DE2749271C2 - Clamping one-way clutch - Google Patents

Description

The invention relates to a clamping jaw

Overrunning clutch with an outer ring with a cylindrical bore and a rotating body rotatably mounted coaxially with it, as well as at least one tangential shaped wedge held with spring pressure in a wedge gap between the outer ring and the rotating body and connected to the latter with play, which is pulled in the clamping direction into the wedge gap and out of it in the freewheeling direction runs out
In conventional clamping jaw overrunning clutches of this type (compare, for example, US Pat compared to the fixed outer ring in the direction opposite to the wedge tip, the wedge is carried along by the frictional force, this effect being increased by the increase in transverse force resulting from the deformation, so that the outer ring and the rotating body couple in this direction. In the opposite direction, apart from the slight friction on the outer ring as a result of the pressure exerted by the pretensioning spring, the tangential wedge rotates freely supported in the outer ring with the rotating body.

This known training of clamping jaw overrunning clutches required inevitably - due to the mode of action via the deformation of the wedge and the increase in lateral force to respond to the clutch

so both at the transition from the freewheeling direction to the Clamping direction as well as vice versa - a certain amount of play, so that the clamping and also the releasing for many use cases does not take place quickly and precisely enough

The invention is therefore based on the object of creating a jaw overrunning clutch which works free of play when starting up and does not only engage or disengage after a certain delay. releases. To solve this problem, the one mentioned at the beginning is used in the case of a clamping jaw overrunning clutch Kind provided that a braking device acting on the tangential wedge is provided this when it is entrained by the rotary body with a direction opposite to the direction of rotation of the rotary body directed force component applied

In the case of a clamping jaw overrunning clutch according to the invention the rotation of the body of revolution that forms the free-running direction

ring in the direction of the wedge tip of the Tangentiaiformkörper - For the sake of simplicity, this mode of operation should always be addressed in the following, although it is Of course, for the functioning of such a clamping jaw overrunning clutch only on the relative rotation from the outer ring and the rotating body arrives - this braking force component pulls the tangential shaped wedge back out of the wedge gap. The force component must of course be greater than that Spring force of any pre-tensioning spring provided for the tangential shaped wedge, so that in The free direction also overcomes this spring force can be.

When the rotating body is rotated in the clamping direction, the braking member ensures that the tangential shaped wedge is drawn into the wedge gap between the outer ring and the rotating body, so that a rapid safe clamping coupling takes place

The braking element, which is a simple friction element could be that acts, for example, on a side surface of the tangential wedge, should in a further development of Invention as a radially deformable one mounted between the rotating body and the tangential shaped wedge Be formed slip ring with a lower Angular velocity in the freewheeling direction revolves as the body of revolution.

It can be further provided in an embodiment of the invention that the centrally symmetrical, z. B. oval or rounded polygonal bodies of revolution extend over at least two places on its circumference the sliding ring surrounding it is supported on the inner wall of the outer ring while braking the sliding ring The braking can take place through the mere friction of the sliding ring on the inner wall of the outer ring. Instead, it can also be provided that the sliding ring and the outer ring by a toothing in Are engaged with each other, so that when the rotation body in the fixed outer ring of Although the sliding ring is deformed in accordance with the shape of the rotating body in the outer ring but shifts essentially in the same way as this is held.

A very separate, advantageous, ball-bearing embodiment of a clamping jaw overrunning clutch according to the invention results according to the invention Ί5 in that the rotational body, preferably in one piece, is connected to a circular ring mounted as an inner ring of a ball bearing in the outer ring and that df sliding ring is coupled to the ball cage. After the ball cage is essentially at half the speed of rotation of the inner ring of a ball bearing rotates in the outer ring, this also applies to the sliding ring connected to the ball cage, so that there is a very considerable difference in angular speed between the rotating body and the sliding ring and consequently a relatively large one that moves the tangential wedge into and out of the wedge gap Braking force.

