DE102019115140A1 - roller bearing - Google Patents

Abstract

The invention relates to a rolling bearing with an outer ring (2), an inner ring (3) and rolling elements in the form of balls (6, 7) arranged in between in two rows (4, 5), each row (4, 5) on one Raceway (8, 9, 10, 11) rolls on the outer ring (2) and on the inner ring (3). According to the invention, each row (4, 5) is connected to the two raceways (8, 9, 10, 11), with both rolling contact points (a, b, c, d) on the outer ring (2) being offset from the rolling contact points (e, f, g, h) on the inner ring (3).

Description

Field of invention

The invention relates to a roller bearing with an outer ring, an inner ring and in between in two rows on a raceway on the outer ring and on the inner ring rolling elements rolling elements in the form of balls, which is particularly advantageous for the storage of parts or components of agricultural machines such as planters or seeders or other agricultural equipment can be used.

Background of the invention

Such multi-row rolling bearings are used in various applications, especially where larger loads have to be supported. In order to support both axial and radial loads, rolling bearings with different types of rolling elements, namely balls and rollers, are often used. An example is out DE 30 04 672 A1 known, where a double row rolling bearing is described which has a row of barrel rollers and a row of balls. There the balls are guided through a comb cage, whereas the barrel rows are full complement.

Furthermore, a roller bearing is known which has three rows of rolling elements to support axial and radial loads, namely two rows of balls and a central row of rollers. Such a bearing is very well suited for supporting the various loads that are present, such as occur, for example, in the area of bearings for agricultural machines or the like. The disadvantage here, however, is the size of the bearing, which naturally builds up considerably axially due to the three rows.

Object of the invention

The invention is based on the object of specifying a roller bearing with a compact design that is improved over the prior art and is suitable for different load conditions.

Description of the invention

To solve this problem, the invention provides for a rolling bearing of the type mentioned that each row is supported on the two raceways via four-point contact bearings, the two rolling contact points on the outer ring being offset from those on the inner ring.

The invention proposes a roller bearing that is, as it were, a combination of a two-row angular contact ball bearing with a four-point contact ball bearing. The raceways on the outer and inner rings are designed in such a way that the respective balls are supported on the raceways via a four-point contact bearing or roll on them, so that there are two contact points per raceway and ball. If you consider the connecting lines running through the center of the sphere between the contact points, each row of spheres is designed as a four-point bearing. This four-point bearing, so to speak "superimposed", is now provided according to the invention that the rolling contact points on the outer ring are offset from those on the inner ring to form an angular contact bearing arrangement, that is to say that two rolling contact points formed on the outer and inner ring are not radially aligned, but are laterally offset from one another. This contact point offset leads to an angular contact arrangement in combination with a four-point bearing.

This embodiment of the ball bearings of the two rows of balls according to the invention results in a roller bearing which enables both axial and radial loads to be absorbed very well, but at the same time also enables a sufficient speed of rotation. The design as a four-point angular contact ball bearing enables, on the one hand, the support of high axial loads through the design of the rolling element raceways with correspondingly high raceway shoulders with a correspondingly high number of rolling elements, which means that the bearing is very load-bearing, as well as high axial forces can be recorded in both directions. The additional “skewing” via the defined axial or circumferential offset of the rolling element contact points on the outer and inner ring relative to one another also enables the load-bearing capacity to be increased in the radial direction, which means that the bearing becomes stiffer in the radial direction.

This high axial and radial load-bearing capacity is achieved solely by the corresponding storage of the two rows of balls; the additional integration of different, for example roller or barrel-shaped rolling elements or the integration of a third row of rolling bodies with rollers or barrels is not necessary for this, which means that the invention Storage is designed much more simply, is also much more compact and small and can therefore also be used in applications with little space.

The rolling contact points of both rows are expediently arranged symmetrically with respect to a central plane of the rolling bearing. The bearings of the two rows of balls are designed to be identical to one another, but designed in mirror image with respect to the radial center plane of the bearing, so that the same contact pattern or the same load capacity is given on both rows.

In this case, the two rolling contact points of the two rows on the outer ring raceways are expediently arranged closer to one another than the two rolling body contact points of the two rows of the inner ring raceways. If one considers the respective center lines running through the center of the sphere between the two connecting lines between the contact points, which also run through the center of the sphere, an O-arrangement results with regard to this center line, that is, the center lines are radially outward towards each other and radially inward run away from each other. This O-arrangement defining angle between these center lines, which, as stated, between the two connecting lines running through the center of the sphere and connecting the corresponding rolling contact points on the outer and inner ring, should be at an angle of 20 ° - 65 ° to the normal to the cylindrical Run outer surface of the outer ring. This means that there is a corresponding leeway with regard to the positioning and the distance between the contact points on the outer and inner ring. This angle should preferably be between 40 ° and 50 °.

