Roller bearing with lubrication channel

Abstract

A roller bearing having a first race, a second race, the races being coaxial and in relative rotation about a central axis, and a row of rollers. The first race including a circumferential groove disposed on a surface radially opposite the first bearing track, and at least one hole traversing the race substantially radially and opening out close to the first bearing track. The first race also provides a secondary groove extending in a substantially radial direction and connecting the circumferential groove to the hole. As such, it is possible for lubricant to be transferred from the circumferential groove to the hole via the secondary groove.

Claims

1. A roller bearing comprising: a first race provided with a first bearing track, a second race provided with a second bearing track, the first and second races being coaxial and in relative rotation about a central axis, a row of rollers housed radially between the first and second bearing tracks, the first race also having a circumferential groove provided on a surface radially opposite to the first bearing track, wherein the circumferential groove is centered axially relative to the row of rollers, at least one hole traversing the first race substantially radially and opening proximate to the first bearing track, and the first race also provides a secondary groove which, when viewed in a cross-section in a plane which includes the central axis, extends along the surface radially opposite the first bearing race in a direction which is oblique relative to the central axis, the secondary groove connecting the circumferential groove to the at least one hole such that lubricant can be transferred from the circumferential groove to the at least one hole via the secondary groove, wherein the first race, when viewed in cross-section, also comprises two edge protuberances extending radially on opposite axial sides of the first race such that the two edge protuberances form axial stops for the rollers.

2. The roller bearing of claim 1, wherein, on a side of the first bearing track of the first race, the at least one hole opens in a connecting fillet formed between the first bearing track and one of the two edge protuberances.

3. The roller bearing of claim 2, wherein the connecting fillet forms an annular groove.

4. The roller bearing of claim 1, wherein the at least one hole comprises two series of holes distributed circumferentially along the first race each opening between the first bearing track and one of the two edge protuberances.

5. The roller bearing of claim 4, wherein the holes of the two series of holes are aligned axially in pairs.

6. The roller bearing of claim 4, wherein the holes of the two series of holes are circumferentially offset.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) The present invention will be better understood from studying the detailed description of embodiments given by way of entirely non-limiting example and illustrated by the appended drawings:

(2) FIG. 1 is a view in axial section of a bearing in accordance with a first embodiment of the invention;

(3) FIG. 2 is a view in axial section of a bearing in accordance with a second embodiment of the invention;

(4) FIG. 3 is a view in axial section of a bearing in accordance with a third embodiment of the invention; and

(5) FIG. 4 is a view in axial section of a bearing in accordance with a first embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

(6) A bearing 1 with central axis X1 comprises an outer race 2, an inner race 3, a row of rollers 4 and two leak tight seals 5 and 6.

(7) The races 2, 3 are coaxial and in relative rotation about the central axis X1 in normal operating mode.

(8) The outer race 2 comprises a cylindrical exterior surface 21, a bore 22 in which is provided a bearing track 23 for the rollers 4 and grooves in which the leak tight seals 5, 6 are fitted, the seals forming static leak tightness with the turning outer race 2.

(9) The inner race 3 comprises an exterior surface 31 in which is provided a bearing track 32 for the rollers 4. The exterior surface 31 is also provided with two edges 33, 34 extending radially in the direction of the outer race 2, the edges 33, 34 axially framing the bearing track 32 such as to form axial stops for the rollers 4. Connecting fillets 35, 36 are formed at the axial ends of the bearing track 32 and the edges 33, 34, respectively. These fillets 35, 36 each have the form of an annular groove.

(10) The leak tight seals 5 and 6 each comprise leak tight lips in sliding contact with a portion of the edges 33 and 34, respectively, the seals forming a dynamic leak tightness with the non-turning inner race 3.

(11) The inner race 3 also comprises an essentially cylindrical through-bore 37. For example, a pin or support may be inserted into the bore 37.

(12) Alternatively, the inner race 3 may be a turning race and the outer race 2 a non-turning race, or else both races may be able to turn relative to one another.

(13) The bearing track 32 of the inner race 3, the bearing track 23 of the outer race 2, the edges 33, 34 of the inner race 3, and the seals 5, 6 define a bearing chamber 7 in which the rollers 4 move, between the races 2, 3. The bearing chamber 7 is filled with lubricant, for example grease or oil, in order to reduce friction between the contact surfaces of the moving elementsthe rollers 4, in this caseand the bearing tracks 23, 32.

