DE10244049A1 - Method for enhancing the performance of a friction clutch has magnetic inserts in both clutch sides having similar poles adjacent each other - Google Patents

Abstract

The driven clutch plate (22) has a spring (12) loaded contact with the drive plate (20) to provide a friction coupling. Extending flanges (28,30) carry magnetic pole pieces (32,34) arranged with the same poles (+) facing each other to provide additional power coupling.

Description

The present invention relates to an actuating bearing arrangement to initiate an actuating force into a friction clutch with rotational decoupling of an actuation system from the friction clutch comprising an operating force from an actuation system receiving entrance area and one with respect to the entrance area rotatable about an axis of rotation and for transmitting the actuating force to a friction clutch regarding of the entrance area supported in the direction of the axis of rotation exit area.

To initiate operating forces in Friction clutches, it is known to use rolling element bearings, which one with an actuation system coupled or from this a substantially axially directed operating force receiving input bearing ring and one on the friction clutch has acting output bearing ring, in which respective ball grooves are trained. The actual actuation force transmission can be carried out in these ball grooves providing and at the same time providing the rotational decoupling Bearing balls run. Because through these bearing arrangements for actuation force transmission rotation decoupling must also be provided; be subject to especially in the state in which it is rotationally decoupling are a heavy burden. While in systems in which the release force is the actuating force must be generated, i.e. briefly when engaging or disengaging worked against the force of a diaphragm spring or the like must be the wear problem not so apparent is the wear problem in systems at which is an engagement force is much more serious. With these systems essentially about most of it the operating time, namely whenever the clutch should be in the engaged state, both for axial power transmission for as well To ensure rotational decoupling.

It is the task of the present Invention, an actuating bearing assembly for one To provide a friction clutch, which are known in the prior art through actuation force loading reduces induced problems.

According to the present invention this task is solved through an actuating bearing arrangement to initiate an actuating force into a friction clutch with rotational decoupling of an actuation system from the friction clutch comprising an operating force from an actuation system receiving entrance area and one with respect to the entrance area rotatable about an axis of rotation and for transmitting the actuating force to a friction clutch with respect to the Entrance area supported in the direction of the axis of rotation, the output area and the input area for actuation force transmission are supported with respect to one another by magnetic force interaction.

Since in the actuating bearing assembly according to the invention the one to be transferred operating force not through direct mechanical interaction of two parts, but by magnetic force interaction, one can by actuation force transmission induced wear in Essentially complete be eliminated. The one another through magnetic force interaction supported Areas in this flow of force do not occur in direct physical Contact and enable thus a basically unlimited service life of such a bearing.

To generate the required magnetic forces to be able it is proposed that at the entrance area and / or at the exit area an interaction arrangement generating a magnetic field is provided is. With a particularly easy to implement embodiment can be provided that the interaction arrangement at least comprises a permanent magnet. To over the operating life of a bearing according to the invention to be able to provide essentially constant storage conditions alternatively or additionally to the permanent magnet solution it should be provided that the change (effect arrangement at least one Includes electromagnet assembly. By using an electromagnet arrangement it can be ensured that an operating life possibly away Demagnetization of permanent magnets due to vibrations is eliminated or at least compensated.

In the bearing arrangement according to the invention it can be provided that at the entrance area and at the exit area an interaction arrangement is provided and that the The entrance area and the exit area themselves with their interaction arrangements opposite are positioned. Alternatively, however, it is also possible that an interaction arrangement at the entrance area and at the exit area is provided and that the entrance area and the exit area with the magnetic field of the respective interaction arrangement conductive support areas facing each other are positioned.

A very high level of operational safety when using a magnetic support can be achieved in that the input area and the output area are supported with respect to one another by magnetic repulsion for the transmission of actuating force. The two regions to be supported against one another will then assume a defined position with respect to one another, following the influence of external forces. To especially under the influence of To be able to provide magnetic force interaction for stable positioning of the two areas to be supported with respect to one another, it is proposed that a radial bearing arrangement be provided for radially supporting the input area with respect to the output area.

Here can be a very easy to implement design provide that the radial bearing assembly is a slide bearing element includes.

