Patent Application
20160084310
The invention relates to a rolling-element bearing including at least one inner ring and at least one outer ring, wherein a number of rolling elements having a diameter are disposed between the bearing rings, wherein the rolling elements are held by a cage, wherein the cage is comprised of a number of cage segments, wherein each cage segment is comprised of a frame-shaped structure, wherein a plurality of lateral boundary walls form a receiving pocket for a rolling element, wherein the receiving pocket is dimensioned such that in the load-free state of the rolling-element bearing there is a clearance in the circumferential direction of the rolling-element bearing on the pitch circle of the rolling-element bearing between the lateral surfaces of the receiving pocket, which lateral surfaces face the rolling element, and the rolling element received by the receiving pocket.
A rolling-element bearing of the above-described type is known from WO 2012/076583 A2. Instead of a classical one-piece bearing cage, here the cage is formed by a number of cage segments. This has the advantage that there is a particularly good suitability for large tapered roller bearings, and the loads occurring here can be particularly well supported. Furthermore, the individual cage segments can be installed well; a low cage weight can simultaneously be achieved. The formation of the cage segments makes possible a secure receiving of the rolling element and a reliable guiding of the cage segment on the rolling element. In intended usage here the cage segments do not come into contact; they are not connected to one another.
US 2012/0082409 A1, DE 10 2006 022 951 A1, DE 11 2009 002 624 T5, DE 20 2008 017 091 U1, DE 102 46 825 A1, DE 31 14 325 A1, and JP 2012 026 534 A disclose further similar and also different solutions.
Here the mentioned segmented cages have been proven in particular in large bearings. In operation, forces arise between the cage segments and the adjacent rolling elements. They are both dynamic and also static forces depending on the operating state of the rolling-element bearing.
The cage segments should be as thin-walled as possible in order to be able to use as many rolling elements as possible, which, however, is limited because the cages should not be damaged by the forces mentioned.
The object of the invention is to further develop a bearing of the above-described type such that the disadvantage mentioned can be eliminated. Accordingly the cage segments should be designed such that on the one had they can be kept small in the circumferential direction in order to be able to accommodate as many rolling elements as possible in the bearing. However, then they should also be designed such that even in the operating state under high load no negative effects occur on the running behavior of the bearing. Overall an improved running behavior of the rolling-element bearing should thereby result.
The solution of this object by the invention is characterized in that the clearance in each axial section of the rolling-element bearing satisfies the relationship:
cmax≧c≧cmin
with:
c
min=0.01*Dw−0.5 mm and
c
max=0.02*Dw−0.4 mm,
wherein the diameter of the rolling-element bearing is at least 50 mm.
The clearance (in mm) thus results in the defined range based on the diameter of the rolling element Dw (in mm) in each axial section, provided the diameter is not in any case constant over the axial extension of the rolling element (as in the case of a cylindrical roller bearing). The diameter of the rolling element Dw is multiplied by the factors mentioned (0.01 or 0.02), and the respective mentioned amount (0.5 mm or 0.4 mm) is deducted in order to obtain the minimum and the maximum clearance c.
Here a cage segment preferably receives a rolling element with its receiving pocket, wherein a rolling element following this rolling element in the circumferential direction is kept free from a cage segment so that rolling elements located in a receiving pocket and rolling elements not located in a receiving pocket are alternately disposed in the circumferential direction. Here the cage segment preferably includes two running surfaces, each for a rolling element adjacent in the circumferential direction.
Generally, with uniform distribution of the clearance in the rolling-element bearing on the pitch circle of the rolling-element bearing, there is a clearance in the circumferential direction of the rolling-element bearing between the running surface of the cage segment and the rolling element adjacent to the cage segment in the circumferential direction. Here between the clearance (c) between the lateral surfaces of the receiving pocket and the rolling element received in the receiving pocket, and the total clearance (x) (i.e., summed over the entire circumference) between the running surface of the cage segment and the rolling element adjacent to the cage segment in the circumferential direction, there is preferably the relationship:
c<0.2 x.
The cage segments can be rolling-element-guided, raceway-guided, or flange-guided or shoulder-guided.
The cage segments are preferably formed as one-piece plastic molded parts.
The invention proposal is preferably used in a tapered roller bearing or in a cylindrical roller bearing.
The inventive concept leads to a clearance in the cage pocket, which is set such that with the loading of the cage in the nominal operating state of the rolling elements they can run freely in the interior of the cage without being clamped by the surrounding cage. However, in the rarely occurring operating states having significantly higher loads, these loads press the cage together so far that the rolling element deploys its support effect and protects the cage from damage. Due to the rarity of these occurrences and their short duration, the clamping of the rolling elements under these conditions has no negative effect on the further operating behavior of the bearing. Thus a high security against extreme operating states is achieved with smaller overall dimensions.
