EP3931469A1 - Actuating mechanism, in particular for a clutch actuator - Google Patents

Abstract

The invention relates to an actuating mechanism for a clutch actuator, comprising: - a transmission element (1) which is designed so as to be movable in parallel with an actuation direction (X); - an actuating element (6) which is designed to have an actuating force applied thereto; and - a wedge element (3) which is arranged between the transmission element (1) and the actuating element (6) and, when an actuating force is applied to the actuating element (6), is designed to increase a contact force between the wedge element (3) and the transmission element (1) such that the actuating force can be transmitted to the transmission element (1) and therefore the transmission element (1) can move in the actuation direction (X). The actuating mechanism is designed such that, if no actuating force is acting on the actuating element (6), said actuating mechanism reduces the contact pressure between the transmission element (1) and the wedge element (3) in such a way that a relative movement of the transmission element (1) with respect to the actuating element (6) in parallel with the actuation direction (X) is made possible. The invention also relates to a clutch actuator having such an actuating mechanism.

Description

DESCRIPTION

Actuating mechanism in particular for a clutch actuator

The present invention relates to an actuating mechanism for a clutch actuator and to a clutch actuator with such a device

Operating mechanism.

Actuating mechanisms convert an actuating force which on a

Actuator is applied in a shift of a

Transmission element to, for example, disengage a clutch by introducing the displacement into the clutch. However, other technical devices can also be actuated by means of such an actuation mechanism.

Furthermore, under certain conditions, relative movements between the actuating element and the transmission element must be permitted, for example to compensate for wear on the technical device, in particular friction linings of the clutch, thereby avoiding idle travel that would have to be overcome during actuation. The connection between the actuating element and the transmission element must be designed to prevent slipping when actuated, in order to be able to actuate the clutch at any time and in particular to avoid safety-critical situations, such as the undesired engagement of a clutch.

It is therefore the object of the present invention to provide an actuating mechanism of the type described above and a clutch actuator which solve at least one of the problems mentioned above.

This object is achieved by the subjects of the independent claims. Advantageous further developments are the subject of the subclaims. According to the invention, an actuating mechanism for a clutch actuator is provided, comprising:

- a transmission element which is designed to be displaceable parallel to an actuation direction,

an actuating element which is designed to be acted upon by an actuating force and which is designed to be displaceable parallel to the actuating direction, and

- A wedge element between the transmission element and the

The actuating element is arranged and which is designed to increase a contact force between the wedge element and the transmission element when the actuating element is acted upon by an actuating force so that the actuating force can be transmitted to the transmission element so that the transmission element can be shifted in the actuating direction, in which

the actuating mechanism is designed, when no actuating force acts on the actuating element, to reduce the contact pressure between the transmission element and the wedge element in such a way that a relative movement of the

Transmission element opposite the actuating element parallel to the

Operating direction is enabled.

The actuation mechanism is preferably designed so that the actuation force is transmitted from the actuation element to the wedge element. This can be done directly or via elements arranged between the wedge element and the actuating element.

In this way it is achieved that the transmission element at any time

Relative movement to the actuating element or the rest

Can perform actuating mechanism as soon as no actuating force is applied to the actuating element. If the transmission element is designed to operate a clutch, that is, to disengage and engage the clutch, the relative movement of the transmission element can preferably be used to readjust a wear path within the clutch. The contact pressure between the transmission element and the wedge element is preferably so high that a force fit is formed, the maximum force that can be transmitted corresponds to at least the amount of the actuation force. The frictional connection thus preferably creates a clamping between the transmission element and the wedge element.

When the actuating force is applied to the actuating element, the actuating element, the wedge element, the counter element and the transmission element are preferably blocked. I.e. these elements of the

Actuating mechanisms are now shifted by the actuating force as a block, i.e. as a unit, in the actuating direction.

The transmission element is preferably designed as a rod which has an axis that extends parallel to the actuation direction, the rod particularly preferably having a circular cross section. In this way, an arrangement of several wedge elements around the transmission element is possible. In addition, however, other cross-sectional shapes, such as a

rectangular cross-section conceivable.

The wedge element preferably has a support surface which is not oriented parallel and not perpendicular to the actuation direction or the axis of the transmission element. The support surface is preferably designed to generate the pressing force or the clamping when the actuating force is supported. For this purpose, the support surface is preferably designed so that the actuating force on the

Support surface is transmitted, whereby, by the orientation of the support surface to the actuation direction or the axis of the transmission element, a

Force component perpendicular to the direction of actuation or to the axis of the

Transmission element arises, which acts as the contact pressure.

