WO2008110140A1 - Multi-row roller bearing - Google Patents

Abstract

The invention relates to a multi-row roller bearing with improved guidance and roll-off properties of the rolling elements (10a, 10b). Said roller bearing comprises at least one pair of rows of rolling elements (10a, 10b) arranged in X alignment, the two rolling element rows (6, 7; 8, 9) of the at least one pair of rows having the same number of rolling elements and the same rotational speed about the longitudinal axis of the roller bearing. The rolling elements (10a, 10b) of the pair of rows roll off on a rimless outer bearing ring (1, 2, 3) and on a rimless inner bearing ring (4, 5). A rotationally symmetric spacer element (13) in the form of a pin-type bulge having a contact surface (14) that is convex in relation to the axial direction is arranged between two axially adjacent rolling elements (10a, 10b). The spacer element (13) is configured on the face on one of the two axially adjacent rolling elements (10a, 10b), the spacer element (13) being axially supported in a recess (15) of the other rolling element (10b, 10a). The multi-row roller bearing also comprises a common, single-piece rolling element cage (18a, 18b) which accommodates both rolling element rows (6, 7; 8, 9) of every pair of rows.

Description

 Name of the invention

Multi-row roller bearing

description

Field of the invention

The invention relates to a multi-row roller bearing, with at least one pair of rows of rolling elements in X-arrangement according to the feature combination of claim 1.

Background of the invention

From US Pat. No. 1,885,852, a two-row or multi-row tapered roller bearing with two rows of rolling elements in an X arrangement is known, in which the rolling elements roll on a non-railed bearing outer ring and a non-bearing bearing inner ring. Between axially adjacent rolling elements, a rotationally symmetrical spacer element is arranged in each case with a contact surface which convexly curved in the axial direction at the end, in the present case spherical or spherically curved contact surface. This spacer element is formed on one of the axially adjacent rolling elements as an end-side, pin-shaped recess which is axially supported in a recess of the other rolling element. Object of the invention

The invention has for its object to provide a further improved multi-row roller bearing of the type described above.

Summary of the invention

It is proposed a multi-row roller bearing, with at least one row pair of rolling elements in an X arrangement, the two Wälzkör- rows of at least one pair of rows have the same number of rolling elements and the same rotational speeds around the longitudinal axis of the roller bearing, wherein the rolling elements of the row pairing on a bordlosen Roll outer bearing ring and a bordlosen bearing inner ring, in which between two axially adjacent rolling elements a rotationally symmetrical spacer element is arranged in the form of a peg-shaped bulge with convexly curved contact surface in the axial direction, wherein the spacer element is formed on the front side of one of the two axially adjacent rolling elements, at in which the spacer element is axially supported in a recess of the other rolling body, and in which in each case a common rolling element K, which is formed in one piece and forms both rows of rolling bodies of each pair of rows, is supported is available fig.

This construction creates a roller bearing with further improved guiding and unwinding properties of the rolling elements, which is easy to manufacture and install at the top.

According to an advantageous embodiment of the invention it is provided that the contact surface of the recess of the other rolling element is formed as far as possible complementary to the contact surface of the spacer element, but at least designed such that between the one rolling element including spacer element and the other rolling elements, an axial force transmission and a mutual Leadership of the same is possible. According to a further embodiment variant of the invention, the spacer element may be formed by a separate element, in particular a separate ball, a barrel or another separate spacer element, with rotationally symmetrical and convexly curved in the axial direction contact surfaces, which is axially supported in the recess of the adjacent rolling elements.

The spacer element may also be formed by an end-face peg-shaped outer surface having a rotationally symmetrical outer contour and having a convexly curved contact surface in the axial direction, which is then axially supported in the recess of the other rolling element.

As the invention further provides particularly preferred, the said one-piece peg-shaped bulge may have a hemispherical, kugelkalot- tenförmige or any other suitable rotationally symmetrical outer contour with a convexly curved contact surface in the axial direction.

It is further provided that the rolling element cage is formed as a sheet metal cage, which advantageously made of a metal strip, provided with cutouts for the rolling elements and finally welded tubular, crimped or joined in other known per se manner.

Also, the rolling element cage may be formed as a deep-drawn part, which may continue to be further processed by subsequent forming.

Finally, a roller bearing of the at least one paired row pairing of the multi-row roller bearing can be designed as a tapered roller, cylindrical roller, barrel or other bearing for accommodating at least axial roller bearing forces. The other paired roller bearing can be identical, but also with different pressure angle, or in different design, eg tapered roller paired with pendulum roller, be formed.

