阅读说明：本技术 分离单元以及离合器装置 (Release unit and clutch device ) 是由 A·格列博夫 T·伯施 于 2020-03-11 设计创作，主要内容包括：本发明涉及一种分离单元以及一种用于打开和闭合转矩传递路径的离合器装置。分离单元(1)包括壳体(13)和与其至少轴向固定连接的或由壳体(13)构造的缸(10)、活塞(11)以及传感器装置(20),借助于传感器装置能够产生关于活塞(11)相对于壳体(13)的轴向位置的信号,传感器装置(20)具有待感测元件(21)以及探测装置(22),且待感测元件(21)和探测装置(22)中的一个至少在轴向方向上与活塞(11)机械固定连接,与活塞(11)在轴向方向上机械连接(15)的相应模块具有弹簧力引起的轴向方向上的预紧。利用根据本发明的分离单元以及配备有此的离合器装置能够以结构简单的实施方案实现长的使用寿命,同时具有高精度的活塞位置求取。(The invention relates to a decoupling unit and a clutch device for opening and closing a torque transmission path. The separating unit (1) comprises a housing (13) and a cylinder (10) which is at least fixedly connected axially to the housing or is formed by the housing (13), a piston (11) and a sensor device (20) by means of which a signal can be generated as to the axial position of the piston (11) relative to the housing (13), the sensor device (20) having an element (21) to be sensed and a detection device (22), and one of the element (21) to be sensed and the detection device (22) being mechanically fixedly connected to the piston (11) at least in the axial direction, the respective module which is mechanically connected (15) to the piston (11) in the axial direction having a spring-force-induced pretension in the axial direction. With the clutch device according to the invention and the clutch device equipped therewith, a long service life can be achieved with a structurally simple embodiment, while the piston position can be determined with high precision.)

1. A release unit (1), in particular a central release, for a hydraulic or pneumatic clutch actuation device, preferably of a motor vehicle, in an axial direction for actuating a clutch device, comprising: a housing (13); and a cylinder (10), in particular a cylinder (10) with an annular cross section, which is connected at least axially fixedly to the housing or is formed by the housing (13) and functions as a pressure chamber; and a piston (11), in particular an annular piston, which is movable in translation in the cylinder (10); and a sensor device (20) by means of which a signal can be generated as to the axial position of the piston (11) relative to the housing (13), wherein the sensor device (20) has an element (21) to be sensed and a detection device (22) for detecting the position of the element (21) to be sensed, and one of the two modules, the element (21) to be sensed and the detection device (22), is mechanically fixedly connected to the piston (11) at least in the axial direction, and the respective other module (21, 22) is fixedly connected to the housing (13) at least in the axial direction, wherein the mechanical connection (15) of the respective module to the piston (11) in the axial direction has a pretension in the axial direction caused by a spring force.

2. The separation unit (1) according to claim 1,

the piston (11) is configured with a retaining element (12) or a retaining element (12) is arranged on the piston (11), wherein the mechanical and pretensioned connection (15) of the respective module of the sensor device (20) to the piston (11) is achieved by spring-force-loaded contact of at least one contact element (33), which is fixedly connected to the respective module (21, 22) at least in the axial direction, on the retaining element (12).

3. The separation unit (1) according to claim 2,

the pretensioning is produced by means of a compression spring (31) supported on the housing (13) and acting with pressure on a pressure element (34) which is located in the axial direction between the holding element (12) and the housing (13) and is configured as an abutment element (33).

4. The separation unit (1) according to claim 3,

the pressure element (34) is mechanically fixedly connected to a driving element (36) which is axially spaced apart from the pressure element (34), wherein the retaining element (12) is axially located between the pressure element (34) and the driving element (36) and in this way enables a positively locking driving between the piston (11) and the contact element (33) in the axial direction.

5. The separation unit (1) according to claim 2,

the pretensioning is produced by means of a tension spring (32) supported on the housing (13), said tension spring acting with a tensile force on a tension element (35) configured as an abutment element (33) on the side of the holding element (12) facing away from the housing (13) in the axial direction.

6. The separation unit (1) according to claim 5,

the pull element (35) is mechanically connected to a driving element (36) which is spaced apart axially from the pull element (35), wherein the retaining element (12) is located axially between the pull element (35) and the driving element (36) and in this way enables a positively locking driving between the piston (11) and the contact element (33) in the axial direction.