The actuation force is preferably oriented parallel to the actuation direction.

The support surface is preferably designed as part of a conical surface which extends around the direction of actuation or around the axis of the transmission element extends. However, the support surface can also have a different shape. Preferably, the support surface is designed as a plane that leads to the

Operating direction or the axis of the transmission element is inclined.

The direction of actuation or the axis of the transmission element preferably form an angle greater than 0 ° and less than 90 ° with the support surface. This angle is preferably between 5 ° and 45 °, particularly preferably between 10 ° and 35 °. In the case of a support surface which is designed as part of a conical surface, this angle corresponds to half the opening angle of the cone. If the support surface is designed as a plane, this angle corresponds to an angle of inclination of the plane with respect to a horizontally extending plane.

The support surface is preferably designed to act when the

Actuating element to come into contact with the actuating force with a correspondence surface, via which the actuating force can be transmitted, wherein the correspondence surface is formed on a counter element. It can

Counter element both in front of and behind the wedge element in relation to the

Be arranged operating direction.

The contact between the support surface and the corresponding surface is preferably achieved that the introduced into the actuating mechanism

Operating force is at least partially deflected into a pressing force between the wedge element and the transmission element. In this way, clamping preferably begins when the actuating force is sufficiently high.

The correspondence surface is preferably designed as a rotationally symmetrical surface around the direction of actuation or around the axis of the transmission element.

The correspondence surface is preferably designed such that the support surface of the wedge element can come into contact over the entire surface with at least part of the correspondence surface.

The correspondence surface and / or the support surface are preferably designed at least as part of a conical surface or as a plane. The correspondence surface preferably forms the same angle with the

Operating direction or with the axis of the transmission element.

At least one further wedge element is preferably provided. Furthermore, the wedge elements are preferably arranged at a distance from one another around the actuating direction or around the axis of the actuating element, the wedge elements particularly preferably being arranged regularly spaced from one another around the actuating direction or around the axis of the actuating element. A regular one

Spacing allows an even distribution of forces within the

Operating mechanism, which are caused in particular by the operating force.

To create a spacing between the wedge elements, you can

preferably grooves are provided which are parallel to the actuation direction

are formed, each wedge element is particularly preferably guided in its own groove. So the wedge elements are spaced from one another. The grooves can preferably be formed on the transmission element.

Another possibility of realizing a spacing consists in the formation of guides which extend parallel to the direction of actuation and which only give the wedge elements a possibility of movement parallel to the direction of actuation. The guides can be used separately or on any element of the

Actuating mechanism, in particular on the actuating element or the

Counter element, be formed.

The spacing can also take place by means of a cage which contains the wedge elements and is designed to spac them apart from one another. The cage extends around the direction of actuation and allows the wedge elements to be displaced parallel to the direction of actuation. Furthermore, the cage also allows the transmission element to be displaced parallel to the actuation direction if no actuation force is applied to the actuation element. The actuation direction is preferably designed as a straight line.

Preferably, a stop is provided which is designed to with the

Wedge element or to come into contact with the counter element when the wedge element or the counter element is displaced counter to the actuation direction, so that further displacement of the wedge element or the counter element counter to the actuation direction is blocked. The stop is preferably positioned so that a contact force between the support surface of the wedge element and the

Correspondence surface of the counter element is reduced or completely eliminated when the wedge element and the counter element move opposite to the actuation direction and when the wedge element or the counter element rest against the stop. This is achieved in that the element, that is to say the wedge element or the counter-element, which rests against the stop, no longer goes against the

Operating direction can be shifted while the other element, that is, the counter element or the wedge element, which does not bear against the stop, is moved further against the operating direction.

The actuating mechanism is preferably designed so that a clamping between the wedge element and the transmission element is brought about by the pressing force between the wedge element and the transmission element.

The actuating mechanism is preferably designed to bring about the pressing force between the wedge element and the counter-element in response to the application of the actuating force to the actuating element.

The actuating mechanism is preferably designed so that when the contact force is reduced, for example by reducing the actuating force or because one of the elements is supported on the stop, the contact pressure between the transmission element and the wedge element is also reduced, so that at sufficient reduction finally the clamping is released, and that a relative movement of the transmission element relative to the wedge element and relative to the actuating element is made possible. The relative movement can thereby take place with contact of the transmission element with the wedge element, or completely without contact.

If the actuating mechanism is used for a clutch actuator, a possible wear path can be compensated for when the clutch is engaged.

