DE102018215076A1 - Release device for a friction clutch - Google Patents

Abstract

Disengaging device (10) for a friction clutch of a motor vehicle, comprising a guide tube (14), a sliding sleeve (12) which is designed to be axially movable relative to the guide tube (14), and at least one sliding element (20) which is arranged radially between the guide tube (14 ) and the sliding sleeve (12), wherein a sliding surface (16a) of the sliding sleeve (12) is in contact with the sliding element (20) and, in the event of an axial relative movement of the sliding sleeve (12) relative to the guide tube (14), the sliding sleeve (12 ) slides axially along the sliding element (20) via the sliding surface (16a). Furthermore, a sliding sleeve (12) and a guide tube (14) of such a disengaging device are described.

Description

The invention relates to a disengaging device for a friction clutch of a motor vehicle and an associated sliding sleeve and a guide tube.

The DE 10 2013 219 842 A1 discloses a disengaging device. This disengaging device comprises a sliding sleeve which is arranged around a guide tube. The sliding sleeve is designed to be movable in the axial direction in order to actuate a friction clutch. In particular, the sliding sleeve comprises a sliding sleeve, on which a release bearing for contacting the friction clutch is attached. The guide tube is formed by a steel tube which is fastened to a gear housing. To provide a smooth and low-wear axial movement of the sliding sleeve on the guide tube, grooves are formed on the sliding sleeve, in which corresponding guide bands are arranged. These guide bands provide low-friction contact between the sliding sleeve and the guide tube.

A cast steel guide tube is relatively heavy. In addition, most of the components of the gearbox housing to which the guide tube is attached are made of aluminum. It is therefore difficult to integrate additional functions on a guide tube.

It is therefore an object to provide a disengaging device which is lighter in weight and enables better functional integration.

This object is achieved by the disengaging device according to claim 1. Advantageous design variants of the disengaging device are described in the dependent claims.

The release device is suitable for a friction clutch of a motor vehicle. The basic functioning of the release device does not differ from the release devices of the prior art.

The disengaging device has a guide tube, a sliding sleeve and a sliding element. The sliding sleeve is axially movable relative to the guide tube. In particular, this sliding sleeve is controlled via an actuating lever, so that a friction clutch is actuated by the axial movement of the sliding sleeve or the disengagement process.

The sliding sleeve in particular comprises a sliding sleeve and a release bearing, the release bearing being fastened to the sliding sleeve.

The sliding element is arranged radially between the guide tube and the sliding sleeve, in particular the sliding sleeve.

The sliding sleeve, in particular the sliding sleeve, forms a sliding surface with which the sliding element is in contact. When the sliding sleeve moves axially relative to the guide tube, the sliding sleeve slides axially along the sliding element via the sliding surface.

The sliding element is accordingly fixed relative to the guide tube. In particular, the sliding element can perform essentially no free movement in relation to the guide tube in the axial direction, so that its degrees of freedom in the axial direction are restricted. The sliding surface of the sliding element and the sliding surface of the sliding sleeve form a pair of sliding surfaces. The sliding surfaces of the pair of sliding surfaces are in contact with the system and provide a low-friction relative movement between the sliding sleeve and the guide tube.

The material combination selected such that the sliding element and the sliding sleeve have a low coefficient of friction with respect to one another. In particular, the sliding sleeve is made of steel, whereas the sliding elements are made of a plastic. As a result, the guide tube can be made of aluminum.

As a result, an optimal pair of friction surfaces is further provided, which has low wear and a low coefficient of friction. If the aluminum guide tube is formed, weight can be saved on the one hand. On the other hand, further functional sections can be formed on the guide tube, which provide a particularly advantageous functional integration. For example, the cast aluminum part, which also provides the guide tube, can also provide a function on the gearbox side, such as, for example, attachment to the gearbox housing and / or a receptacle for a gearbox brake. These functions can be provided by a single aluminum component.

Advantageous design variants of the disengaging device are explained below.

The sliding element is particularly advantageously captively arranged on the guide tube or the sliding element is fastened to the guide tube.