The sliding ring, which is made by an elastically bendable Metal ring can be formed, should be preferred, in particular in the case of the ball-bearing-mounted ones described above Embodiment as an elastic band made of individual lamellae connected by worm springs, preferably made of steel.

The lamellae can have a central eyelet bend that engages in a circumferential groove of the rotating body have to accommodate a worm spring, or be designed so that they are on both, over the End faces of the rotating body protruding ends for receiving one worm spring each eyelet-shaped are bent back.

To connect the ball cage to the elastic band forming the sliding ring can be provided be that at least one radial pin attached to the ball cage has a recess of a transverse lobe Slat with loosely sliding penetration Through this type of radially adjustable connection, the elastic Band under radial deformation adapt to the outer shape of the rotational body without thereby the rotary connection with the ball cage is impaired.

Instead of the connection described above between the ball cage and the elastic band can For example, it can also be provided that a transverse tab of a lamella is inserted into a radial groove of the ball cage engages since the rotary coupling can be seen to move and bend the freely even with this connection elastic band

The inventive design of the sliding ring as an elastic band connected by worm springs single lamellae has the additional advantage that by choosing the spring force of the worm spring such that at the nominal speed, the elastic band is essentially attached to the tangential shaped body by centrifugal force supports a significant frictional effect between the elastic band and the rotational body, the inner ring of the ball bearing does not speak at all

Finally, it is also within the scope of the invention that the tangential wedge with a, in a circular arc-shaped hanging groove in the end face of the rotating body with play in the circumferential direction engaging, preferably integrally formed, hook attachment is provided by this suspension of the Tangential wedges on the body of revolution, d. H. the inner ring of the ball bearing are the tangential shaped wedges not pressed against the outer ring by the centrifugal force so that a disruptive friction on this Position is excluded even at high speeds.

The invention is explained with reference to the drawings. It shows

F i g. 1 is an end view of a first embodiment of a clamping jaw overrunning clutch according to the invention,

F i g. 2 shows a section through the arrangement according to FIG. 1,

F i g. 3 shows an end view of a second embodiment of a clamping jaw overrunning clutch according to the invention, in which the sliding band and the outer ring mesh with one another via gear rings,

F i g. 4 shows a side view of the arrangement according to FIG. 3 with the outer ring cut open,

F i g. 5 shows a modified embodiment of the embodiment shown in FIG. 3 Clamping overrunning clutch with three clamping wedges,

F i g. 5a shows a section along line V, -V _a in FIG. 5,

F i g. 6 is a partially sectioned end view of a jaw overrunning clutch according to the invention with ball bearing of the inner ring in the outer ring, corresponding to section VI-VI in F i g. 7,

F i g. 7 shows a section along the line VII-VII in FIG. 6,

F i ζ. 8 is a partial perspective view of the im Embodiment according to FIGS. 6 and 7 used sliding ring designed as an elastic link belt,

F i g. 9 shows a partial section through a modified one

Embodiment of the arrangement according to FIGS. 6 to 8 and

10 is a perspective partial view of the rotary body with the sliding ring according to FIG. 9, where the For the sake of clarity, only half of the slats are shown.