Preferably, the contact between the support surface and the corresponding surface also already exists before the actuation force is applied, with this preferably not causing any clamping between the wedge element and the transmission element.

Preferably, the actuating mechanism is designed to

Actuating element, the wedge element and / or the counter element with an elastic biasing force against the direction of actuation, so that

preferably a movement of at least one of these elements against the

Actuation direction takes place, wherein the elastic preload force is preferably caused by a spring. This elastic pre-tensioning force preferably results in tensioning of the corresponding elements.

The actuation mechanism is further preferably designed so that the elastic preload force counteracts the actuation force. The elastic pre-tensioning force enables a return movement of the interlocked elements of the actuation mechanism to occur as soon as the actuation force is reduced or no longer applies.

The actuating mechanism is further preferably designed to have an elastic biasing force, preferably with an effective direction parallel to the

Operating direction, is provided between the wedge element and the counter element. This elastic pretensioning force is preferably produced by a spring. The pretensioning force can either be designed to brace the wedge element and the counter-element against one another, so that the spring force eliminates any possible play between the support surface and the corresponding surface. This causes an increase in the contact force between the wedge element and the Counter element. In this way, in particular, the initial clamping between the wedge element and the transmission element can be improved, so that the individual elements can be quickly blocked when an actuating force is applied. Alternatively, the biasing force is designed to the wedge element and the

To apply a force to the counter element that drives the two elements apart. As a result, the contact between the support surface and the correspondence surface can be released or at least relieved, if none

Actuating force acts on the actuating element. This causes a reduction in the contact force between the wedge element and the counter element. As a result, the initial clamping between the wedge element and the

Transmission element can be reduced, so that when an actuating force is no longer required, the individual elements can be quickly released.

The transmission element is preferably acted upon by an elastic prestressing force in the actuating direction, which is preferably caused by a spring. This spring is also preferably based on one opposite the

Transmission element fixed point, such as a housing of the

Actuating mechanism or another suitable element. This elastic pretensioning force advantageously ensures that the

Transmission element, if no actuating force is applied to the actuating element, a force is always applied in the actuating direction, so that the transmission element always has a corresponding element to it

Shifting it is designed to stay in contact.

The actuating element is preferably designed to be acted upon by a fluidic actuating force, the actuating element preferably being designed as a piston, particularly preferably as an annular piston, which further

is preferably designed to be displaceable parallel to the actuation direction.

A fluidic actuation force is to be understood in particular as a pneumatically generated actuation force, alternatively also a hydraulically generated one

Operating force is conceivable. Alternatively, the actuating element is also designed to be acted upon by a mechanically, electrically or electromechanically generated actuating force.

In the case of mechanical generation of the actuation force, a linkage can preferably be provided which is designed to apply the actuation force to the actuation element by preferably transmitting a displacement to the actuation element via the linkage. In the case of an electrical or electromechanical generation of the actuation force, actuation means are preferably provided in order to apply the actuation force to the actuation element. An electric motor, a linear motor or a magnetic mechanism, for example, can be provided as the actuation means. When the actuating force is generated mechanically, electrically or electromechanically, the actuating element is not necessarily designed as a piston or ring piston. Rather, it can

The actuating element can only be designed to absorb the actuating force and to support it on the other elements, such as the counter element or the wedge element.

The transmission element is preferably designed to disengage a clutch upon displacement in the actuating direction. For this purpose, for example, one end of the transmission element can be brought into contact with a corresponding point on the coupling.

In a special embodiment of the invention, the actuating element and the counter-element or the actuating element and the wedge element are formed in one piece.

According to the invention, a clutch actuator is also provided, the one

Has operating mechanism as described above. Of the

Actuating mechanism is preferably designed to use the

Transfer element to come into contact with a corresponding element of the clutch in order to disengage it. The clutch is disengaged when the

Transmission element is moved in the actuating direction and thus moves the corresponding element of the clutch. The interaction of the clutch actuator, especially the

Operating mechanism with the clutch can be described as follows. The clutch is not discussed in detail here, since the construction of a clutch is known to the person skilled in the art.