The captive arrangement is provided, for example, by a sliding element, which is arranged in a groove of the guide tube. The groove provides a restriction on the axial freedom of movement of the sliding element in the axial direction. In addition, the sliding element in the radial direction is restricted in its freedom of movement by the sliding surface of the sliding sleeve of the sliding sleeve.

In addition, the sliding element can be attached to the guide tube. Such attachment can be carried out by gluing the sliding element onto the guide tube, for example. In particular, the sliding element is arranged within a groove of the guide tube and glued into this.

The sliding element is particularly advantageously arranged within a groove of the guide tube.

Only part of the sliding element is arranged within the groove, so that it provides a sliding surface for the sliding sleeve, thereby avoiding contact between the sliding sleeve and the guide tube. In particular, the sliding element protrudes beyond the groove in the radial direction. In particular, the groove is circularly circumferential, the sliding element preferably also being circularly circumferential. In particular, the sliding element is designed by a guide band which is inserted into the groove. For example, a plastic guide band is slotted at one point. By interrupting the band, the guide band can be radially expanded for assembly within the groove.

In a further embodiment variant, the sliding element is glued to the guide tube.

The sliding element is also designed, for example, as a guide band. This can then be glued directly onto the guide tube. In particular, the sliding element is arranged within a groove and is also glued to the guide tube.

It is further proposed that the sliding element is sprayed onto the guide tube.

With this type of attachment, a large sliding surface is provided on the guide tube. Such a large sliding surface enables a better absorption of tilting moments by the actuating lever on the sliding sleeve.

The sliding element can extend over the entire radially outer surface of the guide tube. Alternatively, the sliding element can also cover only a partial area of the guide tube. A plurality of such sliding elements, which cover a partial area, are advantageously formed. The sprayed-on sliding elements on the guide tube advantageously form a circular structure.

A sliding element, in particular a sprayed-on sliding element, can have corresponding depressions or grooves. These grooves run more favorably in the circumferential direction. Corresponding dirt particles, which are arranged between the sliding surfaces, are stripped off at the edges of these grooves or depressions. Wiping keeps the sliding surfaces clean and reduces wear.

The sliding element is particularly advantageously formed by a guide band.

Such a guide band can be inserted into a groove. Alternatively, the guide band is glued to the guide tube.

The guide tube is made of aluminum with particular advantage.

In particular, weight is saved by providing the guide tube from an aluminum part. A design made of aluminum is possible due to the inverted structure of the release device in relation to the prior art, since this means that there is no direct sliding contact or contact between the guide tube and the sliding surface of the sliding sleeve.

The sliding sleeve and in particular the sliding sleeve is advantageously made of steel. In particular, this is designed as a cast steel part. The sliding element is particularly advantageously made of a plastic. The material pairing of steel and plastic provides a particularly advantageous coefficient of friction and low wear.

It is further proposed that the guide tube provide a further functional component.

Such a functional component can, for example, be a receptacle for a transmission brake or also a receptacle for a bearing of a transmission shaft. However, other configurations for the most diverse components of such a transmission are also conceivable. As an aluminum part, the provision of the guide tube, which also provides other functional components, is possible without any problems.

It is particularly advantageous for the disengaging device to have two or three sliding elements which are arranged on the guide sleeve.

The sliding elements are at least captive, but can also be attached to the guide sleeve. In particular, each of the sliding elements according to at least one of the previous statements. The sliding elements are advantageously designed as guide bands.

The sliding elements together provide a sliding plane that covers the entire travel of the sliding sleeve in new condition and also in worn condition, so that the sliding surface of the sliding sleeve is in contact with the sliding surface of the sliding elements at all times.

In the case of two sliding elements, these are in particular arranged directly adjacent to one another with a small distance. In addition, the two sliding elements are formed approximately centrally on the guide tube in the axial direction. Likewise, a distance from the axial ends of the respective sliding element or guide band is relatively large compared to the distance between the two guide bands or sliding elements. This arrangement of the two sliding elements means that a minimum number of guide belts is necessary in order to provide a sufficient sliding surface. However, since the two guide bands are arranged close to one another, the sliding sleeve can tilt relatively far.

This tilting is prevented in particular by the formation of three sliding elements, in particular guide bands. The axial guide bands are essentially axially distributed over the guide tube. This provides a larger sliding surface, so that an acting force can be better absorbed by the actuating lever and tilting is reduced.