In the case of the FIG. 1 and 2, 1 denotes the outer ring of a Klemmbakken-FreilaufkuppIung, 2 a rotating body rotatably mounted coaxially in the outer ring 1, and 3 a tangential shaped wedge which is connected to the rotating body 2 with play via a connecting member 4. The tangential form! 3 opposite, a second such Tangentiaifortnkeii is indicated, which can be provided in the second wedge gap 5 formed between the outer ring 1 and the rotating body 2. Between the rotating body 2 and the tangential shaped wedge 3, a radially deformable sliding ring 6, which rests against the surface of the rotating body 2 and is, for example, designed as a spring metal ring, is arranged over which two points A and B are located opposite one another at one point, which during the rotation of the rotating body 2 migrate accordingly, the rotating body 2 is supported on the inner surface 7 of the outer ring 1. This causes friction braking of the sliding ring 6, so that when it rolls on the inner surface 7 of the outer ring 1 it revolves considerably more slowly than the rotating body 2 when rotating in the freewheeling direction F. Due to this different rotational speed of the rotating body 2 and the sliding ring 6, the one that is in contact with the sliding ring 6 Tangential wedge 3 is withdrawn from the wedge gap 5 against the direction of rotation of the rotating body 2, ie it is essentially freely supported in the wedge gapL The restoring force given to the tangential wedge 3 by means of the braked sliding ring against its wedge direction and thus against the clutch clamping direction is greater than the resilient preload force caused by the Torsion spring 8 built into the connecting member 4. When the rotating body 2 is rotated in the direction of arrow K, ie the clamping direction, the rotating body 2 and the outer ring 1 are momentarily coupled via the sliding ring and the tangential shaped wedge 3. Conversely, the clamping jaw overrunning clutch according to the invention also acts immediately and quickly responsive when transitioning in the freewheeling direction of rotation. It is of particular importance in this context that, in the construction according to the invention, the wedge angle can be selected so that it is greater than the self-locking angle. This makes the loosening quicker and more direct.

The jaw overrunning clutch according to FIGS. 3 and 4 differs from that according to FIGS. 1 and 2 essentially in that the sliding ring 6 does not just slide against the inner surface 7 of the outer ring 1, gpndem that the outer ring 1 as well as the sliding ring 6 are provided over part of their width with a toothing 9 and 10, respectively Comb with each other in the area of landing stages A and B. Essentially U-shaped driver brackets 12, which are provided with a driver pin 13 for the tangential shaped wedge 3, are inserted into diametrically opposite slots 11 of the rotating body. At 14, the usual helical spring for prestressing the tangential standard wedge 3 is shown

The embodiment of a jaw overrunning clutch according to the invention according to FIGS. 5 and 5a corresponds in its functional structure to that according to FIGS that a total of three tangential shaped wedges can be arranged in as many wedge gaps 5 between the rotating body 2 'and the outer ring 1. In addition, the rotary body 2 'is designed as a ring for wedging onto a shaft.
In the arrangement according to FIGS. 6 to 9, the rotating body 2 "is part of a ball bearing inner ring 17 supported in the outer ring 1 via balls 16. so that, like the latter, it only revolves at half the speed of the inner ring 17 of the ball bearing in order to act as a braking member for the tangential wedge 3 ″ Rolled up eyelet-shaped to receive worm springs 20. At least one of the lamellae is provided with a transverse tab 21 with a hole for receiving a wheel valley pin 22, which is attached to the ball cage 19 which, however, is the radial deformation of the sliding ring as it revolves around the rotating body ers 2 The tangential shaped wedges 3 "are provided with integrally molded hook sections 23, which are hooked in the circumferential direction with a certain amount of play in annular groove sections 24 of the end face 25 of the rotating body 2" which are coaxial with the outer ring, so that the centrifugal force of the tangential shaped bodies is intercepted even at high rotational speeds and these do not rest against the inner surface 7 of the outer ring in a frictional manner with correspondingly high forces. In a corresponding manner, the spring forces of the worm springs 20 are set so that at the nominal speed the centrifugal force due to its own mass and the mass of the lamellas 18 are essentially supported on the tangential shaped wedges and there is practically no friction between the sliding ring 6 "and the rotating body 2"

In the arrangement according to FIGS. 9 and 10, the

Lamellas 18 'are not rolled up on the outside but with a central eyelet bend 26 for receiving a Worm spring 20 'provided. A circumferential groove 27 is used in the to accommodate the eyelet bends 26 Rotation body 2 "forming section of the inner ring

so 17 of the ball bearing. The slats 18 are just like in the embodiment according to FIG. 8 is actually arranged close to each other, with a corresponding pressing process during production also providing a curvature in the circumferential direction corresponding to the curvature of the rotating body 2 ″ in the most strongly curved contact area on the inner ring 1. One of the lamellae 18 is designed as a one-piece extension with the Cross tab 21 with the recess for receiving the radial pin 22 of the

Ball cage 19 provided.