The clutch has a clutch spring which is designed to have a

Establish a frictional connection between an input and an output side of the clutch. By moving the transmission element, the

Clutch spring compressed, whereby the frictional connection is interrupted. The clutch is now disengaged. Wear of the friction linings within the clutch can result in a greater shift to disengage the clutch than when the clutch is not worn. This larger displacement can be achieved by the actuating mechanism or the clutch actuator with it

Compensate the operating mechanism. The transmission element is preferably acted upon by an elastic biasing force in the actuating direction, which is preferably caused by a spring. The elastic pretensioning force has the effect that the transmission element remains in contact with the corresponding point of the coupling. If no actuating force acts on the actuating element, the transmission element can be parallel to the actuating element relative to the

Move direction of actuation. The forces of the clutch spring and the elastic preload force now act against one another via the transmission element. The elastic biasing force or the corresponding spring is preferably designed so that the clutch is always engaged when there is no actuating force on the

Actuating element acts. The clutch spring therefore has a higher one

Spring constant than the spring. As a result, it is advantageously achieved that the transmission element is always tracked to the corresponding point of the clutch, as a result of which a larger displacement that is caused by wear of the clutch is compensated.

The embodiments described so far can be combined with one another as desired in order to obtain further embodiments which likewise have objects which correspond to the objects according to the invention. Below Therefore, preferred embodiments of the invention are described with reference to the accompanying drawings.

In detail shows

1 shows a basic sectional view of an inventive

Operating mechanism, and

2 shows a basic sectional view of a second embodiment of a

operating mechanism according to the invention.

Fig. 1 shows a basic sectional view of an inventive

Operating mechanism.

A transmission element 1 is shown which is designed to be displaceable parallel to an actuation direction X. The direction of actuation X extends horizontally from left to right in the illustration. The transmission element 1 is designed here as a rod which has an axis 1b. In the embodiment shown, the actuation direction X and the axis 1b are coaxial.

At its left end, the transmission element 1 is acted upon by a force from a spring 10, which is oriented in the actuation direction X. The spring 10 is supported at a fixed point. The right end of the transmission element 1 is designed to disengage a clutch (not shown) when it is displaced in the actuation direction X.

An actuating element 6 is also shown, which is designed as an annular piston. For the sake of clarity, only that part of the actuating element 6 has been shown, which is located above the axis 1b. However, the actuating element 6 extends rotationally symmetrically around the axis 1b. It has a

Through opening which is penetrated by the transmission element 1. The actuating element 6 closes a pressure chamber 8 which is formed by a housing 7. The actuating element 6 is sliding and sealing

Housing walls 7a, 7b out. The pressure chamber 8 also has a connection 9 which is designed to be connected to a compressed air source in order to conduct compressed air into the pressure chamber 8. By means of this compressed air, the actuating element 6 can be acted upon by an actuating force from the left. The pressure chamber 8 also extends rotationally symmetrically around the axis 1b, with only the part being shown here which is located above the axis 1b.

A counter-element 11 is formed in one piece with the actuating element 6, which extends to the right from the actuating element 6 in the actuating direction X and which is also penetrated by the transmission element 1. The counter element 11 extends rotationally symmetrically around the axis 1b. It has a through opening through which the transmission element 1 penetrates. For the sake of clarity, however, only that part of the counter-element 11 is shown which is located above the axis 1b. The

On its inside facing the transmission element 1, the counter element 11 has a correspondence surface 11a which extends rotationally symmetrically about the axis 1b and which is conical, the correspondence surface 11a expanding in the actuation direction X.

Between the actuating element 6 and the transmission element 1 is a

Wedge element 3 arranged. This wedge element 3 has at one of the

Transmission element 1 facing away from a support surface 3a, which is designed to come into full surface contact with the corresponding surface 11a. For this purpose, the support surface 3a is accordingly, here as part of a cone jacket,

educated. The wedge element 3 also has a transmission surface 3b which is designed to come into contact with the transmission element 1 or with a contact surface 1a of the transmission element 1.

The embodiment shown has several of these wedge elements 3 which are arranged around the axis 1b, the further wedge elements not being shown for reasons of clarity. These wedge elements are on the same position in the operating direction X as the wedge element 3 shown and are regularly spaced from one another.

Between the wedge element 3 and the counter element 11, a spring 4 is provided which is designed to apply a spring force between the two elements that is oriented parallel to the actuation direction X, so that this spring force moves the wedge element 3 and the counter element 11 towards one another become.

The actuating element 6 is in contact here with a further spring 5, which is supported between the actuating element 6 and a fixed point, for example a part of the housing 7. The spring 5 acts on the actuating element 6 with a force counter to the actuating direction X.

Finally, the actuating mechanism has a stop 2, which is designed to displace the wedge element 3 against the

To block actuation direction X beyond a certain point. The

In the illustration shown, the wedge element 3 rests against the stop 2, so that, starting from the position shown, it can only be moved in the actuation direction X.