To also in the area of this radial bearing Wear like that low as possible to keep, it is proposed that the radial bearing arrangement the Entrance area and the exit area by magnetic interaction in terms of supports each other in the radial direction. This can be done structurally very easy to implement and only requires a few components Provide variant that the radial bearing arrangement at least includes an interaction arrangement.

The present invention is described below Reference to the accompanying drawings based on preferred embodiments described in detail. It shows:

1 a longitudinal sectional view of a bearing assembly according to the invention;

2 a partial longitudinal sectional view of a modified embodiment of the bearing arrangement according to the invention;

3 another of the 2 corresponding representation of an alternative embodiment;

4 another of the 2 corresponding representation of an alternative embodiment;

5 another of the 2 corresponding representation of an alternative embodiment;

6 another of the 2 corresponding representation of an alternative embodiment;

7 a schematic view of a further alternative embodiment of a bearing arrangement according to the invention;

8th one of the 7 corresponding representation of a further alternative embodiment.

In 1 A bearing arrangement according to the invention is designated by 10. Through the bearing arrangement 10 an actuating force that is directed essentially in the direction of an axis of rotation A can be transmitted from an actuation system to a friction clutch, of which in 1 symbolically the radially inner area of a force application arrangement, for example a diaphragm spring 12 , is shown. Since the actuation system is generally fixed, for example on a gearbox 14 is attached, and by the camp 10 Area of the friction clutch to be acted on, for example the diaphragm spring 12 or any other power transmission lever assembly that will rotate about axis of rotation A must pass through the bearing 10 not only transmit the actuating force directed in the axial direction, but a rotational decoupling of the two system areas of actuating mechanism and friction clutch must be provided, especially in the force-transmitting state.

The warehouse 10 comprises an essentially ring-shaped entrance area 16 and a correspondingly ring-shaped exit area 18 , Both the entrance area 16 as well as the exit area 18 have a radially inner sleeve-like bearing section 20 or 22 on. With this storage section 20 . 22 are the entrance area 16 and the exit area 18 on a substantially cylindrical bearing protrusion 24 one for example on the transmission 14 fixed carrier arrangement 26 of the camp 10 rotatably carried. In order to keep the friction losses as low as possible here, the bearing section 20 or / and the storage section 22 on the bearing tab 24 with intermediate positioning of a slide bearing element, a rolling element bearing arrangement or the like, wherein here the axial mobility of the input area required for the transmission of actuating force 16 and the exit area 18 to watch out for.

On flange-like or arm-like support sections projecting radially outwards 28 or 30 of the entrance area 16 and the exit area 18 are in the example shown in the circumferential direction around the axis of rotation A successive permanent magnets 32 . 34 carried. These are positioned so that they face each other with areas of the same magnetic polarity. This is indicated by the plus sign symbolizing the magnetic south pole or the minus sign symbolizing the magnetic north pole, for example. It will thus be between the entrance area 16 and the exit area 18 generated a repulsion by magnetic interaction. With a suitable selection of the permanent magnets 32 . 34 generated repulsive force it becomes possible in the entrance area 16 initiated operating force on the exit area 18 by magnetic force interaction, without this the entrance area 16 and the exit area 18 rub against each other. Especially in the heavily loaded condition, the occurrence of wear is largely excluded, so that such a bearing 10 will have a significantly longer service life than conventional rolling element thrust bearings.

A modified embodiment of the bearing according to the invention 10 is in 2 shown. It can be seen there that the sleeve-like bearing section 22 of the exit area 18 no longer on the bearing projection positioned on the gearbox 24 is stored, but on an outer peripheral region of the carrier section 28 of the entrance area 16 , For this purpose, this can be in Axis extended support area 36 have to increase the storage area. Between the two areas 22 and 34 or 28 again a plain bearing arrangement or a rolling element bearing arrangement can be effective.

One recognizes in the embodiment according to 2 however, that the entrance area 16 and the exit area 18 face each other directly in the radial direction with respective body sections thereof. Now, for example, the carrier section 28 with the support area 36 and the beam section 30 made of magnetisable material or material that conducts the magnetic flux, surfaces in the boundary region G face each other with the same magnetic polarity. This also leads to magnetic repulsion there, so that in the radial direction, even with the absence of corresponding sliding or rolling element bearing arrangements, for stable support of the entrance area 16 regarding the exit area 18 is taken care of.