There is also a corresponding possibility of variation with regard to the angle between the two connecting lines, that is to say the pressure angle. The angle between the two connecting lines that run through the center of the sphere and connect the corresponding rolling contact points on the outer and inner ring should be between 20 ° - 70 °. Here, too, the angle is preferably between 40 ° and 50 °.

By setting the corresponding angular relationships defined above, it is possible to set the axial and radial load-bearing capacity within the rolling bearing according to the invention over a corresponding bandwidth and thus to adapt to the requirements given during operation.

The outer ring itself is expediently made in one piece and curves with its two raceways towards the center towards the inner ring, that is, the two raceway shoulders in the area of the bearing means are drawn radially inwards towards the inner ring. So the outer ring is massive. In contrast, the inner ring is divided, it consists of two separate ring sections, each with a raceway, which curve in the direction of the axial end face of the respective ring section towards the outer ring. This means that on these ring sections the preferably terminal raceway shoulders run radially outward to the outer ring. The raceway shoulders absorb the corresponding high axial forces in both directions and the corresponding high radial forces.

The balls in each row are preferably held in a separate cage. Such a cage can be made of brass or a plastic, preferably polyamide. The cage is preferably a snap cage. The two cages are expediently arranged adjacent to one another in the area of the parting plane of the two ring sections, that is to say they lie axially against one another in the area of the central plane of the roller bearing or are positioned closely adjacent to one another.

Figure list

• 1 eine geschnittene Perspektivansicht eines erfindungsgemäßen Wälzlagers,
• 2 eine Aufsicht auf die Schnittebene des Wälzlagers in einer Teilansicht aus 1, und
• 3 eine vergrößerte Darstellung der Ansicht aus 2.

A preferred embodiment of the roller bearing designed according to the invention is explained in more detail below with reference to the accompanying drawings. Show:

• 1 a sectional perspective view of a rolling bearing according to the invention,
• 2 a plan view of the sectional plane of the roller bearing in a partial view 1 , and
• 3 an enlarged representation of the view 2 .

Detailed description of the drawings

1 shows a roller bearing according to the invention 1 , with an outer ring 2 , an inner ring 3 and in between in two rows 4th , 5 running rolling elements in the form of balls 6th , 7th . Any row 4th , 5 runs on appropriate careers 8th , 9 on the outer ring 2 respectively careers 10 , 11 on the inner ring. The outer ring 2 itself is a massive component, while the inner ring 3 from two ring sections 3a , 3b consists of assembling the rolling bearing 1 to enable. The balls 6th , 7th of the two rows 4th , 5 themselves are in appropriate cages 12th , 13th out, which can be metal or plastic cages, preferably made of brass or polyamide, where the balls 6th , 7th are included in corresponding snapshots.

2 shows an enlarged partial view of the roller bearing 1 with a view of the cutting plane. The careers 8th , 9 of the outer ring 2 are over appropriate career shoulders 14th , 15th formed so that they extend curved radially inward in the area of the bearing center plane.

In contrast, are on the ring sections 3a , 3b final career shoulders 16 , 17th running the careers 10 , 11 form or define, and which are curved radially outwards.

In the roller bearing according to the invention 1 how in particular 3 shows is every row 4th , 5 respectively every ball 6th , 7th via a four-point contact bearing on the raceways 8th , 9 and 10 , 11 stored. On the raceways on the outer ring side 8th , 9 are the four rolling contact points a , b , c and d realized and shown, while on the inner ring-side raceways 10 , 11 the rolling contact points e , f , G and H given are. The storage of each row 4th , 5 is therefore a four-point support.