7. The separation unit (1) according to claim 2,

characterized in that the pretensioning is generated by means of a tension spring (32) which acts with a tensile force on a first pressure element (37) which is designed as an abutment element (33) and which is located on the side of the holding element (12) facing away from the housing (13) in the axial direction and acts with a tensile force on a second pressure element (38) which is designed as an abutment element (33) and which is located on the side of the holding element (12) facing the housing (13), wherein the first pressure element (37) and the second pressure element (38) are arranged on both sides of the holding element (12) in the axial direction and thus clamp the holding element (12) in the axial direction.

8. The separation unit (1) according to any one of the preceding claims,

characterized in that the element to be sensed (21) is fixedly connected in the axial direction to the piston (11) and a detection device (22) for detecting the position of the element to be sensed (21) is fixedly connected in the axial direction to the housing (13).

9. The separation unit (1) according to claim 8,

characterized in that the housing (13) and the at least one abutment element (33) together form a translational guide for the axial translational movement of the abutment element (33) relative to the housing (13).

10. A clutch device for opening and closing a torque transmission path in a motor vehicle, comprising a separator unit (1) according to any one of claims 1 to 9 for operating the clutch device.

Technical Field

The invention relates to a release unit, in particular a central release, and to a clutch device for opening and closing a torque transmission path in a motor vehicle.

Background

Central decouplers are known from the prior art as decoupling units for actuating clutches for opening and closing the torque transmission paths of clutch devices in motor vehicles. Such a central decoupler, which here is usually part of a hydraulic or pneumatic clutch actuation device, comprises a housing with a cylinder (which acts as a pressure chamber) and a piston arranged in the cylinder. Here, the cylinder is movable in translation in the piston. Sensor means are optionally provided for generating a signal relating to the axial position of the piston relative to the housing.

For this purpose, the element to be sensed, the so-called target body, moves in the direction of movement of the piston and together with the piston relative to the fixed sensor. The target is in turn mechanically connected to the piston for determining the position of the piston, wherein this mechanical connection is usually achieved by a form-locking connection of a component which carries the target and is fixedly connected to the piston.

Thus, the movement of the piston causes an alternating load on the mechanical connection.

After a certain operating duration, wear occurs on the elements of the mechanical connection, which leads to play in the connection, whereby the position determination thus loses the required accuracy.

Disclosure of Invention

In view of this, the object of the present invention is to provide a release unit and a clutch device equipped with the release unit, which combine a long service life with a highly precise position determination in a structurally simple embodiment.

This object is achieved by a separation unit according to the invention according to claim 1. Advantageous configurations of the separation unit are given in the dependent claims 2 to 9. A clutch device having the disengagement unit is supplementarily provided according to claim 10.

The features of the claims can be combined in any technically meaningful manner, wherein for this purpose also the features from the following description and from the drawings, which comprise the complementary embodiments of the invention, can be considered.

Within the framework of the present invention, the terms "axial" and "radial" always relate to the central axis of the cylinder of the separation unit.

The invention relates to a release unit, in particular a central release device, for a hydraulic or pneumatic clutch actuation device in the axial direction, preferably for a motor vehicle, for actuating a clutch device. The separating unit comprises a housing and a cylinder (in particular a cylinder with an annular cross section) which is at least axially fixedly connected to the housing or is formed by the housing and acts as a pressure chamber, and a piston (in particular an annular piston) which can be moved in translation in the cylinder, and a sensor device by means of which a signal can be generated as to the axial position of the piston relative to the housing. The sensor device has an element to be sensed and a detection device for detecting the position of the element to be sensed. One of the two modules, the element to be sensed and the detection device, is mechanically fixedly connected to the piston at least in the axial direction, and the respective other module is fixedly connected to the housing at least in the axial direction. The mechanical connection of the respective module to the piston in the axial direction has a pretension in the axial direction caused by the spring force. The pretensioning caused by the spring force ensures a play-free configuration of the connection between the respective module (element to be sensed or detection device) and the piston, so that the position determination of the piston can be carried out with high accuracy.

The detection of the position can be on the one hand a determination of the distance between the detection device and the element to be sensed or can also be a determination of the presence of the element to be sensed only at a certain distance relative to the detection device.

The mechanical connection of one of the two modules to the piston at least in the axial direction serves here to transmit the movement of the piston to the respective module and thus to adjust the position of the respective module in accordance with the position of the piston cylinder.

The housing can also be referred to herein as a bracket.

