DE102010018519A1 - Rotatable roller bearing has inner bearing ring, outer bearing ring and multiple rolling elements which are arranged between inner and outer bearing rings - Google Patents

Abstract

The rotatable roller bearing (10) has an inner bearing ring (1), an outer bearing ring (2) and multiple rolling elements (3) which are arranged between the inner and outer bearing rings. The outer bearing ring is rotated opposite to the inner bearing ring. A rolling body is arranged between the adjacent rolling elements. The rolling body is rotatable during a rotary motion of the rolling elements in opposite rotational direction. The rotary motion is generated by a rotation of the outer bearing ring opposite to the inner bearing ring.

Description

The invention relates to a rotatable rolling bearing according to the preamble of patent claim 1.

Rotatable bearings are used in many areas of technology, often in the form of ball bearings. Conventional ball bearings have a ball cage through which the balls, which serve there as rolling elements, are held. The ball cage has the function to ensure a certain distance between the balls and keep the balls at a constant distance. A disadvantage of the ball cage that undesirable friction between the balls and the ball cage occurs, through which the ball bearing has a considerable frictional resistance. In conventional ball bearings, therefore, attempts are made to make the ball cage so that the friction is minimized.

From the DE 84 23 565 U1 is a rotationally damped bearings known. The function of the conventional ball cage is taken over there by a arranged between the cover plate and the rolling elements damping element. Again, the problem of friction between the rolling elements and the damping element occurs.

The invention is based on the object to provide a rotatable rolling bearing with reduced frictional resistance.

This object is achieved by the invention defined in claim 1. The subclaims indicate advantageous embodiments of the invention.

According to the invention, a roller body arranged between two adjacent rolling elements is proposed, which is rotatable in opposite directions to the rolling elements. Here, between each two adjacent rolling elements, a rolling body may be arranged, so that a plurality of rolling elements is distributed over the circumference of the rolling bearing. Advantageously, the number of rolling elements corresponds to the number of rolling elements used in the rolling bearing.

With the proposed rolling body, the disadvantages of the fixed compared to the rotational movement of the rolling elements ball cage can be overcome. By the rolling body, the adjacent rolling elements are, so to speak, roller-mounted and thus very low friction rotation. Here, a rolling body of adjacent rolling elements in the manner of a gear is rotated in opposite directions to the rolling elements, so that the relative movement is minimized at the contact surfaces between rolling elements and rolling elements and thus the friction losses are minimized. Advantageously, the rolling body also acts as a spacer between adjacent rolling elements, so that no additional component is required as a spacer. By ensuring a certain distance between adjacent rolling elements they can not come into contact with each other. Thus, a friction between co-rotating rolling elements and thus in opposite direction to each other running contact surfaces of the rolling elements is avoided.

Calculations have shown that with the invention, a rotatable roller bearing can be realized with respect to conventional bearings approximately halved frictional resistance.

The invention is basically suitable for all types of roller bearings, in particular regardless of the type of rolling element. The rolling elements can be shaped, for example, as a ball, cone or cylinder. Advantageously, other shapes, such as barrel shape or combinations of spherical and cylindrical shape can be used.

According to an advantageous embodiment of the invention, the rolling bearing is cageless. This allows a simple and low-friction construction of the rolling bearing.

According to an advantageous embodiment of the invention, two adjacent rolling elements are held by means of the rolling body at a distance from each other. This has the advantage that no separate, possibly frictional components are required to realize the desired distance between the rolling elements. Overall, this makes it possible to realize a simple and inexpensive construction of the rolling bearing.

Basically, the rolling body can be freely rotatable between the adjacent rolling elements and requires no special storage. According to an advantageous development of the invention, the inner ring or the outer ring has at least one inner groove extending in a circumferential direction in a side wall. The rolling body extends in its longitudinal direction, which corresponds to the rotational or rotational axis of the rolling body, into the inner groove. This has the advantage that the rolling body can be guided defined in the inner groove and the guide can be additionally designed friction. The rolling body can, for. B. have a substantially cylindrical shape.