The invention is not limited to the exemplary embodiments shown. This is how it is in practice It is cheaper to use a plurality of spaced apart radial pins instead of one radial pin 22. In addition, it is it is not necessary that the sliding ring 6 rests on the entire circumference of the rotary body 2 since it is sufficient if he is in the area of the Tangentialformkefls 3 am Rotary body rests This can therefore with

Recesses, for example in the form of segment sections or the like. Be provided. After all, he can Sliding ring can also be designed as a one-piece elastic metal or plastic ring, in the case of which If necessary, reinforcement rings can be embedded using plastic.

For this purpose 2 sheets of drawings

Claims (11)

Patent claims: 1. Clamping overrunning clutch with an outer ring with a cylindrical bore and a rotating body rotatably mounted in it coaxially to it, as well as at least one tangential shape element held with spring pressure in a wedge gap between the outer ring and the rotating body and connected to the latter with play, which is drawn in the clamping direction into the wedge gap and in Freewheeling direction runs up from this, characterized in that a braking device acting on the tangential wedge (3, 3 ") is provided, which when it is entrained by the rotating body (2, 2 ¹ , 2") with a force component directed against the direction of rotation of the rotating body applied ?. Clamping overrunning clutch according to claim 1, characterized in that the braking device is designed as a radially deformable sliding ring (6, 6 ', 6 ") mounted between the rotating body (2, 2", 2 ") and the tangential wedge (3, 3") is, which revolves at a lower angular speed in the freewheeling direction than the rotating body (2,2 '. 2 "). 3. jaw overrunning clutch according to claim 2, characterized in that the zeniralsymmetrische, z. B. oval or rounded polygonal body of revolution (2, 2 ', 2 ") at at least two points (A, B) of its circumference above the sliding ring (6,6', 6") surrounding it on the inner wall (7) of the outer ring (t) is supported by braking the sliding ring 4. Clamping one-way clutch according to claim 2, characterized in that the sliding ring (6 ') and the outer ring (1) are in engagement with one another by means of teeth (9, 10). 5. Clamping one-way clutch according to one of claims 1 to 3, characterized in that the rotary body (2 "), preferably in one piece, with an inner ring (17) of a ball bearing in the Outer ring (1) is connected to the circular ring and that the sliding ring (6 ") with the ball cage (19) is coupled. 6. Clamping one-way clutch according to claim 5, characterized in that the sliding (6 ") as an elastic band made of individual lamellae (18) connected by worm springs (20 '), is preferably made of steel 7. Clamping one-way clutch according to claim 6, characterized in that the lamellae (18 ') one in a circumferential groove (27) of the rotating body (2 ") have engaging central eyelet bend (27) for receiving a worm spring (20 '). 8. Clamping one-way clutch according to claim 6, characterized in that the lamellae (18) at both ends protruding beyond the end faces of the rotating body (2 ") for receiving of worm feathers (20) are bent back like an eyelet. 9. jaw overrunning clutch according to claim 5, characterized in that an am Ball cage (19) attached radial pin (22) a recess in a transverse tab (21) of a lamella (18) loosely sliding through. 10. Clamping one-way clutch according to claim 6, characterized in that a transverse tab a lamella engages in a Radtalnut of the Kugelkäligs 11. Clamping one-way clutch according to claim, characterized in that the spring force of the worm spring (20) is chosen such that at the nominal speed, the elastic band forming the sliding ring is moved by the centrifugal force in the essentially on the tangential wedge (3 ") IZ clamping jaw overrunning clutch according to claim 1, characterized in that the tangential shaped wedge (3 ") with an in a circular arc-shaped hanging groove (24) in the end face (25) of the Rotary body (2 ") engaging with play in the circumferential direction, preferably integrally formed Hook attachment (23) is provided