According to one embodiment of the invention, the piston is formed with or arranged on a holding element, wherein the mechanical and pretensioned connection of the respective module of the sensor device to the piston is achieved by a spring-force-loaded contact of at least one contact element, which is fixedly connected to the respective module at least in the axial direction, on the holding element.

In particular, the retaining element is configured as a retaining ring.

This means that the mechanically fixed connection of one of the two modules to the piston is realized by means of a retaining ring.

The movement of the piston can also be transmitted to the respective module indirectly, for example via a release bearing of the clutch actuation device.

The retaining element can also fulfill multiple functions. In this case, the holding element, in addition to ensuring the mechanical and pretensioning connection, can also be used, for example, as an abutment for a pretensioning spring of the clutch actuating device, and/or a protective sheath radially surrounding the piston and the cylinder can be arranged fixedly at its axial ends on the holding element in order to protect the piston or the cylinder from dirt particles.

According to a further advantageous embodiment, the pretensioning is generated by means of a compression spring supported on the housing, which acts with pressure on a pressure element configured as an abutment element between the holding element and the housing in the axial direction.

As a result, the contact element or the pressure element is pressed permanently against the holding element and in this way a play between the contact element and the holding element and thus also between the piston and the respective module is suppressed.

The invention is not limited to the fact that the spring is fastened directly to the housing, but rather also enables the spring to be fastened to an element which is fixedly connected to the housing.

According to a supplementary aspect, the pressure element is mechanically fixedly connected to a driver element which is spaced apart from the pressure element in the axial direction, wherein the retaining element is located axially between the pressure element and the driver element and in this way enables a positively locking driving between the piston and the contact element in the axial direction.

In this case, the pressure element and the driver element can each be an edge of a substantially U-shaped element or an edge of a U-shaped projection of an element.

In an alternative advantageous embodiment, the pretensioning is generated by means of a tension spring supported on the housing, which acts with a tensile force on a tension element configured as an abutment element, which is located axially on the side of the holding element facing away from the housing.

As a result, the contact element or the tension element is permanently pulled onto the holding element and thus a play between the contact element and the holding element and thus also between the piston and the respective module is suppressed.

The invention is not limited to the fact that the spring is fastened directly to the housing, but rather also enables the spring to be fastened to an element which is fixedly connected to the housing.

According to a supplementary aspect, the tension element is mechanically connected to a driver element spaced apart from the tension element in the axial direction, wherein the retaining element is located axially between the tension element and the driver element and thus can perform a positively acting driver in the axial direction between the piston and the contact element.

The tensioning element and the driver element can each be an edge of a substantially U-shaped element or an edge of a U-shaped projection of an element.

According to a further alternative embodiment, the pretensioning is generated by means of a tension spring which acts with a tensile force on a first pressure element configured as an abutment element on the side of the holding element facing away from the housing in the axial direction and on a second pressure element configured as an abutment element on the side of the holding element facing the housing in the axial direction, wherein the first pressure element and the second pressure element are arranged on both sides of the holding element in the axial direction and thus clamp the holding element in the axial direction.

That is to say that the tension spring is provided for calibrating the position of the two pressure elements relative to one another or the axial spacing of the two pressure elements from one another.

The pressure elements permanently pulled toward one another by means of the tension spring can thus ensure a secure abutment of the two pressure elements on the retaining element, so that any wear can be compensated for by the automatic calibration of the pressure elements.

In a simple and stable embodiment, the element to be sensed is fixedly connected in the axial direction with the piston, and for detecting the position of the element to be sensed, the detection device is fixedly connected in the axial direction with the housing.

The connection in the axial direction between the element to be sensed and the piston is realized in particular indirectly by a guide element which carries or guides the element to be sensed and which forms either two contact elements or one contact element and one driver element. Instead of forming either two abutment elements or one abutment element and one driver element as an integrated component, the guide element can also be fixedly connected to a component forming either two abutment elements or one abutment element and one driver element.

According to another embodiment, the housing and the at least one abutment element together form a translational guide for the axial translational movement of the abutment element relative to the housing.

The separating unit according to the invention has the advantage that a constantly reliable position determination of the piston relative to the housing can be carried out over a long service life.

When wear-induced grinding occurs and therefore a displacement of the contact surface occurs on at least one of the components (which effect the mechanical connection between the piston and the element of the sensor device), the play occurring in the mechanical connection as a result of wear is permanently compensated for or eliminated by the force exerted by the tension or compression spring. Therefore, the wear present on the participating components has no effect on the accuracy of the position determination.