According to an advantageous embodiment of the invention, the rolling body has a smaller distance from the inner ring than the outer ring. This has the advantage that the axis of rotation of the rolling body can be arranged below the axis of rotation of the adjacent rolling elements, so that the rolling body can be held by the adjacent rolling elements in a defined position. Hereby are No special holding elements for the rolling body required. As a reference for determining the distance, the axis of rotation of the rolling body or serve the inner ring and the outer ring respectively facing surface of the rolling body. In an advantageous embodiment of the invention, the axis of rotation of the rolling body has a smaller distance from the inner ring than a circular arc through the points of the rolling elements, which have the smallest distance from each other. Such an arrangement has the further advantage that the centrifugal force generated during operation of the rolling bearing, by which the rolling body is acted upon in the direction of the outer ring, is used so that the rolling body is held in a defined manner between the adjacent rolling bodies. As a result, the rolling bearing can be designed even lower friction.

According to an advantageous embodiment of the invention, the inner groove on a running along the entire circumference of the inner groove bearing edge, on which the rolling body comes to rest. In this way, so to speak, a rail-like mounting of the rolling body can be realized in the inner groove, which is also friction-reducing.

As can be seen, there are areas in which the rolling body touches the adjacent rolling elements. There are also areas in which the rolling body touches the inner groove.

According to an advantageous development of the invention, the outer circumference of the rolling elements coming into contact with the areas of the rolling body is matched to the outer circumference of the inner groove or the bearing edge of the inner groove coming into contact outer surface of the rolling body. The vote is such that upon rotation of the outer bearing ring relative to the inner bearing ring, the contact points between the rolling body and the rolling elements on the one hand and between the rolling body and the inner groove or the support edge on the other hand each have substantially the same peripheral speeds. As a result, the rolling distances of the mutually rolling surfaces are each substantially the same, so that there is no relative movement at the contact surfaces. By avoiding the relative movements on the contact surfaces, the rolling bearing can be performed even more friction.

According to an advantageous embodiment of the invention, the rolling body in the circumferential direction of the rolling body extending annular support elements, which come into contact with the adjacent rolling elements. The support elements also have an additional friction-reducing effect. In addition, a defined position of the rolling body in its longitudinal direction is ensured by the support elements. By the support elements of the rolling body is centered so to speak between the adjacent rolling elements.

According to an advantageous embodiment of the invention, the outer circumference of coming into contact with the rolling elements annular support elements is matched to the outer periphery of the inner groove or the bearing edge coming into contact outer surface of the rolling body, such that upon rotation of the outer bearing ring relative to the inner bearing ring the Contact points between the rolling body and the rolling element and between the rolling body and the inner groove or the support edge each have substantially the same peripheral speeds.

The inner and / or the outer bearing ring can be designed in several parts, for. B. to simplify the assembly of the parts of the bearing.

The invention will be explained in more detail by means of embodiments using drawings. Show it:

1 - a rolling bearing and

2 - A detailed view of the rolling bearing according to 1 and

3 - A detailed view of the rolling bearing according to 2 from the viewing direction A) and

4 - A detailed view of the rolling bearing according to 2 from the viewing direction B) and

5 - embodiments of rolling elements and

6 - Another embodiment of a rolling bearing in a comparable perspective as in 3 ,

In the figures, like reference numerals are used for corresponding elements.

In the 1 is a rolling bearing 10 to recognize in plan view. The rolling bearing 10 has an outer bearing ring 2 , an inner bearing ring 1 and one between the inner bearing ring 1 and the outer bearing ring 2 formed rolling element receiving space 11 on. In the rolling element receiving space 11 are a plurality of rolling elements 3 over the circumference of the rolling bearing 10 arranged distributed. The rolling bearing 10 is in the 1 with opened rolling element receiving space 11 shown. In practical applications, the rolling element receiving space becomes 11 closed with a sealing washer to protect the rolling elements from external influences.

In the following, it is assumed by way of example that the outer bearing ring 2 in the direction of in 1 illustrated arrow relative to the inner bearing ring 1 is turned. Insofar it is assumed that the inner bearing ring 1 does not move. However, the statements generally apply to any type of relative movement between the inner bearing ring 1 and the outer bearing ring 2 in which a rotational movement is carried out in any direction.

The 2 shows a section of the rolling bearing 10 according to 1 in an enlarged view. Visible are the inner bearing ring 1 , the outer bearing ring 2 , the rolling element receiving space 11 as well as three rolling elements 3 , Between two rolling elements 3 is each a rolling body 4 arranged. The rolling bodies 4 are just like the rolling elements 3 over the circumference of the rolling bearing 10 arranged distributed.