In the position shown, in which no actuating force acts on the actuating element 6 and at the same time the wedge element 3 rests against the stop 2, the spring 4 ensures that the counter element 11 and the wedge element 3 or the correspondence surface 11 a and the transmission surface 3a are at least in contact with one another, so that play between the correspondence surface 11 a and the

Transfer surface 3a is avoided, which would first have to be overcome when applying an actuating force to the actuating element 6 before the

Correspondence surface 11 a and the transfer surface 3a are in contact.

The operation of the operating mechanism shown is as follows.

In the illustration shown, the pressure chamber 8 is vented. This will make that

Actuating element 6 is not subjected to an actuating force. Instead it will acted upon by the spring 5 with a restoring force counter to the actuation direction X. At the same time acts on the counter element 11 and thus on the

Actuating element 6 the force of the spring 4, as described above. This in turn is supported on the wedge element 3 and the stop 2. Thus, the forces of the springs 4 and 5 act in opposition to each other, which means that the

Actuating element 6 moved to a position along the actuating direction X at which the forces of the springs 4, 5 are in equilibrium.

This, and in particular the force of the spring 5, ensures that the

Support surface 3a and the corresponding surface 11 a or the contact of these two surfaces is relieved. With an appropriate design of the springs 4, 5, namely, for example, when the spring constant of the spring 5 was chosen to be significantly higher than that of the spring 4, the support surface 3a and the corresponding surface 11a can also detach from one another. The relief of this contact has the consequence that a pressing force between the transmission surface 3b and the contact surface 1a is reduced to such an extent that a relative movement between the transmission element 1 and the actuating element 6 can take place. The transmission element 1 can accordingly move parallel to the actuation direction X, for example to carry out an adjustment movement.

If the pressure chamber 8 is now filled with compressed air via the connection 9, the side of the actuating element 6 which faces the pressure chamber 8 is provided with a

Actuation force applied, which acts in the direction of actuation. As a result, the actuating element 6 is moved in the actuating direction X, as a result of which, as the displacement progresses in the actuating direction X, a pressing force between the support surface 3a and the corresponding surface 11a is increased.

The conical design of the support surface 3a and the corresponding surface 11a also produces a force component that is perpendicular to the

Direction of actuation X is oriented and which is supported as a pressing force in the contact of the transmission surface 3b and the contact surface 1 a. With the increase in

Actuating force is thus also increased the contact force until finally the

Contact pressure is increased such that the actuation force from the actuation element 6 can be transferred to the transmission element 1 via the counter element 11 and the wedge element 3. The transmission of the operating force between the

Wedge element 3 and the transmission element 1 are frictionally engaged.

This has the consequence that the actuating element 6, the counter element 11, the wedge element 3 and the transmission element 1 are blocked so that they can then be moved as a unit in the actuating direction X.

If the actuating force is removed again from the actuating element 6 by venting the pressure chamber 8, the actuating element 6 moves

Counter element 11 and the wedge element 3 by the forces of the springs 4, 5 back into the position shown, while the transmission element 1 due to the now reduced contact force between the transmission surface 3b and the

Contact surface 1a again relative to the actuating element 6 parallel to the

Operating direction X is displaceable, since the frictional engagement has been released again due to the lack of operating force.

Fig. 2 shows a basic sectional view of a second embodiment of an actuating mechanism according to the invention.

A transmission element 1 is shown which is designed to be displaceable parallel to an actuation direction X. The direction of actuation X extends horizontally from left to right in the illustration. The transmission element 1 is designed here as a rod which has an axis 1b. In the embodiment shown, the actuation direction X and the axis 1b are coaxial.

At its left end, the transmission element 1 is acted upon by a force from a spring 10, which is oriented in the actuation direction X. The spring 10 is supported at a fixed point.

The right end of the transmission element 1 is designed to be at a

Shift in actuation direction X to disengage a clutch (not shown). An actuating element 6 is also shown, which is designed as an annular piston. For the sake of clarity, only that part of the actuating element 6 that is located above the axis 1b has been shown. However, the actuating element 6 extends rotationally symmetrically around the axis 1b. It has a

Through opening which is penetrated by the transmission element 1.

The actuating element 6 closes a pressure chamber 8 which is formed by a housing 7. The actuating element 6 is sliding and sealing

Housing walls 7a, 7b out. The pressure chamber 8 also has a connection 9 which is designed to be connected to a compressed air source in order to conduct compressed air into the pressure chamber 8. By means of this compressed air, the actuating element 6 can be acted upon by an actuating force from the left. The pressure chamber 8 also extends rotationally symmetrically around the axis 1b, with only the part being shown here which is located above the axis 1b.

