EP3047166A1

EP3047166A1 - Anti-friction bearing

Info

Publication number: EP3047166A1
Application number: EP14755971.0A
Authority: EP
Inventors: Thomas Drescher; Horst Brehm; Martin Kram
Original assignee: Schaeffler Technologies AG and Co KG
Current assignee: Schaeffler Technologies AG and Co KG
Priority date: 2013-09-17
Filing date: 2014-07-25
Publication date: 2016-07-27
Also published as: US9670955B2; CN105518322A; DE102013218620A1; CN105518322B; US20160208852A1; WO2015039656A1

Abstract

An anti-friction bearing comprises a mechanical bearing (2) transmitting mechanical loads and a potential equalization bearing (3) each rolling element (7) of which has two identical side surfaces. The potential equalization bearing is particularly a ball roller bearing or a cylindrical roller bearing. The potential equalization bearing (3) preferably comprises resilient rolling elements (7) in the form of hollow rollers.

Description

Name of the invention

Rolling bearing description

Field of the invention

The invention relates to a roller bearing, which comprises a main bearing provided for the transmission of mechanical loads and an electrically conductive potential equalization bearing.

Background of the Invention A roller bearing of the type mentioned above is known for example from DE 198 05 566 B4. This is a rolling bearing for rail vehicles, which is constructed of a load-transmitting single or multi-row bearings and a device arranged next to it for transmitting electrical power. The device provided for transmitting current is in the case of DE 198 05 566 B4 designed as a skewed roller bearing, in particular tapered roller bearings.

As current-conducting elements in rolling bearings and seals can be used, which have a conductive insert. By way of example, reference is made in this context to DE 10 2007 052 104 A1, to DE 199 83 988 B4, and to DE 198 24 022 A1.

OBJECT OF THE INVENTION It is the object of the invention to further develop an equipotential bonding device of a roller bearing with respect to the cited prior art, in particular with regard to a compact construction with long-term durability while maintaining the same electrical properties. Description of the invention

This object is achieved by a rolling bearing with the features of claim 1. This rolling bearing comprises two bearings having a common axis of rotation, namely a main bearing and an equipotential bearing. The main bearing can be designed as any rolling bearing of known design, for example as a single or multi-row ball bearing, cylindrical roller bearings or tapered roller bearings.

The equipotential bonding according to the invention is a rolling bearing in which each rolling element has two equal side surfaces. Such a rolling bearing may be formed for example as a cylindrical roller bearing, needle roller bearings, roller bearings or ball roller bearings. Ball roller bearings are known, for example, from DE 10 2008 060 957 A1 and from WO 2010/133462 A1. Ball rollers are rolling elements, which each have two symmetrically flattened from a spherical base shape, arranged parallel to each other side surfaces. Due to the lateral flattening of the rolling elements, a ball roller bearing is narrower than a ball bearing whose rolling elements have the same diameter. The surface areas of the rolling elements and raceways, which are available for power transmission, however, are not reduced in a ball roller bearing compared to a ball bearing with rolling elements of the same diameter. The bearing used as an equipotential bearing of the roller bearing, in particular Kugelrol- lenlager, is preferably designed as a single-row radial bearing.

In different embodiments of the rolling bearing, the main bearing can be either electrically isolated from the potential equalization or electrically connected to the equipotential bonding. Here, in the former case, the bearing rings of the equipotential bonding against the bearing rings of the main bearing electrically isolated, while in the latter case, at least one bearing ring of the equipotential bonding bearing is electrically connected to a bearing rings of the main storage. A Electrical isolation is chosen, for example, in cases where any current flow through the main bearing must be avoided.

In order to enable at any time a low-resistance current flow through the potential equalization bearing, this is preferably biased. This can be achieved in a simple and reliable manner by the rolling elements, namely rollers, in particular ball rollers or cylindrical rollers, of the equipotential bearing are designed as hollow rollers. This design has the advantage that a large radial clearance of the main bearing can be compensated by means of the potential equalization bearing, whereby only a moderate mechanical load of the equipotential bonding bearing always occurs.