Furthermore, according to the invention, a clutch device for opening and closing a torque transmission path in a motor vehicle is provided, which has a release unit according to the invention for actuating the clutch device. The disengagement unit is provided for applying a force substantially in the axial direction to the torque-transmitting member for thereby opening or closing the clutch device.

Drawings

The above invention is explained in detail below in the related art background with reference to the accompanying drawings showing preferred configurations. The invention is not limited in any way by the figures, which are only schematic, wherein it should be noted that the embodiments shown in the figures are not limited to the dimensions shown. It shows that:

FIG. 1: a sectional view of a part of the separation unit according to the invention in a first embodiment,

FIG. 2: according to the separation unit according to the invention of the second embodiment,

FIG. 3: a separation unit according to the invention according to a third embodiment, and

FIG. 4: a separation unit according to the invention according to the fourth embodiment.

Detailed Description

Fig. 1 shows a detail of a separation unit 1 according to the invention of a first embodiment, shown in cross section.

The separation unit 1 includes: a housing 13; a main body 14 of the cylinder 10, which constitutes the cylinder 10 and is fixedly connected to the housing 13, said cylinder being supported on the housing 13; and a piston 11 longitudinally movably arranged in the cylinder 10; and a sensor device 20.

The cylinder 10 and the piston 11 are designed with an annular cross section, wherein the cylinder 10 acts as a pressure chamber in which the piston 11 can be moved in translation along the central axis 2 of the cylinder 10. The release unit 1 can thus be used as a central release for a hydraulic or pneumatic clutch actuation device (not shown). The axial movement of the piston 11 is transmitted here via a release bearing 40 to a clutch, not shown here, for closing or opening it. The release bearing 40 in this case effects a relative rotation between the stationary release unit 1 and the rotating element of the clutch. Furthermore, a substantially annular retaining element 12, which forms a stop 44 for the axial end of the preload spring 43 and on which one axial end of the protective sheath 42 is arranged, is fixedly connected in the axial direction to the inner ring of the release bearing 40. The other axial end of the protective sheath 42 is connected to the body 14 of the cylinder 10, so that the protective sheath 42 partially surrounds the cylinder 10 and the piston 11 arranged therein in the axial direction in order to protect it from dirt particles. The other axial end of the pretensioning spring 43 is supported on the body 14 of the cylinder 10 and serves to axially load the clutch actuating device with force in order to pretension the connection to the clutch.

Thus, the axial movement of the piston 11 also effects the axial movement of the holding element 12.

The sensor device 20 has an element to be sensed 21, which is coupled to the piston in the axial direction via the holding element 12, and a detection device 22. The detection device 22 is in this case fixedly connected to the housing 13, wherein the element to be sensed 21 is arranged on a carrier rail 24, so that a relative movement with an axial direction component between the element to be sensed 21, which is movable on the carrier rail 24, and the detection device 22 is possible. The detection means 22 are provided for detecting such relative movements and/or the position or presence of the element to be sensed 21 in a determined position. The element to be sensed 21 is connected for driving with the guide element 23. In order to compensate for the movement component of the element to be sensed 21 in the radial direction when the element to be sensed 21 moves along the carrier rail 24, the element to be sensed 21 is resiliently connected to the guide element 23.

The guide element 23 is in turn mechanically connected to the holding element 12 and is therefore mechanically coupled indirectly to the piston 11. Thus, the axial movement of the piston 11 effects an axial movement of the element to be sensed 21 on the movement track of the carrying rail 24.

The mechanical connection 15 between the guide element 23 and the holding element 12 is achieved by arranging the holding element 12 in the axial direction between the abutment element 33 of the guide element 23 and the driver element 36. The abutment element 33 arranged on the side of the holding element 12 facing the housing 13 and the driver element 36 arranged on the side of the holding element 12 facing away from the housing 13 are formed as an integral component of the guide element 23 on its end section 27 facing away from the housing 13. The abutment element 33 and the driver element 36 form a U-shaped receptacle which is open toward the center axis 2 of the cylinder 10 and in which the holding element 12 is arranged, as a result of which a form-locking driving of the guide element 23 is achieved when the holding element 12 is moved in the axial direction.

An axially acting compression spring 31 is arranged in the axial direction on the end section 26 of the guide element 24 facing the housing 13. The pressure spring 31 is supported with its first axial end 45 in the axial direction on the end section 26 of the guide element 24 facing the housing 13 and with its second axial end 46 in the axial direction on the housing 13.