The actuating element 6 strikes a wedge element 3 in the actuating direction X. The wedge element 3 has a support surface 3a, which is at least part of a

Conical surface forms, wherein the support surface 3a is also in

Actuation direction X tapers. The wedge element 3 also has a transmission surface 3b, which is designed to be with the transmission element 1 or with a

Contact surface 1 a of the transmission element 1 to come into contact.

The embodiment shown has several of these wedge elements 3 which are arranged around the axis 1b, the further wedge elements not being shown for reasons of clarity. These wedge elements are located in the same position in the actuation direction X as the wedge element 3 shown and are regularly spaced from one another.

The actuating mechanism also has a counter element 11, which is a

Has correspondence surface 11 a, which is designed as a conical surface and which tapers in the actuation direction X. The counter element 11 extends

rotationally symmetrical around axis 1 b. It has a through opening through which the transmission element 1 penetrates. Because of For clarity, however, only that part of the counter-element 11 is shown which is located above the axis 1b.

The support surface 3a is designed to come into contact over the entire surface with the corresponding surface 11a.

Between the wedge element 3 and the counter element 11, a spring 12 is provided, which is designed to apply a spring force between the two elements, which is oriented parallel to the actuation direction X, so that the wedge element 3 and the counter element 11 are driven apart by this force .

The counter element 11 is here in contact with another spring 5, which is located between the counter element 11 and a fixed point, for example part of the

Housing 7 is supported. The spring 5 acts on the counter element 11 with a force against the actuation direction X.

Finally, the actuating mechanism has a stop 2 which is designed to allow a displacement of the counter element 11 against the

To block actuation direction X. In the illustration shown, the counter-element 11 rests against the stop 2, so that, starting from the position shown, it can only be moved in the actuation direction X.

The spring 5 is made stronger than the spring 12, so that it is ensured that the counter-element 11 rests against the stop 2 when no actuating force acts on the actuating element 6.

The functioning of the operating mechanism shown is as follows.

In the illustration shown, the pressure chamber 8 is vented. This will make that

Actuating element 6 is not subjected to an actuating force. The counter element 11 is pressed against the stop 2 by the spring 5. The wedge element 3 and the actuating element 6 are counteracted by the force of the spring 12

Direction of actuation X moves into the position shown. The force of the spring 12 means that the support surface 3a and the corresponding surface 11a or the contact between these two surfaces is relieved. With a suitable design of the spring 12, the support surface 3a and the corresponding surface 11a can also detach from one another. This has the consequence that a pressing force between the transmission surface 3b and the contact surface 1a is reduced to such an extent that a relative movement between the transmission element 1 and the actuating element 6 can take place. The transmission element 1 can accordingly move parallel to the actuation direction X in order to carry out an adjustment movement, for example.

If the pressure chamber 8 is now filled with compressed air via the connection 9, the side of the actuating element 6 which faces the pressure chamber 8 is provided with a

Actuating force applied in the direction of actuation X. The actuating element 6 is thereby moved in the actuating direction X. The actuating element 6, which strikes the wedge element 3 in actuating direction X, transmits the actuating force to the wedge element in actuating direction X. As a result, wedge element 3 is acted upon by the actuating force in actuating direction X. The wedge element 3 is with the support surface 3a against the correspondence surface 11 a of the

Counter element 11 pressed. Due to the conical design of the support surface 3 a and the corresponding surface 11 a, the actuating force in the

Actuation direction X is transferred to the counter element 11 and, on the other hand, a pressing force is generated which is oriented perpendicular to the actuation direction X.

The contact force, which is supported on the transmission element 1 between the transmission surface 3b and the contact surface 1a, if the actuating force is sufficiently high, ensures that a frictional connection is formed between the transmission surface 3b and the contact surface 1a parallel to the actuation direction X.

This has the consequence that the actuating element 6, the wedge element 3, the

Transmission element 1 and the counter element 11 are interlocked so that they can then be moved as a unit in the actuation direction X. If the actuating force is removed again from the actuating element 6 by venting the pressure chamber 8, the actuating element 6 moves

Counter-element 11 and the wedge element 3 by the forces of the springs 5, 12 back into the position shown, while the transmission element 1 due to the now reduced contact force between the transmission surface 3b and the

Contact surface 1 a again relative to the actuating element 6 parallel to the

Operating direction X is displaceable, since the frictional engagement has been released again due to the lack of operating force.