The same applies to those in the 3 illustrated embodiment. Here is the storage section again 22 of the exit area 18 positioned radially inward, but surrounds the axially elongated bearing portion of the entrance area 16 which in turn is on the storage ledge 24 is carried at least displaceably in the axial direction. Here too, in the border area G, with a suitable choice of material for the carrier sections 28 . 30 or the storage sections 20 . 22 ensure that the entrance area 16 and the exit area 18 solely by means of the permanent magnets 32 . 34 generated magnetic forces are supported with respect to each other in the radial direction and of course also in the axial direction. Of course, the design would be in accordance with 3 rolling element or sliding element bearings effective in the limit area G are also possible.

At the in 4 The embodiment shown is the entrance area 16 the positioning lead 24 arranged on its outside surrounding during the storage section 22 of the exit area 18 in the inner circumferential area of the bearing protrusion 24 is used. The permanent magnets also lie in this embodiment 32 . 34 directly opposite. The radial bearing can here with respect to the bearing projection 24 again using plain bearings or rolling element bearings.

In 5 An embodiment is shown in which the radial bearing as well as the axial force transmission takes place by magnetic interaction. It can be seen that the interaction arrangements or permanent magnets lying directly opposite one another 32 . 34 not only face each other with respective axially oriented surfaces, but that the permanent magnets 34 of the exit area 18 have an angled structure and the permanent magnets 32 of the entrance area 16 , which can have a correspondingly angled structure, overlap radially on the outside. Because also in this radially staggered area of the permanent magnets 32 or 34 surfaces of the same magnetic polarity face each other, the induced repulsion also ensures that the output area 18 and the entrance area 16 are centered with respect to each other in the radial direction without requiring any kind of frictional interaction. The entrance area 16 is in the area of its storage section 20 then on the storage ledge 24 worn movable at least in the axial direction.

Also in 6 An embodiment is shown in which the radial centering of the two areas 16 . 18 by magnetic force interaction. It can be seen that both the entrance area 16 as well as the exit area 18 Magnets staggered in the radial direction 32 or 34, which are each tapered at their axial free end regions, so that a tapering end region, for example of a permanent magnet, is staggered in the radial direction 32 between two corresponding tapered end areas of two permanent magnets 34 intervenes. Due to the resulting overlap, radial forces become effective again, due to the same polarity of the permanent magnets 32 and .34 provide centering in opposing surfaces.

With regard to this embodiment, it should be stated that the permanent magnets 32 and 34 can have a ring-like structure, so that in each case a plurality of magnet rings are arranged radially staggered. Of course, such axially intermeshing structures can also each have a single permanent magnet 32 and a single permanent magnet 34 are formed, which then have, for example, a corresponding groove structure or projection structure. It should also be pointed out that in 6 Design variant shown in the boundary region G between the carrier section 28 of the entrance area 16 and the now radially outer storage section 22 of the exit area 18 When these two regions positioned opposite one another are constructed of magnetically conductive or magnetizable material, magnetic radial centering is ensured.

In 7 is schematically indicated an embodiment in which the entrance area 16 and the exit area 18 are coupled in both axial directions for axial force transmission. This is achieved by using magnetic or magnetized areas 40 of the entrance area 16 which are axially polarized on one side and polarized on the other have, are arranged in a staggered manner with correspondingly magnetized regions 42 of the exit area 18 , By the number of areas arranged one after the other in this way in the axial direction 40 . 42 the strength of the coupling can be adjusted. The construction of such an embodiment can be realized, for example, in that the entrance area 16 is ring-shaped, during the exit area 18 has several segments, which then radially from the outside into the corresponding spaces of the entrance area 16 be inserted. A reverse arrangement is of course also possible.

In 8th is illustrated that in an embodiment as shown in 7 is shown, can also be provided for radial centering. This is done in that, for example, compared to that in 7 shown embodiment the respective areas 40 or 42 are extended in the radial direction and thus in border areas G very close to the respective other area 16 or 18 protrude. Here it is possible to provide radial support by means of rolling elements or sliding element bearings. Alternatively, support can also be provided here by magnetic interaction if, for example, magnetic or magnetized areas extend radially outward to a certain polarity to the extent that they interact magnetically with the magnetized areas of the other area with the required strength 18 or 16 can kick. Here, too, the magnetic alternation can be carried out by permanent magnets that generate magnetic forces directly or by carrier sections that essentially form a yoke or magnetic conductor.