Inside the pocket of the cage segment the rolling element has a defined clearance (c) in the circumferential direction of the bearing. Here the clearance is selected and set such that upon exceeding a certain load on the cage segment, contact occurs between the rolling element lying in the receiving pocket and the cage segment, which leads to an additional supporting effect and improves the force-absorbing ability of the cage.
If a larger region of the bearing circumference is unloaded, the cage segments are loaded in the respective lower part of the unloaded zone by the summed mass of the rolling elements lying thereover. The clearance (c) is dimensioned sufficiently large such that under these loads a clamping of the rolling element inside the receiving pocket does not result.
In the normal operation of the rolling-element bearing the clearance (c) is sufficiently dimensioned such that such a large deforming does not result that would lead to a clamping of the rolling element inside the receiving pocket. Since the force, up to which the rolling element still has clearance in the receiving pocket, can be set in a controlled manner, it can be chosen at which loads contact is present and at which not yet.
However, the cage clearance (c) is also set in a targeted manner such that when exceeding a certain load of an adjacent rolling element on the cage segment, the resulting cage deformation is so large that the rolling element is clamped inside the receiving pocket of the cage segment, and the cage is thus supported by the rolling element. The load that the cage can withstand thereby increases.
The proposed maximum and minimum cage clearance takes into account the elastic behavior of the cage material and results from the above-mentioned relationships for suitable roller sizes, i.e.:
cmax≧c≧cmin
with:
c
min=0.01*Dw−0.5 mm and
c
max=0.02*Dw−0.4 mm,
with c (in mm) as the clearance in the cage pocket in the circumferential direction of the bearing and Dw as the roller diameter (in mm).
The inexpensive plastic cage segments can also be used with larger roller masses.
With the proposed concept, large bearings are preferably equipped with cylindrical rollers or tapered rollers, wherein one-pocket segments are preferably provided; multiple-pocket-segment cages are also possible.
In an advantageous manner an increase of the supportable loads on the segmented bearing cage thus results due to the supporting effect of the adjacent roller elements.
An exemplary embodiment of the invention is depicted in the drawings:
In the figures the inventive concept is illustrated for the use in a tapered roller bearing.
The rolling-element bearing 1 in the form of a tapered roller bearing includes an inner ring 2 and an outer ring 3, wherein rolling elements 4, 4′ are disposed between the bearing rings 2, 3. The rolling elements 4, 4′ are not held by a classical cage: rather, cage segments 5 are provided, which are disposed between the rolling elements. For details in this regard reference is expressly made to WO 2012/076583 A2 of the applicant.
Each cage segment 5 includes a frame-type structure, which is formed by four boundary walls; boundary walls 5, 6, and 7 are visible in the Figures, i.e. three of the altogether four walls that form a receiving pocket 9 for a rolling element 4.
In each axial section the conical rolling element 4 has a diameter Dw. Here the rolling elements lie on a pitch circle 10 (course of the centerpoints of the rolling elements 4).
The cage pockets 9 are bounded by lateral surfaces 11 and 12, which are formed on the boundary walls 6 and 7 and which are at least sectionally adapted to the shape of the rolling element 4.
Rolling elements 4, which are located in a receiving pocket 9 of the cage segment 5, and rolling elements 4′, which are free from a cage segment 5, alternate here in the circumferential direction U. However, for their guiding a running surface 13 is provided on both sides of the cage segment 5.
In
Also recorded is the clearance x/z (with z as the number of rolling elements), assumed uniformly distributed over the circumference U on the pitch circle 10, which clearance x/z is present in the circumferential direction U between the rolling element 4′ and the running surface 13. The clearance x thus represents the total clearance of the rolling-element series summed over the circumference.
The relationships specified above apply for the size of the clearance c in a receiving pocket 9 and the ratio of this clearance c to the total clearance x.
1 Rolling-element bearing
2 Inner ring
3 Outer ring
4 Rolling element
4′ Rolling element
5 Cage segment
6 Boundary wall
7 Boundary wall
8 Boundary wall
9 Receiving pocket
10 Pitch circle
11 Lateral surface
12 Lateral surface
13 Running surface
Dw Diameter of the rolling element
c Clearance
x (Total) clearance
z Number of rolling elements
K Constant
U Circumferential direction
r Radial direction
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2013 206 347.4 | Apr 2013 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2014/057409 | 4/11/2014 | WO | 00 |
