming a full circle 12 is formed. Thus, the friction surface extends 10 in this embodiment along a circular arc, as the friction surface 10 as completely circumferential cylindrical outer surface of the cam disc 12 is trained. The cam disk 12 points on its outer peripheral surface, that is, the friction surface 10 , a total of four cams 13 on. The cams 13 are similar to the friction elements 9 along the outer circumference of the cam disc 12 evenly distributed, that is diametrically, arranged. Every cam 13 forms with respect to the in itself flat and arcuate friction surface 10 a substantially rounded projection.

The friction elements 9 are in the tangential direction of the friction surface 10 fixed to the bracket 4 stored and in the radial direction to the friction surface 10 radially movable and resilient against the friction surface 10 biased. For resilient bias of the friction elements 9 is in the illustrated embodiment of the device 1 per friction element 9 one plate spring each 14 intended. Other spring elements, for example, leaf springs or coil spring, or even several spring elements per friction element 9 can also be used.

Furthermore is 3 can be seen that in the illustrated embodiment of the device 1 the friction surface 10 facing side of each friction element 9 a with respect to the friction surface 10 concave contour 15 having. In addition, at the in 3 illustrated device 3 with respect to the direction of movement of the friction element 9 to the friction surface 10 (tangential direction to the friction surface 10 ) defined front and back of each friction element 9 at the friction surface 10 facing side of the friction element 9 each with a chamfer 16 Mistake.

In the 3 shown position of the friction elements 9 and the friction surface 10 corresponds to the non-actuated state of the actuator 2 , In this state, the friction elements are 9 against the circular arc-shaped and flat friction surface 10 on, as in 3 is shown. In the embodiment of the device 1 corresponds to the total possible actuating travel of the actuating element 2 a rotation of the axle bolt 11 about 35 °.

Will now be the actuator 2 operated in the direction of its operating position, rotates in the representation of 3 the cam disk 12 about 35 ° clockwise. This rubs each friction element 9 initially with constant contact pressure (= constant friction force) along the arcuate, flat friction surface 10 until each friction element 9 one cam each 13 reached. To further rotation of the cam 12 on the cam 13 to arrive, every friction element 9 in the radial direction relative to the friction surface 10 moved outward, causing the through each diaphragm spring 14 provided bias on each friction element 9 as long as increases to the maximum of the cam 13 is reached. This increases the between the friction surface 10 and the respective friction element 9 effective friction force.

The at the device 1 provided bevel 16 or chamfering each friction element 9 on its front side allows adaptation to the slope of the rising flank of each cam 13 the friction surface 10 and thus better control of the on each friction element 9 generated frictional force. Similarly, this allows the shape of each cam 13 adapted concave contour 15 on the friction surface 10 facing side of each friction element 9 a more controllable force curve of the friction between the friction element 9 and the friction surface 10 when the friction element 9 on the cam 13 emotional.

Once the maximum of each cam 13 upon further rotation of the cam disc 12 until reaching the maximum operating position of each friction element 9 is overcome, the sinking at each friction element 9 acting frictional force between the friction element 9 and the friction surface 10 as that through each plate spring 14 generated bias of each friction element 9 as a result of its inward on the friction surface 10 facing radial movement decreases. Again, the bevel allows 16 every friction element 9 on its back, an adjustment to the slope of the falling edge of each cam 13 the friction surface 10 and thus better control of the on each friction element 9 generated frictional force.

When you release the actuator 2 the in turns 3 illustrated cam 12 as a result of the on the actuator 2 acting restoring force of the return spring 6 ( 1 and 2 ) counterclockwise until the non-actuating position or starting position of the actuating element 2 is reached again. The in the return path of the cam 12 generated friction between the friction elements 9 and the friction surface 10 leads to a on the actuator 2 perceptible lower total force than on the way, resulting in a desired hysteresis effect on the actuator 2 adjusted force-displacement curve sets.

The manner described herein on the actuator 2 generated force-displacement behavior of the device 1 corresponds in a very good approximation to the force curve on the actuator 2 from one the actuator 2 actuable user is noticeable when the actuator 2 would be used to actuate a hydraulically operated clutch.

In 4 are the force-displacement curves of the device corresponding to the foregoing description 1 out 1 applied. Here, the abscissa corresponds to the pedal travel 17 of the actuating element 2 in millimeters and the ordinate corresponds to the force in Newton.