Brief description of the drawings

The invention will be explained in more detail below with reference to the accompanying drawings of some embodiments. It shows

1 is an overall perspective view of a four-row roller bearing of the type according to the invention,

2 shows the roller bearing of FIG. 1 in a partial longitudinal section,

Fig. 3 shows the detail "Z" of FIG. 2, and

Fig. 4 is an exploded perspective view of a rolling element cage of the roller bearing according to the invention.

Detailed description of the drawings

The four-row roller bearing shown in Figures 1 and 2 is essentially two single-row and axially outer bearing outer rings 1 and 2, a middle double row bearing outer ring 3, two double-row bearing inner rings 4, 5 and a plurality in between four rows of rolling elements 6, 7; 8, 9 rolling rolling elements 10a, 10b formed. Between the outer bearing rings 1, 2, 3 are also known per se outer Zwischenrin- 11 arranged, while between the bearing inner rings 4, 5, a single inner intermediate ring 12 is arranged. In the present case, the rolling elements 10a, 10b are formed as tapered rollers, wherein adjacent rows of rolling elements 6, 7; 8, 9 each form a row pairing with rolling elements 10a, 10b in an X arrangement, in which the pressure lines of the individual rows of rolling elements 6, 7; 8, 9 cut each row pairing.

Furthermore, the bearing outer rings 1, 2, 3 and bearing inner rings 4, 5 are formed without a bord, whereby an increased load capacity of the roller bearing is recorded for given external dimensions by the achievable larger roller length over-board bearing rings. In contrast, the size and weight of the roller bearing can be reduced at given load ratings. Furthermore, the production of the bearing outer and inner bearing rings 1, 2, 3, 4, 5 is simplified; the roller bearing is thus inexpensive to produce.

In order to achieve further improved guiding and rolling properties of the rolling bodies 10a, 10b with regard to conventional roller bearings, a rotationally symmetrical spacer element 13 is arranged between the two axially adjacent rolling elements 10a, 10b of each row pairing (FIGS. 2 and 3).

This spacer element 13 is integrally formed as an end-side peg-shaped bulge on one of the two axially adjacent rolling elements 10a and 10b, in this case formed on the respective inner rolling elements 10a and 10b of each row pairing of the four-row roller bearing.

The spacer element 13 also has in each case a convexly curved in the axial direction of the contact surface 14, which in a recess 15 of the end face 16 of the respective other rolling elements 10b, 10a of the respective series mating axially supported such that an axial force transmission and mutual guidance of each adjacent rolling elements 10a, 10b including spacer element 13 of each row pairing is possible. The spacer element 13 in the form of a peg-shaped bulge of one of the two rolling elements 10a, 10b of each row pairing may, for example, have a hemispherical, spherical cap-shaped or other rotationally symmetrical outer contour with a convexly curved contact surface 14 in the axial direction. In the present case, the spacer element 13 is provided with a hemispherical outer contour, the contact surface 14 preferably bears against a contact surface 17 of the recess 15, which is formed as far as possible in a complementary manner, that is spherically profiled (see FIG. 3). However, other profiles of the recess 15 are conceivable, such as conical profiles (not shown in detail).

In any case, however, such mutually corresponding contact surfaces 14, 17 are provided, which ensure an axial force transmission and mutual guidance of the respective adjacent rolling elements 10a, 10b, including the dance element 13 of each row pairing. Depending on which contour pairing of the contact surfaces 14, 17 is selected, a surface or linear load of the mutually corresponding contact surfaces 14, 17 is recorded.

With the knowledge of the invention, it is self-evident to the person skilled in the art that with the arrangement of the rolling elements 10a, 10b, the number of rolling elements of the rolling element rows 6, 7; 8, 9 and the rotational speeds of the same about the bearing axis per row pairing are the same.

In particular, Fig. 2 further shows, each row pairing is an integrally formed and both rows of rolling elements 6, 7; 8, 9 receiving rolling element cage 18a, 18b provided. According to Fig. 4, the rolling element cage 18a, 18b formed as a sheet metal cage, which easily and inexpensively made of a metal strip, provided with punched holes 19 for the rolling elements 10a, 10b and finally welded tubular, crimped or other known per se manner is added.