The contacts of the rolling elements of the equipotential bonding bearing on the bearing rings can be designed in the case of ball rolling as rolling elements in principle as in a deep groove ball bearing. According to an advantageous development, working with ball rollers as current-transmitting elements equipotential bearing is designed as a four-point bearing. In this case contacted a ball roller of the equipotential bearing whose bearing rings at two points. A designed as a four-point bearing ball roller bearing is known for example from DE 10 2006 035 180 A1. This is a full complement bearing, ie a bearing without the rolling element cage leading.

The rolling elements of the equipotential bonding are preferably made of a self-lubricating material, regardless of their geometry. Particularly suitable aluminum-zinc alloys have been found. The use of aluminum-zinc alloys for rolling bearing components is known in principle from DE 690 6209 U, for example.

If the equipotential bonding bearing is operated with a lubricant, an electrically conductive lubricant can be used in all designs. In this context, reference is made by way of example to EP 0 479 904 B1 and to DE 10 2010 013 517 B4 and EP 1 780 01 1 B1. While electric current flowing through the roller bearing flows exclusively or largely through the equipotential bonding bearing, forces are transmitted for the most part or almost exclusively via the main bearing. In the case of a common outer ring of the main bearing and the equipotential bearing, the outer diameter of this bearing ring in the region of the potential equalization bearing is preferably somewhat reduced in order to avoid an unintentional transmission of power at this point. In an analogous design, a common inner ring of main bearing and equipotential bonding in the section in which the rolling elements of the potential equalization bearing are arranged, preferably slightly widened.

Several embodiments of the invention will be explained in more detail with reference to a drawing. Herein show:

Short description of the drawing

1 shows a first embodiment of a main bearing and a potential equalization bearing having rolling bearing in plan view,

2 shows the roller bearing according to Fig. 1 in a sectional view,

Fig. 3 to 6 sectional views of other rolling bearings with equipotential bonding.

Detailed description of the drawing

Corresponding or basically equivalent parts are indicated in all figures with the same reference numerals.

A roller bearing, designated overall by the reference numeral 1 in FIGS. 1 and 2, comprises a main bearing 2, namely a ball bearing, as well as an equipotential bonding bearing 3, namely a ball roller bearing. The Rolling bearing 1 is formed overall as a radial bearing; the axis of rotation is denoted by R.

In the exemplary embodiment according to FIGS. 1 and 2, the roller bearing 1 has a common inner ring 4 and a common outer ring 5. Between the bearing rings 4,5 roll the rolling elements 6, namely balls, the main bearing 2, and the rolling elements 7, namely ball rollers, the equipotential bonding 3 from. The rolling elements 6 of the main bearing 2 can be guided in a cage. Likewise, the main bearing 2 may be formed as a full complement bearing.

In the case illustrated in FIGS. 1 and 2, the number of rolling elements 6 of the main bearing 2 is several times higher than the number of rolling elements 7 of the equipotential bonding bearing 3. Deviating from this, the same number of rolling elements 6 can be used in the main bearing 2 and in the equipotential bonding bearing 3 7 be present. It is also possible that the number of rolling elements 7 of the equipotential bonding 3 is higher than the number of rolling elements 6 of the main bearing 2. As is apparent from Figure 1, the equipotential bonding 3 only three ball rollers 7 as rolling elements. Each of these ball rollers 7 is designed as a hollow roller and elastically yielding to a considerable extent. In contrast to the main bearing 2, which has a play in the radial direction, the equipotential bonding 3 is biased. While the balls 6 of the main bearing 2 made of conventional bearing steel, such as 100Cr6, are made, the rolling elements 7 of the equipotential bonding 3 made of an aluminum-zinc alloy. Alternatively, the rolling elements 7 may be made of steel with an aluminum-zinc coating, for example. The inner ring 4 of the rolling bearing 1 is provided for placement on a shaft, the outer ring 5 for installation in a housing. The shaft, not shown, as well as the housing, also not shown, have for this purpose a cylindrical or slightly conical lateral surface or bore. In order to avoid a significant force transmission via the rolling elements 7 of the equipotential bonding 3, as shown in Figure 2, the inner diameter of the inner ring 4 in the region of the equipotential bonding 3 compared to the portion in which the main bearing 2 is slightly widened. Similarly, the outer diameter of the outer ring 5 in the region of the equipotential bonding 3 with respect to the main bearing 2 is slightly reduced. A shoulder formed in the jacket surface of the outer ring 5 by the taper in the region of the equipotential bonding bearing 3 is marked A in FIG.