In the assumed rotational movement of the outer bearing ring 2 in the direction of the arrow, ie counterclockwise, lead the rolling elements 3 a rotational movement with the same direction of rotation as the outer bearing ring 2 off, but at a slower speed. The rotational movement of the rolling elements 3 is through each in the rolling elements 3 indicated arrows indicated. The rolling elements 3 rotate around a respective axis of rotation 22 passing through a cross in the middle of each rolling element 3 is reproduced. The rolling bodies 4 lead a rotational movement in opposite directions of rotation to the direction of rotation of the rolling elements 3 out. The rotational movement of the rolling elements 4 is through each above the rolling body 4 illustrated arrows symbolizes. The rolling bodies 4 rotate around a rotation axis 9 passing through respective crosses in the rolling bodies 4 are shown. The rolling bodies 4 are in this case of the adjacent rolling elements 3 put into the rotary motion.

With the dashed line 12 is the circle defined by the adjacent, each closest to the surface points of the rolling elements. The circle 12 would thus be used as a connecting line between the contact points of the rolling elements 3 arise when the rolling bodies 4 would not be present and the rolling elements 3 could touch directly. The by the axes of rotation 22 the rolling elements 3 formed circle has a larger diameter than the circle 12 , As can be seen, the axes of rotation are 9 the rolling body 4 each within the circle 12 arranged. Accordingly, the axes of rotation 9 thus closer to the inner bearing ring 1 as the outer bearing ring 2 arranged.

The 2 symbolized by the arrow A is a viewing direction on two rolling elements 3 and an intermediate rolling body 4 in the 3 - without the outer ring 2 - is reproduced. By the arrow B, a viewing direction is symbolized, which in the 4 is reproduced.

The 3 shows two rolling elements 3 in the form of balls. One between the balls 3 arranged rolling body 4 has a cylindrical part 20 and two in the circumferential direction of the cylindrical part 20 of the rolling body 4 extending annular support elements 7 . 8th on. About the annular support elements 7 . 8th that z. B. at points of contact 19 . 21 with the ball 3 come into contact, a low-friction small contact surface and a centering of the rolling body 4 between the balls 3 ensured.

The 4 shows the inner bearing ring 1 , the outer bearing ring 2 according to 3 described sphere 3 and according to 3 Rolling body described 4 , The inner bearing ring 1 has a concave curved ball tread 12 on. The outer bearing ring 2 is constructed in three parts, namely a ball raceway 40 , a first retaining ring 41 and a second retaining ring 42 , The ball race 40 has a corresponding concave curved ball tread 13 on. On the ball raceway 40 are from the left and right respectively the first and the second retaining ring 41 . 42 pressed. Between the ball raceway 40 and the retaining rings 41 . 42 For this purpose, a press fit is provided. The assembly takes place under heating of the retaining rings 41 . 42 , Due to the three-part design of the outer bearing ring 2 will be the assembly of the balls 3 and the rolling body 4 simplified in the rolling bearing. Also the inner bearing ring 1 can be multi-part, z. B. in two parts, be executed.

The outer bearing ring 2 has a right internal groove 5 and a left inner groove 6 on. The inner groove 5 is in a sidewall 23 of the second retaining ring 42 intended. The inner groove 6 is in a sidewall 24 of the first retaining ring 41 intended. The interior grooves 5 . 6 run in the circumferential direction in the respective retaining rings 41 . 42 , ie in the direction of in 2 As can be seen, extends the cylindrical part 20 of the rolling body 4 in the longitudinal direction, ie in the direction of the longitudinal axis 9 of the rolling body 4 , in the interior grooves 5 . 6 into it. On the underside has the respective inner groove 5 . 6 a respective support edge 14 . 15 on, on which the rolling body 4 comes to rest and rolls on it. The points of contact between the bearing edges 14 . 15 and the rolling body 4 are through the arrows 17 . 18 marked. The bearing edges 14 . 15 For example, they may have a semicircular profile.