In the 4 illustrated curve 19 corresponds to the Reibkraftverlauf of the flat, circular arc-shaped friction surface 10 rubbing friction elements 9 , This is for the round trip of the operation of the actuator 2 equal and constant.

The curve 20 describes the friction force curve of the friction element 9 during the rubbing motion along a cam 13 for the way of actuation of the actuator 2 (Movement of the actuator 2 from the non-actuating position to the operating position). As described above, the force curve increases with the movement of the friction element 9 along the rising flank of the cam 13 initially, reaches a maximum force and falls during the movement along the descending flank of the cam 13 back to its original value.

The curve 21 describes the friction force curve of the friction element 9 during the rubbing motion along a cam 13 for the return path of the actuation of the actuating element 2 (Movement of the actuator 2 from the operating position to the non-actuating position). Qualitatively, the curve corresponds 21 the course of the curve 20 However, the frictional force of the curve 21 opposite the curve 20 due to the between the friction elements 9 and the friction surface 10 generated friction decreases (hysteresis).

In the 4 illustrated curve 22 represents the linear force curve of the return spring 6 generated spring force for the way the actuation of the actuator 2 dar. The curve 23 represents the linear force curve of the return spring 6 generated spring force for the return path of the actuation of the actuating element 2 Here, too, arises due to internal friction of the return spring 6 (For example, a helical compression spring) a hysteresis of this force curve.

The curve 24 represents the total force curve resulting from the addition of the individual force curves of the curves 19 . 20 and 22 for the way of actuation of the actuator 2 results. The curve 25 represents the total force curve resulting from the addition of the individual force curves of the curves 19 . 21 and 23 for the return path of the actuation of the actuating element 2 gives (hysteresis).

The maximum possible pedal travel 17 (eg when reaching an end stop) is through the curve 26 illustrated.

Like that 1 and 2 it can be seen are at both axial ends of the axle bolt 11 that is on both sides of the actuator 2 , one friction surface each 10 and four friction elements 9 arranged as described above. Overall, the embodiment of the device 1 thus two friction surfaces 10 and a total of eight friction elements 9 on. In this way, the contact pressure per friction element can be 9 on the friction surface 10 and thus the wear or the wear of the friction elements 9 significantly reduce, so that the device 1 has a longer life and durability.

Preferably, the friction elements 9 made of a POM material (polyoxymethylene), with which in the embodiment of the device shown in FIGS 1 at least at least 1 , 2 million cycles of operation of the device 1 can be achieved.

The above-described force-simulation apparatus according to the invention and the electrically actuated clutch system according to the invention are not limited to the embodiment disclosed herein, but also include similar further embodiments.

In particular, for example, a reversal of movement of the friction surface and friction element is conceivable in which instead of the friction surface, the at least one friction element rotates about the pivot axis of the actuating element, in which case the friction surface rests with respect to the holder. In this case, the at least one friction element would be non-rotatably connected, for example, with the axle pin, so that an actuation of the actuating element would cause a rotation of the at least one friction element.

In addition, the device according to the invention is not limited to use on clutch actuators for electronically controlling a clutch system of a vehicle, but of course can generally be used to control vehicle operation, including, for example, electronic brake control, electronic acceleration control, or any other electronic control using an actuator in which a haptic feedback is to be simulated via a predetermined force-displacement behavior of a conventional, mechanical coupling of the actuating element with its actuator.

In a preferred embodiment, the inventive device for force simulation is used on an actuating element of a vehicle for the electrical actuation of a clutch system of the vehicle.

LIST OF REFERENCE NUMBERS

1

 Device for force simulation

2

 Actuator, pedal arm

3

 pedal plate

4

 bracket

5

 swivel axis

6

 Return spring

7

 sensor unit

8th

 control unit

9

 friction

10

 friction surface

11

 axle

12

 cam

13

 cam

14

 Belleville spring

15

 Concave contour

16

 chamfer

17

 pedal travel

18

 force

19

Reibkraftverlauf of 9 along 10 (plane section)

20

Reibkraftverlauf of 9 along 13 (Way)

21

Reibkraftverlauf of 9 along 13 (Way back)

22

Force course of 6 (Way)

23

Force course of 6 (Way back)

24

Total power output 19 . 20 . 22 (Way)

25

Total power output 19 . 21 . 23 (Way back)