(14) The inner race 3 comprises mean 8 for transferring lubricant to the bearing chamber 7.

(15) The means 8 comprise a circumferential groove 81 formed in the bore 37 of the inner race 3. This circumferential groove 81 is provided on a surface 37 radially opposite the bearing track 32. As illustrated in FIG. 1, the circumferential groove 81 is centred axially relative to the row of rollers 4.

(16) The means 8 also comprise a first series 82 of through-holes and a second series 83 of through-holes. Each of the holes 82, 83 traverses the inner race substantially radially, from the bore 37, and opens out into a fillet 35, 36, respectively, close to the bearing track 32.

(17) In the embodiment illustrated in FIG. 1, the holes 82, 83 of the two series are offset relative to one another in the circumferential direction.

(18) According to the invention, the means 8 also comprise a first series 84 of secondary grooves, each of these secondary grooves extending in a radial direction and connecting the circumferential groove 81 to one of the holes in the first series 82. The means 8 also comprise a second series 85 of secondary grooves, each of these secondary grooves extending in a radial direction and connecting the circumferential groove 81 to one of the holes in the second series 83.

(19) In the embodiment illustrated in FIG. 1, the secondary grooves 84, 85 each extend strictly in the axial direction, the grooves in the first and second series thus being offset relative to one another in the circumferential direction.

(20) Lubricant may thus be transferred from the circumferential groove 81 to each of the holes 82, 83 opening out in the bearing chamber 7 via the secondary grooves 84, 85.

(21) A second embodiment of the roller bearing 1 is illustrated in FIG. 2 and differs from the first embodiment in that the inner race 3 comprises lubricant-transfer means 10 with two series 102, 103 of through-holes aligned axially in pairs.

(22) The means 10 comprise a circumferential groove 101 formed in the bore 37 of the inner race 3. This circumferential groove 101 is centred axially relative to the row of rollers 4. The means 10 also comprise a first series 102 of through-holes and a second series 103 of through-holes. Each of the holes 102, 103 traverses the inner race substantially radially, from the bore 37, and opens out into a fillet 35, 36, respectively, close to the bearing track 32.

(23) In the embodiment illustrated in FIG. 2, the holes 102, 103 of the two series are aligned axially in pairs.

(24) According to the invention, the means 10 also comprise a first series 104 of secondary grooves, each of these secondary grooves extending in a radial direction and connecting the circumferential groove 101 to one of the holes in the first series 102. The means 10 also comprise a second series 105 of secondary grooves, each of these secondary grooves extending in a radial direction and connecting the circumferential groove 101 to one of the holes in the second series 103.

(25) In the embodiment illustrated in FIG. 2, the secondary grooves 104, 105 each extend strictly in the axial direction, the grooves in the first and second series thus being aligned in pairs in the axial direction.

(26) A third embodiment of the roller bearing 1 is illustrated in FIG. 2 and differs from the first embodiment in that the inner race 3 comprises lubricant-transfer means 20 with two series 204, 205 of oblique secondary grooves.

(27) The means 20 comprise a circumferential groove 201 formed in the bore 37 of the inner race 3. This circumferential groove 201 is centred axially relative to the row of rollers 4. The means 20 also comprise two series 202, 203 of through-holes similar to those described in FIG. 1. In the embodiment illustrated in FIG. 3, the holes 202, 203 of the two series are offset relative to one another in the circumferential direction.

(28) In the embodiment illustrated in FIG. 3, the means 20 comprise two series 204, 205 of secondary grooves. Each of these secondary grooves 204, 205 extend obliquely in an intersecting plane in axial section such as to connect the circumferential groove 201 to the holes 202, 203 that are offset circumferentially.

(29) In a fourth embodiment illustrated in FIG. 4, the inner race 3 comprises lubricant-transfer means 30 with two series 302, 303 of holes aligned axially in pairs and two series of secondary grooves extending obliquely in an intersecting plane in axial section such as to connect the holes 202, 203 to a circumferential groove 301 centred axially relative to the rollers 4.

(30) Furthermore, all or only some of the technical features of the various embodiments may be combined with one another. The bearing may thus be adapted in terms of costs, performance and simplicity of implementation.