However, the embodiments shown here do not limit the subject matter of the invention. Rather, further embodiments are conceivable which can be formed by combining or omitting individual features. Are special

The characteristics described below are conceivable.

In the embodiments shown, the actuating element 6 and the

Wedge element 3 formed separately. However, other embodiments are also conceivable in which the actuating element 6 and the wedge element 3 are formed in one piece. For example, the wedge element 3 can have a surface which is designed to be subjected to the actuating force. At

pneumatic or hydraulic application of the actuating force to the

Actuating element 6 can also be a part of wedge element 3 designed as a piston, the piston forming the actuating element. In particular, in the embodiment from FIG. 2, a one-piece design of the actuating element 6 and the wedge element 3 can be conceivable. Here the actuating element 6 is designed as an annular piston, with the side facing away from the pressure chamber 8

Actuating element 6, the wedge element 3 is formed, which is in

Operating direction X extends. In the same way, further wedge elements 3 can be arranged around the actuation direction X, which are also formed in one piece with the actuation element 6 and which also extend from the

Actuating element 6 extend in actuating direction X.

In Fig. 1, the actuating element 6 and the counter element 11 are formed in one piece. Alternatively, an actuating mechanism can also be formed at which the actuating element 6 and the counter element 11 are formed in the actuating direction X in front of the wedge element 3, the actuating element 6 and the

Counter element 11 are formed separately.

The illustrated and further embodiments can also have a stop which is designed to limit a movement of the actuating element 6 counter to the actuating direction X. It can thereby be achieved that the actuating element 6, in particular by the springs 4, 5 and 12, can be moved back into a defined position along the actuating direction X when no actuating force is acting on the actuating element 6.

If at least two wedge elements 3 are provided, these are around the

Arranged actuation direction X around, for example, they are arranged regularly spaced around the actuation direction X around. Are the

Wedge elements 3, as described above, are designed in one piece with the actuating element 6, so the regular spacing can be achieved by the construction of the actuating element 6 and the wedge elements 3. However, if the wedge elements 3 are designed separately from the other elements of the actuation mechanism, another solution must be found if regular spacing is desired. Here, it is conceivable, for example, to space the wedge elements 3 apart from one another by guides which are formed parallel to the actuation direction X. These guides can be formed on the transmission element 1, for example. For example, it is conceivable that the contact surfaces 1 a in grooves on the

Form transmission element 1, which is parallel to the actuation direction X

are trained. The wedge elements 3 are then provided in these grooves so that a relative movement between wedge element 3 and transmission element 1 is enabled when no actuating force acts on actuating element 6, i.e. when there is no frictional connection between transmission surface 3b of wedge element 3 and contact surface 1a des Transmission element 1 a consists. Alternatively or additionally, guides can also be provided which are formed on the actuating element 6 and / or the counter element 11. Another possibility of spacing the wedge elements 3 apart around the actuation direction X is to provide a cage which is designed to bring all of the wedge elements 3 together apart, the cage, for example, otherwise not in contact with the other elements of the actuating mechanism.

In Fig. 2, a spring 12 is provided which is designed to apply a force between the wedge element 3 and the counter element 11, which relieves the contact between the support surface 3a and the corresponding surface 11a. In a further embodiment, however, a spring can also be provided here instead, which increases a force on this contact in order to eliminate possible play in this contact. The spring or generally an elastic biasing force must be designed in such a way that no contact pressure between the

Contact surface 1 a and the transmission surface 3 b result, which prevents a relative movement of the transmission element 1 with respect to the actuating element 6 when no actuating force acts on the actuating element 6. In other words: no frictional connection between the contact surface 1 a and the transmission surface 3 b may be formed by this spring.

In FIGS. 1 and 2, certain elements, such as the actuating element 6, the pressure chamber 8 or the counter element 11, are designed to be rotationally symmetrical about the axis 1b. However, other forms of training are also possible. For example, the pressure chamber 8 can only partially extend around the axis 1 b, a corresponding actuating element 6 being formed which closes the pressure chamber 8.