The object is also achieved via a sliding sleeve according to claim 9. The sliding sleeve is designed according to at least one of the explanations explained above or below

The sliding sleeve is particularly suitable for a disengaging device according to claims 1 to 8. The sliding sleeve comprises at least one sliding sleeve and a release bearing, which are firmly connected to one another. In addition, the sliding sleeve provides a sliding surface for corresponding sliding elements of a guide tube. In particular, the sliding sleeve of the sliding sleeve is designed for direct contact with a sliding surface with a sliding surface of at least one sliding element.

The object is also achieved by a guide tube according to claim 10. The guide tube is designed according to at least one of the preceding or following explanations.

Such a guide tube is particularly suitable for a release device according to one of claims 1 to 8.

The guide sleeve has sliding elements which are arranged at least captively on the guide tube. In particular, the sliding elements are fixed axially with respect to the guide sleeve. This axial fixing can take place in particular by restricting the axial freedom of movement or also by fastening to the guide tube. In particular, the combination with the sliding sleeve also restricts the radial freedom of movement of the sliding element. The guide tube is advantageously made of aluminum.

• 1 a-c eine erste Ausführungsvariante einer Ausrückvorrichtung;
• 2 a- c eine weitere Ausführungsvariante für eine Ausrückvorrichtung;
• 3 eine weitere Ausrückvorrichtung;
• 4 eine weitere Ausrückvorrichtung.

The disengaging device, the sliding sleeve and the guide tube are described in detail and by way of example with reference to several figures. Show it:

• 1 ac a first embodiment of a release device;
• 2 a - c a further embodiment variant for a disengaging device;
• 3 another release device;
• 4 another release device.

In the 1 a to 1c is a release device 10 shown. The 1a shows the release device in the engaged position in the new state of a clutch disc. The 1b shows the release device 10 in disengaged position when new, a clutch disc and the 1c shows the release device 10 in engaged position with worn friction clutch.

The release device 10 includes a sliding sleeve 12 as well as a guide tube 14 , The sliding sleeve 12 is still through a sliding sleeve 16 and a release bearing 18th trained, which are firmly connected. The release bearing 18th serves the system contact with a diaphragm spring of a friction clutch and provides a rotational decoupling between the release device and the friction clutch. The sliding sleeve 16 is designed to interact with an operating lever, which is not shown here. An axial relative movement of the sliding sleeve is under the action of a force by the actuating lever 16 opposite the guide tube 14 provided.

The guide tube 14 also includes two sliding elements 20th that are within circular circumferential grooves 22 of the guide tube 14 are arranged. The sliding elements 20th are here as guide bands 20th educated. The guide bands 20th are circular and made in one piece, these are slotted at one point, so that radial expansion can be provided. This radial expansion enables assembly within the grooves 22 of the guide tube.

After installing or sliding on the sliding sleeve 12 are the sliding elements 20th or the guide bands 20th secured in the radial direction. The arrangement of the sliding elements within the respective groove 22 on the other hand provides a restriction of the axial freedom of movement. The position of each slide 20th is thereby axially fixed with respect to the guide tube, so that no or only a slight axial relative movement between the sliding element 20th and the guide tube 14 can be done. In particular, the grooves 22 formed in the radial depth such that an inserted sliding element 20th or guide band 20th in the radial direction over the radial extension of the guide tube 14 survives.

The two sliding elements 20th are seen in the axial direction in the middle of the guide tube 14 arranged. In particular, each of the sliding elements 20th a relatively large distance from the axial ends of the guide tube, the distance between the two sliding elements 20th itself is relatively small. The two sliding elements 20th together form a sliding surface 20a ready with a sliding surface 16a the sliding sleeve interact.

The sliding sleeve 16 is advantageously designed as steel, in particular manufactured as a cast steel part. The sliding elements 20th are advantageously made of plastic, so that a low wear and a low coefficient of friction is provided. The two sliding elements 20th are due to their axially central arrangement over the axial length of the guide tube 14 optimally designed to overlap the sliding surfaces over all possible positions of the sliding sleeve when new and when the friction clutch is worn 16a and 20a to provide. The guide tube 14 is preferably made of aluminum to enable easy and inexpensive production.