As 3 but clearly shows are the rolling contact points a - g on the outer ring 2 relative to the rolling contact points e - h on the inner ring 3 respectively the ring sections 3a , 3b arranged offset to one another in the axial or circumferential direction. The rolling contact points a , b are positioned closer to each other than the rolling contact points e , H . This causes the center line M1 or. M2 through the respective center of the sphere K1 or. K2 extend and centered between the connecting lines V1 and V2 respectively V3 and V4 , each also through the center of the sphere K1 or. K2 run and connect two rolling contact points with each other, each at an angle α to the normal N on the lateral surface 18th of the outer ring 2 that is <90 °. This angle is preferably between 20 ° and 65 °, in particular between 40 ° and 50 °. The connecting line connects V1 the rolling contact points a and f , the connecting line V2 connects the rolling contact points b and e , the connecting line V3 connects the rolling contact points c and H and the connecting line V4 connects the rolling contact points d and G . It can be seen that this quasi-twisted contact point arrangement leads to the connection lines being present V1 and V3 are arranged running closer to the vertical than they would be if the corresponding rolling contact points were radially aligned with each other, so if, as is usual with four-point bearings, the rolling contact point is present a with the rolling contact point e is radially aligned, the rolling contact point b with the rolling contact point f etc. This enables better absorption of radial loads, which means that the radial load-bearing capacity is significantly increased.

At the same time is the respective connecting line V2 and V4 arranged tilted more relative to the vertical than it would be if the rolling contact points were radially aligned with one another as described above. This in turn improves the axial load absorption.

The angle β between the connecting lines V1 and V2 or. V3 and V4 should be between 20 ° - 70 °, preferably also approx. 40 ° - 50 °.

Since the structure is symmetrical to the center plane, the angles α and β of both partial supports or both rows are consequently 4th , 5 identical.

The corresponding course of the connecting lines can be seen by varying the contact point arrangement accordingly V1 - V4 as well as the center lines M1 , M2 can be set or influenced, which can also be used to set the respective axial and radial load capacity.

List of reference symbols

1

roller bearing

2

Outer ring

3

Inner ring

3a

Ring section

3b

Ring section

4th

line

5

line

6th

Bullet

7th

Bullet

8th

career

9

career

10

Outer ring

11

Outer ring

12

Cage

13th

Cage

14th

Career shoulder

15th

Career shoulder

16

Career shoulder

17th

Career shoulder

18th

Outer surface

a - h

Rolling contact point

M1, M2

Center line

K1, K2

Center of the sphere

V1 - V4

Connecting line

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• DE 3004672 A1 [0002]

Claims (8)

Rolling bearing, with an outer ring (2), an inner ring (3) and rolling elements in the form of balls (6, 7) arranged in between in two rows (4, 5), each row (4, 5) on a respective raceway (8 , 9, 10, 11) on the outer ring (2) and on the inner ring (3), characterized in that each row (4, 5) has a 4-point contact bearing on the two raceways (8, 9, 10, 11 ) is mounted, both rolling contact points (a, b, c, d) on the outer ring (2) being offset to the rolling contact points (e, f, g, h) on the inner ring (3). Roller bearings after Claim 1 , characterized in that the rolling contact points (a to h) of both rows (4, 5) are arranged symmetrically with respect to a central plane of the rolling bearing (1). Roller bearings after Claim 1 or 2 , characterized in that the two rolling contact points (a, b, c, d) of the two rows (4, 5) on the outer ring raceways (8, 9) are closer to one another than the two rolling contact points (e, f, g, h) of the two rows (4, 5) on the inner ring raceways (10, 11). Roller bearings after Claim 3 , characterized in that the respective center line (M1, M2) between the two connecting lines (V1, V2, V3, V4), which run through the center of the sphere (K1, K2) and the corresponding rolling contact points (a to h) on the outer and Connect the inner ring (2, 3) at an angle (α) of 20 ° - 65 ° to the normal (N) on the cylindrical surface (18) of the outer ring (2). Roller bearings after Claim 3 or 4th , characterized in that the angle (β) between the two connecting lines (V1, V2, V3, V4) which run through the center of the sphere (K1, K2) and the corresponding rolling contact points (a to h) on the outer and inner ring (2 , 3) connect, is between 20 ° -70 °. Rolling bearing according to one of the preceding claims, characterized in that the outer ring (2) is in one piece and its two raceways (8, 9) curve towards the center towards the inner ring (3), while the inner ring (3) consists of two separate ring sections (3a , 3b) each having a track (10, 11) which curves in the direction of the axial end face of the ring section (3a, 3b) towards the outer ring (2). Rolling bearing according to one of the preceding claims, characterized in that balls (6, 7) of each row (4, 5) are guided in a separate cage (12, 13). Roller bearings after Claim 7 , characterized in that the two cages (12, 13) are arranged adjacent to one another in the region of the plane of separation of the two ring sections (3a, 3b).

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