The 5 shows exemplary advantageous embodiments of rolling bodies 4 with their respective axes of rotation 22 , Shown is a spherical rolling body 50 , a barrel-shaped rolling body 51 and a combined spherical and cylindrical rolling element having a central spherical portion 52 and outer cylindrical areas 53 , The rolling bodies according to 5 are advantageous for the rolling bearing 10 used. On the outer circumference of the respective roll body 50 . 51 . 52 the annular support elements 7 . 8th be provided.

The 6 shows a further embodiment of the rolling bearing 10 in which cylindrical rolling elements 3 be used. The rolling body 4 according to 6 has a cylindrical area 20 on. In the middle of the cylindrical area 20 is a spherically shaped area 60 intended. The cylindrical rolling elements 3 each have a hollow groove 61 on. The hollow groove 61 can in terms of their shape to the spherical area 60 of the rolling body 4 be adjusted. The hollow groove 61 can also have other shapes, such as. B. in the 6 illustrated rectangular profile. The spherical area 60 of the rolling body 4 rolls thereby at points of contact 62 . 63 in the grooves 61 from. This can also be a centering of the rolling body 4 with respect to the rolling elements 3 will be realized.

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 8423565 U1 [0003]

Claims (9)

Rotatable rolling bearing ( 10 ) with an inner bearing ring ( 1 ), one opposite the inner bearing ring ( 1 ) rotatable outer bearing ring ( 2 ) and a plurality of rolling elements ( 3 ), which are arranged between the inner and the outer bearing ring, characterized in that between two adjacent rolling elements ( 3 ) a rolling body ( 4 ) arranged at one by a rotation of the outer bearing ring ( 2 ) in relation to the inner bearing ring ( 1 ) generated rotational movement of the rolling elements ( 3 ) is rotatable in opposite directions of rotation. Rolling bearing according to claim 1, characterized in that the rolling bearing ( 10 ) is cageless. Rolling bearing according to one of the preceding claims, characterized in that two adjacent rolling elements ( 3 ) by means of the rolling body ( 4 ) are kept at a distance from each other. Rolling bearing according to one of the preceding claims, characterized in that the rolling body ( 4 ) a smaller distance to the inner ring ( 1 ) as the outer ring ( 2 ) having. Rolling bearing according to one of the preceding claims, characterized in that the inner ring ( 1 ) or the outer ring ( 2 ) at least one in a side wall ( 23 . 24 ) extending in the circumferential direction inner groove ( 5 . 6 ) and the rolling body in its longitudinal direction in the inner groove ( 5 . 6 ) extends into it. Rolling bearing according to claim 5, characterized in that the inner groove ( 5 . 6 ) one along the entire circumference of the inner groove ( 5 . 6 ) running support edge ( 14 . 15 ), on which the rolling body ( 4 ) comes to the edition. Rolling bearing according to one of claims 5 or 6, characterized in that the outer circumference of the rolling bodies ( 3 ) areas of the rolling body ( 4 ) is matched to the outer circumference of the inner groove ( 5 . 6 ) or the supporting edge ( 14 . 15 ) coming into contact outer surface of the rolling body ( 4 ), such that upon rotation of the outer bearing ring ( 2 ) in relation to the inner bearing ring ( 1 ) the contact points between the rolling body ( 4 ) and the rolling element ( 3 ) and between the rolling body ( 4 ) and the inner groove ( 5 . 6 ) or the supporting edge ( 14 . 15 ) each have substantially the same peripheral speeds. Rolling bearing according to one of the preceding claims, characterized in that the rolling body ( 4 ) in the circumferential direction of the rolling body ( 4 ) extending annular support elements ( 7 . 8th ), which with the adjacent rolling elements ( 3 ) come to the plant. Rolling bearing according to claim 9, characterized in that the outer circumference of the rolling bodies ( 3 ) coming to rest annular support elements ( 7 . 8th ) is matched to the outer circumference of the inner groove ( 5 . 6 ) or the supporting edge ( 14 . 15 ) coming into contact outer surface of the rolling body ( 4 ), such that upon rotation of the outer bearing ring ( 2 ) in relation to the inner bearing ring ( 1 ) the contact points between the rolling body ( 4 ) and the rolling element ( 3 ) and between the rolling body ( 4 ) and the inner groove ( 5 . 6 ) or the supporting edge ( 14 . 15 ) each have substantially the same peripheral speeds.

Images