Furthermore, guide tube 14 a flange at one axial end 14a on, which is formed on the transmission side. This flange on the gearbox side 14a is used for mounting or fastening to the gear housing. In particular, this flange 14a be designed as a functional component. In one example, the flange is 14a executed such that it also represents a component of a transmission brake. In this case, the item represents 14 on the one hand the guide tube is ready, an attachment to a transmission housing and also a component of a transmission brake. Alternatively, the flange can also accommodate a bearing for a gearbox.

In the 2a to 2c a further release device is shown. This disengaging device corresponds essentially to the functioning and structure of the disengaging device according to the 1a to 1c , For this reason, reference numerals from the 1a to 1c adopted identically. The disengagement device differs 2 by the number and arrangement of the sliding elements 20th ,

Here are three sliding elements 20th formed on the guide tube, which are also formed in circulating circumferential grooves. For example, the sliding elements 20th through an adhesive connection on the guide tube 14 be attached.

By forming an additional sliding element 20th becomes a larger sliding surface 20a provided and due to the large-area distribution in the axial better support of transverse forces, which by the actuating lever in the sliding sleeve 12 is introduced, provided.

In the 3 Another embodiment variant of such a disengaging device is shown. The corresponding reference symbols are also adopted here.

The difference is that the sliding element 20th on the guide tube 14 is sprayed on and is thus firmly connected to it. in particular, the sliding element essentially covers the entire radially outer surface of the guide tube. The flange is essentially not covered. This creates a correspondingly large sliding surface 22a provided.

In the 4 a further disengagement device is provided, which follows the disengagement device 3 resembles. In particular, the reference symbols are also adopted identically here.

The sliding element 20th is on the guide tube 14 sprayed on. In addition, are on the sliding element 20th corresponding grooves 20b executed. These grooves 20b are advantageously circular in design. As a result, the sliding surface is interrupted in places in the axial direction by radially inward depressions. In particular, dirt particles that are between the sliding surface 16a the sliding sleeve 16 and the sliding surface 20a of the sliding element 20th penetrated through the grooves 20b be stripped. In particular, the dirt particles on an edge of a corresponding groove 20th be stripped. This reduces the wear on the sliding surfaces or the pair of sliding surfaces.

Reference list

10

Release device

12th

Sliding sleeve

14

Guide tube

14a

Flange / functional component

16

sliding sleeve

16a

Sliding surface

18th

Release bearing

20th

Sliding element / guide band

20a

Sliding surface

20b

groove

22

groove

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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.

Patent literature cited

• DE 102013219842 A1 [0002]

Claims (10)

Disengaging device (10) for a friction clutch of a motor vehicle, comprising - a guide tube (14), - a sliding sleeve (12) which is designed to be axially movable relative to the guide tube (14), and - at least one sliding element (20) which is located radially between the Guide tube (14) and the sliding sleeve (12) is arranged, characterized in that a sliding surface (16a) of the sliding sleeve (12) is in contact with the sliding element (20) and with an axial relative movement of the sliding sleeve (12) relative to the guide tube ( 14) the sliding sleeve (12) slides axially along the sliding element (20) via the sliding surface (16a). Release device (10) after Claim 1 , characterized in that the sliding element (20) is captively arranged on the guide tube (14) or the sliding element (20) is attached to the guide tube (14). Release device (10) after Claim 2 , characterized in that the sliding element (20) is arranged in a groove (22) of the guide tube (14). Release device (10) after Claim 2 , characterized in that the sliding element (20) is sprayed onto the guide tube (14). Release device (10) according to one of the Claims 1 to 4 , characterized in that the sliding element (20) is formed by a guide band (20). Release device (10) according to one of the Claims 1 to 5 , characterized in that the guide tube (14) is made of aluminum. Release device (10) according to one of the preceding claims, characterized in that the guide tube (14) provides a further functional component (14a). Release device (10) according to one of the preceding claims, characterized in that the release device (10) has 2, 3 or more sliding elements (20) which are arranged on the guide sleeve (14). Sliding sleeve (12) for a release device according to one of the preceding claims. Guide tube (14) for a disengaging device according to one of the preceding claims.

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