In the embodiments according to Figures 3 to 6, the inner ring 4 is composed of an inner main bearing ring 8 and an inner auxiliary bearing ring 9, while the outer ring 5 is composed of an outer main bearing ring 10 and an outer auxiliary bearing ring 1 1. In the exemplary embodiments according to FIGS. 3 and 4, the connection between the main bearing rings 8, 10 and the auxiliary bearing rings 9, 1 is produced by a screw connection 12 in the axial or radial direction. The rolling elements 6 of the main bearing 2 are not shown in both cases. This may be, for example, cylindrical rollers.

In the embodiment of Figure 5, a press fit between the inner main bearing ring 8 and the inner auxiliary bearing ring 9 and a further interference fit between the outer main bearing ring 10 and the outer auxiliary bearing ring 1 1 is made. In each of the exemplary embodiments according to FIGS. 3 to 5, the main bearing ring 8, 10 is electrically conductively connected to the adjacent auxiliary bearing ring 9, 1.

In contrast, in the exemplary embodiment according to FIG. 6, each main bearing ring 8, 10 is electrically insulated from the adjacent auxiliary bearing ring 9, 1, as indicated in each case by a solid solid line. In the exemplary embodiment according to FIG. 6, contact elements 13 made of electrically conductive materials such as gold, silver are located on the auxiliary bearing rings 9, 11 or Kuper. A current flow through the main bearing 2 is completely excluded in the embodiment of Figure 6.

LIST OF REFERENCE NUMBERS

1 rolling bearing

2 main storage

3 equipotential bonding bearings

4 inner ring

5 outer ring

6 rolling elements, ball

7 rolling elements, ball roller

8 inner main bearing ring

9 inner auxiliary bearing ring

10 outer main bearing ring

1 1 outer auxiliary bearing ring

12 screw connection

13 contacting element

A paragraph

R rotation axis

Claims

Patent claims

Rolling bearing, with a load-transmitting main bearing (2) and a potential equalization bearing (3), characterized in that a rolling bearing is provided as a potential equalization bearing (3), the rolling bodies (7) of which each have two identical side surfaces.

Rolling bearing according to claim 1, characterized in that the potential equalization bearing (3) is designed as a ball roller bearing.

Rolling bearing according to claim 2, characterized in that the potential equalization bearing (3) is designed as a four-point bearing.

Rolling bearing according to claim 1, characterized in that the potential equalization bearing (3) is designed as a cylindrical roller bearing.

Rolling bearing according to one of claims 1 to 4, characterized in that the potential equalization bearing (3) is prestressed.

Rolling bearing according to claim 5, characterized in that the rolling bodies (7) of the potential equalization bearing (3) are designed as hollow rollers.

Rolling bearing according to one of claims 1 to 6, characterized in that the rolling bodies (7) of the potential equalization bearing (3) comprise a self-lubricating material.

Rolling bearing according to claim 7, characterized in that the rolling bodies (7) of the potential equalization bearing (3) are made of an Al-Zn alloy.

9. Rolling bearing according to one of claims 1 to 8, characterized in that the main bearing (2) and the potential equalization bearing (3) have at least one common bearing ring (4,5).

10. Rolling bearing according to claim 9, characterized in that a wall of a bearing ring (4,5,9,1 1) of the potential equalization bearing (3) facing away from the rolling element raceway is opposite a wall of a bearing ring (4,5,8,10) of the main bearing (2) is discontinued.