The pressure of the pressure spring 31 extends in an action direction 30 which extends parallel to the direction of movement of the piston 11 and presses an abutment element 33, which acts here as a pressure element 34, in the axial direction against the holding element 12. Thereby, the pressure element 34 is permanently pressed onto the holding element 12, whereby a gap between the holding element 12 and the pressure element 34, i.e. thus also between the piston 11 and the element to be sensed 21, is suppressed.

Fig. 2 shows a second embodiment of the separation unit 1 according to the invention.

The separation unit 1 according to the second embodiment shown here largely corresponds to the separation unit 1 of the first embodiment in fig. 1. In this case, the only difference between the two embodiments is the arrangement of the spring acting in the axial direction on the guide element 23.

The spring in fig. 2 (as also in fig. 1) is an axially acting compression spring 31, wherein the compression spring 31 is arranged in fig. 2 not in the axial direction but in the radial direction next to the guide element 23. The pressure spring 31 is supported with its first axial end 45 in the axial direction on the side of the pressure element 34 facing the housing 13 and with its second axial end 46 in the axial direction on the housing 13. The direction of action 30 of the compression spring 31 extends parallel to the direction of movement of the piston (not visible here) as already explained with reference to the first embodiment of the separating unit 1. The pressure element 34 is accordingly, equivalently to the embodiment according to fig. 1, permanently pressed in the axial direction against the holding element 12.

Fig. 2 also shows an adapter device 41 for the purpose of making a screw connection in the axial direction with a further component of the motor vehicle when receiving a screw.

Fig. 3 shows a separation unit 1 according to the invention according to a third embodiment.

The third embodiment of the separating unit 1 shown here is embodied identically to the second embodiment of the separating unit 1, with the difference that the spring in the embodiment according to fig. 3 is a tension spring 32.

Accordingly, the abutment element 33, which acts as a tension element 35, is arranged on the side of the holding element 12 facing away from the housing 13, and the driver element 36 is arranged on the side of the holding element 12 facing the housing 13. The tension of the tension spring 35 extends in the direction of action 30 parallel to the direction of movement of the piston and permanently pulls the guide element 23 in the direction of the housing 13, so that the tension element 35 is pressed in the axial direction against the holding element 12 and accordingly eliminates any play that may occur.

Fig. 4 shows a separation unit 1 according to the invention according to a fourth embodiment.

The separating unit 1 of the fourth embodiment is identical to the separating unit 1 of the third embodiment, with the difference that the tension spring 32 is arranged in another position and the end section 27 of the guide element 23 facing away from the housing 13 is configured differently.

In fig. 4, the end section 27 of the guide element 23 facing away from the housing 13 comprises a first pressure element 37, which is located on the side of the holding element 12 facing away from the housing 13 in the axial direction and is configured as an abutment element 33, and a second pressure element 38, which is located on the side of the holding element 12 facing the housing 13 and is configured as an abutment element 33. A tension spring 32 connecting the two abutment elements 33 is arranged between the two abutment elements in the axial direction. The tension spring 32 is connected in the axial direction with its first axial end 45 to the first pressure element 37 and in the axial direction with its second axial end 46 to the second pressure element 38.

The tension of the tension spring 35 extends parallel to the direction of movement of the covered piston in the opposite direction of action 30 toward the holding element 12 and permanently pulls the first pressure element 37 and the second pressure element 38 toward one another. As a result, the holding element 12 is clamped in the axial direction between the first and second pressure elements 37, 38, so that any wear phenomena can also be compensated for.

The clutch device according to the invention and the clutch device equipped with the clutch device according to the invention make it possible to achieve a long service life with a simple embodiment and at the same time a highly precise determination of the piston position.

List of reference numerals

1 separation unit

2 central axis of cylinder

10 jar

11 piston

12 holding element

13 casing

14 cylinder body

15 mechanical connection

20 sensor device

21 element to be sensed

22 detection device

23 guide element

24 bearing rail

26 guiding the end section of the element facing the housing

27 end section of the guide element facing away from the housing

30 direction of action of the spring

31 pressure spring

32 tension spring

33 abutting element

34 pressure element

35 tensile element

36 driving element

37 first pressure element

38 second pressure element

40 Release bearing

41 engaging device

42 protective wrap

43 pre-tightening spring

44 stop

45 first axial end of spring

46 second axial end of the spring.