The actuating mechanisms shown in Figures 1 and 2 and the embodiments described further here but not shown can also be used in one

Clutch actuator can be provided, which is designed to disengage a clutch by moving the transmission element 1 in the actuation direction X. REFERENCE LIST

1 transmission element

1 a contact area

1 b axis

2 stop

3 clamping element

3a support surface

3b transmission surface 4 spring

5 spring

6 actuator

7 housing

7a housing wall 7b housing wall

8 pressure room

9 connection

10 spring

1 1 counter element 11 a correspondence area

12 spring

X direction of actuation

Claims

PATENT CLAIMS

1. Actuating mechanism for a clutch actuator, comprising:

- A transmission element (1) which is designed to be displaceable parallel to an actuation direction (X),

- An actuating element (6) which is designed to be acted upon by an actuating force and which is designed to be displaceable parallel to the actuating direction (X), and

- A wedge element (3) between the transmission element (1) and the

Actuating element (6) is arranged and which is designed to with

Acting on the actuating element (6) with an actuating force

To increase contact pressure between the wedge element (3) and the transmission element (1) so that the actuating force can be transmitted to the transmission element (1), so that a displacement of the transmission element (1) in the

Operating direction (X) can take place, where

the actuation mechanism is designed to reduce the contact pressure between the transmission element (1) and the wedge element (3) in such a way that a relative movement of the transmission element (1) with respect to the actuation element (6) is parallel to the actuation element (6) when no actuation force acts on the actuation element (6) to the actuation direction (X) is enabled.

2. Actuating mechanism according to claim 1, wherein

the transmission element (1) is designed as a rod which has an axis (1b) which extends parallel to the actuation direction (X), the rod preferably having a circular cross section.

3. Actuating mechanism according to claim 1 or 2, wherein

the wedge element (3) has a support surface (3a) which is not oriented parallel and not perpendicular to the actuation direction (X) or the axis (1b) according to claim 2 of the transmission element (1), and the support surface is designed for this purpose Generate contact pressure when supporting the actuating force.

4. Actuating mechanism according to claim 3, wherein

the support surface (3a) is designed to act upon the

Actuating element (6) to come into contact with the actuating force with a corresponding surface (11 a) via which the actuating force can be transmitted, wherein

the correspondence surface (11 a) is formed on a counter element (11).

5. Actuating mechanism according to claim 4, wherein

the correspondence surface (11 a) as a rotationally symmetrical surface around the

Actuating direction (X) or about the axis (1 b) according to claim 2, the correspondence surface (11 a) and / or the support surface (3a) preferably

are formed at least as part of a conical surface.

6. Actuating mechanism according to claim 4 or 5, wherein

at least one further wedge element (3) is provided, and the wedge elements (3) are preferably arranged at a distance from one another around the actuating direction (X) and particularly preferably regularly spaced from one another around the

Operating direction (X) are arranged.

7. Actuating mechanism according to one of the preceding claims, wherein the actuating direction (X) is designed as a straight line.

8. Actuating mechanism according to one of claims 4 to 7, wherein

a stop (2) is provided which is designed to come into contact with the wedge element (3) or with the counter element (11) when the wedge element (3) or the counter element (11) is displaced counter to the actuation direction (X) , so that further displacement of the wedge element (3) or the counter element (11) against the actuation direction (X) is blocked.

9. Actuating mechanism according to one of claims 4 to 8, wherein

the actuating mechanism is designed to the actuating element (6), the wedge element (3) and / or the counter element (11) with an elastic

Apply a pretensioning force against the actuation direction (X), so that preferably a movement of at least one of these elements against the

Actuation direction (X) takes place, where

the elastic pretensioning force is preferably caused by a spring (5).

10. Actuating mechanism according to one of claims 4 to 9, wherein

an elastic biasing force between the wedge element (3) and the

Counter element (11) is provided, which is designed to increase a contact force between the wedge element (3) and the counter element (11), wherein

the elastic pretensioning force is preferably caused by a spring (4).

11. Actuating mechanism according to one of claims 4 to 10, wherein

an elastic biasing force between the wedge element (3) and the

Counter element (11) is provided, which is designed to reduce a contact force between the wedge element (3) and the counter element (11), wherein

the elastic pretensioning force is preferably caused by a spring (12).

12. Actuating mechanism according to one of the preceding claims, wherein the transmission element (1) with an elastic biasing force in

Actuation direction (X) is applied, which is preferably caused by a spring (10).

13. Actuating mechanism according to one of the preceding claims, wherein the actuating element (6) is designed to have a fluidic,

mechanical, electrical and / or electromechanical actuation force

to be charged.

14. Actuating mechanism according to one of the preceding claims, wherein the transmission element (1) is designed to with a displacement in

Actuation direction (X) to disengage a clutch.

15. Actuating mechanism according to one of claims 4 to 14, wherein the actuating element (6) and the counter element (11) or the

Actuating element (6) and the wedge element (3) are integrally formed.

16. A clutch actuator having an actuating mechanism according to one of the

Claims 1 to 15.