In all of the embodiments described above, permanent magnets are both at the entrance area to generate the magnetic alternating device 16 as well as at the exit area 18 used. It should be noted that, of course, electromagnets can also be used in at least one of these areas. The entrance area is suitable for this, since it does not necessarily have to be arranged in a rotating manner and thus enables an easier power supply. The use of electromagnets avoids the problem that the coupling strength between the input area and the output area decreases over the service life due to a decreasing magnetization. It can also be considered here to combine electromagnets and permanent magnets in at least one of the areas. Furthermore, it should be pointed out that, although the magnetic interaction which is repulsive to obtain the supporting forces has been described above, an attractive magnetic interaction can also be provided between the input area and the output area, in which case, for example, spacing elements must then be used to ensure that the two mutually attracting magnetic or magnetized areas cannot come into direct contact, or, for example, by means of corresponding tracking, it is ensured that the two areas are always at a predetermined minimum distance from one another. Especially in the 7 and 8th The embodiment variant shown can have the same centering effect if the polarities are opposite each other in the entrance area and in the exit area.

Claims (11)

Actuating bearing arrangement for introducing an actuating force into a friction clutch with rotational decoupling of an actuating system from the friction clutch, comprising an input area receiving an actuating force from an actuating system ( 16 ) and one regarding the entrance area ( 16 ) rotatable about an axis of rotation (A) and for transmitting the actuating force to a friction clutch with respect to the input area ( 16 ) supported in the direction of the axis of rotation (A) 18 ), where the output area ( 18 ) and the entrance area ( 16 ) are supported for actuation force transmission by magnetic force interaction with respect to one another. Actuating bearing arrangement according to claim 1, characterized in that at the entrance area ( 16 ) or / and at the exit area ( 18 ) an interaction arrangement generating a magnetic field ( 32 . 34 ; 40 . 42 ) is provided. Actuating bearing arrangement according to claim 2, characterized in that the interaction arrangement at least one permanent magnet ( 32 . 34 ; 40 . 42 ) includes. Actuating bearing arrangement according to claim 2 or 3, characterized in that the interaction arrangement comprises at least one electromagnet arrangement. Actuator bearing arrangement according to one of claims 2 to 4, characterized in that at the entrance area ( 16 ) and at the exit area ( 18 ) one interaction arrangement each ( 32 . 34 ; 40 . 42 ) is provided and that the entrance area ( 16 ) and the exit area ( 18 ) with their interaction arrangements ( 32 . 34 ; 40 . 42 ) are positioned opposite each other. Actuator bearing arrangement according to one of claims 2 to 4, characterized in that at the entrance area ( 16 ) and at the exit area ( 18 ) one interaction arrangement each ( 32 . 34 ; 40 . 42 ) is provided and that the entrance area ( 16 ) and the exit area ( 18 ) with the magnetic field of the respective interaction arrangement ( 32 . 34 ; 40 . 42 ) conductive support areas are positioned opposite each other. Actuator bearing arrangement according to one of claims 1 to 6, characterized in that the input area ( 16 } and the exit area ( 16 ) are supported with respect to one another by magnetic repulsion for actuation force transmission. Operating bearing arrangement according to one of claims 1 to 7, characterized in that a radial bearing arrangement for radial support of the input area ( 16 ) regarding the exit area ( 18 ) is provided. Actuating bearing arrangement according to claim 8, characterized in that the radial bearing arrangement comprises a plain bearing element. Actuating bearing arrangement according to claim 8, characterized in that the radial bearing arrangement forms the entrance area ( 16 ) and the exit area ( 18 ) supported by magnetic interaction with respect to each other in the radial direction. Actuating bearing arrangement according to claim 2 and claim 10, characterized in that the radial bearing arrangement comprises the at least one interaction arrangement ( 32 . 34 ; 40 . 42 ) includes.