26

 Maximum pedal travel

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2007/0234842 A1 [0005]
• DE 10105265 A1 [0006]
• DE 102012217541 A1 [0007]
• DE 102011075603 A1 [0008]
• WO 2015/165451 A1 [0009]
• EP 2896539 A2 [0010]
• DE 112012001380 T5 [0011]
• DE 102007018962 A1 [0012]
• US 2014/0217658 A1 [0013]
• EP 1645769 A2 [0014]

Claims (10)

Device for force simulation on an actuating element ( 2 ) of a vehicle, which conveys a haptic feedback via a predetermined force-displacement behavior, comprising a holder ( 4 ) for pivotally mounting the actuating element ( 2 ) on the vehicle attached to the bracket ( 4 ) along an actuation path between a non-actuation position and an actuation position about a pivot axis (FIG. 5 ) is pivotally mounted and on the one restoring force of a return spring ( 6 ) acts in the direction of its non-actuating position, and at least one friction element ( 9 ), which during pivoting of the actuating element ( 2 ) along the actuation path against an arcuate friction surface ( 10 ), wherein the friction element ( 9 ) against the friction surface ( 10 ) is spring-loaded, characterized in that the friction surface ( 10 ) at least one cam ( 13 ), wherein upon actuation of the actuating element ( 2 ) along the actuation path the friction surface ( 10 ) and the friction element ( 9 ) move relative to each other so that the friction element ( 9 ) along the arcuate friction surface ( 10 ) at least on or over the cam ( 13 ) moved away. Apparatus according to claim 1, characterized in that the at least one friction element ( 9 ) on the bracket ( 4 ) with respect to the arcuate friction surface ( 10 ) is mounted resiliently radially movable and the friction surface ( 10 ) with an actuating element ( 2 ) on the bracket ( 4 ) stored around the pivot axis ( 5 ) rotatable, with the actuating element ( 2 ) rotatably connected axle ( 11 ), so that the friction surface ( 10 ) upon actuation of the actuator ( 2 ) along the actuation path about the pivot axis ( 5 ) turns. Apparatus according to claim 1 or 2, characterized in that at each axial end of the axle ( 11 ) each have a friction surface ( 10 ) and at least one friction element ( 9 ) are arranged. Device according to one of the preceding claims, characterized in that the friction surface ( 10 ) of an outer peripheral surface of at least one circular sector forming cam disc ( 12 ) or is formed by an inner peripheral surface of a cam ring forming at least one circular arc. Device according to one of the preceding claims, characterized in that at least two friction elements ( 9 ) are provided and the friction surface ( 10 ) is formed as a completely circumferential cylinder jacket surface on which at least two diametrically arranged cams ( 13 ) are arranged, wherein the friction elements ( 9 ) are also arranged so diametrically and in each case a friction element ( 9 ) such a cam ( 13 ) is assigned, that upon actuation of the actuating element ( 2 ) along the actuation path the friction surface ( 10 ) and each friction element ( 9 ) move relative to each other so that in each case a friction element ( 9 ) along the friction surface ( 10 ) at least on or over its associated cam ( 13 ) moved away. Device according to one of the preceding claims, characterized in that the friction surface ( 10 ) facing side of the friction element ( 9 ) one with respect to the friction surface ( 10 ) concave contour ( 15 ) having. Device according to one of the preceding claims, characterized in that with respect to the direction of movement of the friction element ( 9 ) to the friction surface ( 10 ) defined front and / or back of the friction element ( 9 ) at the friction surface ( 10 ) facing side of the friction element ( 9 ) each with a chamfer ( 16 ) is provided. Device according to one of the preceding claims, characterized in that per friction element ( 9 ) at least one disc spring ( 14 ) is provided which the friction element ( 9 ) relative to the friction surface ( 10 ) biases radially against them. Device according to one of the preceding claims, characterized in that the return spring ( 6 ) is a linearly actuable spring element. Electrically operated clutch system for vehicles with an actuating element ( 2 ) equipped with a device ( 1 ) for force simulation on the actuating element ( 2 ), wherein the actuating position of the actuating element ( 2 ) from a sensor unit ( 7 ) and electrically connected to a control unit ( 8th ), which is operatively connected to a coupling of the vehicle, characterized in that the device ( 1 ) is designed for power simulation according to one of the preceding claims.

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