For assembly, the bearing inner ring 4 or 5, Wälzkörperkäfige 18a and 18b and associated rolling elements 10a, 10b are pressed together each pair of rows so that the rolling elements 10a, 10b, here tapered rollers, are held by the Wälzkörperkäfig 18a bzw.18b. The assembled unit is no longer dismantled after assembly and can be treated as usual, so with the bearing outer rings 1, 2, 3 and with the outer intermediate rings 11 and the inner intermediate ring 12 to a four-row roller bearing according to the embodiment completed and finally be installed.

The above embodiment can be seen from a four-row tapered roller bearing. However, also encompassed by the invention are both any multi-row tapered roller bearings as well as multi-row cylinder roller, barrel or other bearings for receiving at least axial Wälzkörperkräften, said roller bearings can be constructed symmetrically or asymmetrically, if row pairings of the generic type are formed.

reference numeral

1 bearing outer ring

2 bearing outer ring

3 bearing outer ring

4 bearing inner ring

5 bearing inner ring

6 rolling element row

7 row of rolling elements

8 rolling element row

9 rolling element row

10a rolling elements

10b rolling elements

11 outer intermediate rings

12 inner intermediate ring

13 spacer element

14 contact surface on the spacer element 13

15 recess on the rolling elements 10a and 10b

16 end face on the rolling elements 10a and 10b

17 contact surface on the recess 15th

18a rolling element cage

18b rolling element cage

19 punched out

Claims

claims

1. Multi-row roller bearing with at least one pair of rows of rolling elements (10a, 10b) in an X-arrangement, wherein the two rows of rolling elements (6, 7, 8, 9) of the at least one pair of rows the same number of rolling elements and the same rotational speeds around the

Have longitudinal axis of the roller bearing, in which the rolling elements (10a, 10b) of the row pair on a bordlosen bearing outer ring (1, 2, 3) and a bordlosen bearing inner ring (4, 5) roll, in which between two each axially adjacent rolling elements (10a, 10b ) is arranged a rotationally symmetrical spacer element (13) in the form of a peg-shaped bulge with convexly curved in the axial direction contact surface (14), wherein the spacer element (13) frontally on one of the two axially adjacent rolling elements (10a, 10b) is formed in which the spacer element (13) is axially supported in a recess (15) of the other rolling body (10b, 10a), and in each case a common, integrally formed and both rows of rolling elements (6, 7, 8, 9) of each row pair receiving rolling element cage (18a, 18b) is present.

2. Multi-row roller bearing according to claim 1, characterized in that the contact surface (17) of the recess (15) of the other rolling body (10b, 10a) is formed as far as possible complementary to the contact surface (14) of the Oistanzelementes (13), at least is formed such that between the one rolling element

(10a, 10b) including spacer element (13) and the other rolling elements (10b, 10a) an axial force transmission and mutual guidance of the same is possible.

3. Multi-row roller bearing according to at least one of claims 1 or 2, characterized in that the spacer element (13) by a separate element, in particular a separate ball, a barrel or other separate spacer element (13), with rotationally symmetrical and convexly curved in the axial direction Contact surfaces is formed, which is axially supported in the recess (15) of the adjacent rolling elements (10 a, 10 b).

4. Multi-row roller bearing according to at least one of claims 1 to 2, characterized in that the spacer element (13) by one in one piece with one of the two axially adjacent rolling elements

(10a, 10b) formed frontal peg-shaped bulge is formed with rotationally symmetrical outer contour and convexly curved in the axial direction contact surface, which is axially supported in the recess (15) of the other rolling body (10b, 10a).

5. Multi-row roller bearing according to at least the preceding claim, characterized in that the spacer element (13) in the form of the one-piece, peg-shaped bulge has a hemispherical, kugelkalottenförmige or any other suitable rotationally onssymmetrische outer contour with convexly curved in the axial direction contact surface (17).

6. Multi-row roller bearing according to at least one of claims 1 to 5, characterized in that the rolling element cage (18a, 18b) is integrally formed as a sheet metal cage.

7. Multi-row roller bearing according to claim 6, characterized in that the rolling element cage (18a, 18b) made in the form of a sheet metal cage from a sheet metal strip, provided with cutouts (19) for the rolling elements (10a, 10b) and finally welded tubular, crimped or in other ways known per se.

8. Multi-row roller bearing according to at least one of claims 1 to 7, characterized in that the roller bearing is a tapered roller, cylindrical roller, barrel or other bearing for receiving at least axial rolling bearing forces.