FR2808056A1 - Ball bearing, for mounting car wheels, has inner ring held in place by flange formed on hub, strip of hub material being cast into gap between outer edge of ring and hub after forming flange - Google Patents

Abstract

The ball bearing has two sets of balls (3, 4) which can move in a raceway (51) inside an inner ring (5). This is held in place on a hub (2) by a flange (27) formed by shaping its end (28) after the ring is in position and which pushes the ring against a shoulder (26) on the hub. A discontinuous curve (7) links the outer edge of the ring to its base and a strip of the material of the hub is cast into the gap between the discontinuity and the hub itself, after forming the flange. An Independent claim is also included for the inner ring of the ball bearing.

Description

The present invention relates to rolling bearings, especially rolling bearings' ball bearings for motor vehicle wheels, which comprise at least one bearing inner race reported on shaft supported by this bearing, in particular on a hub of such a wheel. The invention relates more particularly to rolling bearings comprising two rows of balls, or even other rolling bodies such as for example conical rollers. Subsequently, to simplify the expression, we will use essentially

    the <SEP> term <SEP> "<SEP> ball <SEP>", <SEP> being <SEP> heard <SEP> unless otherwise indicated, this shall be understood to mean any rolling body which can be used in two-row bearings of rolling bodies. inner ring, or each inner ring, then carries an inner raceway for one of the two rows of balls.

In known manner, in particular by the document EP-0475792, such bearings comprise a collar, formed by plastic deformation on the hub on which is mounted said ring after assembly of the rings and rows of balls of the bearing. This collar, after it is formed, has a retention face, applied in pressure on an outer face of the ring, so as to immobilize axially said ring, in axial thrust against a shoulder of a bearing of the hub constituting a second inner raceway for the second row of rolling elements. The second rolling track can also be formed on a second inner ring against which the first ring is applied axially, the second ring then being itself in support.

axial <SEP> against <SEP> a <SEP> shoulder <SEP> of the <SEP> hub.
<tb> A <SEP> set <SEP> of <SEP> rolling <SEP> of <SEP> This <SEP> type <SEP> is <SEP> so
<tb> realized <SEP> with <SEP> the <SEP> game <SEP> axial, <SEP> or <SEP> the <SEP> pre-charge,
<tb> necessary <SEP> to <SEP> its <SEP> later <SEP> application. <SEP> One <SEP> times <SEP> the
<tb> collar <SEP> formed, <SEP> the set <SEP> is <SEP> ready <SEP> to <SEP> the job,
<tb> since <SEP> la, <SEP> or <SEP> the <SEP> two, <SEP> ring (s) <SEP> inner <SEP>) <SEP> is
<tb> (are <SEP> axially <SEP> maintained <SEP> (s) <SEP> by <SEP> the <SEP> flange, but the rings reported on the hub are however not completely immobilized in rotation, which can leading to a parasitic movement of rotation of a ring relative to the hub, called the crawling movement, resulting from the combination of the rotational torques and the effects of cyclical variations, more or less regular, bearing load conditions.

This movement of crawling can be very annoying and even harmful, because it can lead to wear and creating a game, which will give more freedom of rotation, further amplifying the game, and so on. Such wear can occur even in the case where a localized heat treatment is performed on the fitting of the rings. It is furthermore known that an area subject to such a phenomenon, called "fretting", or an area close to it, is often the source of the appearance of cracks, and therefore presents an increased risk of rupture, which does not is of course not acceptable for a piece of security, such as a wheel hub in particular. It will be noted that such parasitic movement can occur even in the case of a relatively tight fit of the ring on the hub, and moreover an excessively tight fit of the ring on the hub can result in a deformation of the ring. and a modification of the geometry of the raceway which is detrimental to the durability of the bearing. To reduce the risk of crawling, it is also possible to consider increasing the length of the fitting, so as to compensate for a certain reduction in tightening by an increase in the area in contact between the shaft and the ring, and therefore the friction. But this then leads to an increase in congestion. To limit these changes in geometry, one can of course try to increase section of the inner ring so that it tolerates a closer tight fit without increasing the deformations, but it is then to the detriment of the mass of the entire rolling.

For <SEP> to avoid <SEP><SEP> problems <SEP> relative <SEP> slip
<tb> between <SEP> the <SEP> hub <SEP> and <SEP> a <SEP><SEP> part reported <SEP> carrying <SEP> a
<tb><SEP> path of <SEP><SEP> rolling within <SEP> of a <SEP> rolling <SEP> to <SEP> two
<tb> rows <SEP> of <SEP> beads, <SEP> it <SEP> a <SEP> already <SEP>'<SEP>'<SEP> proposed <SEP> in <SEP>
<tb> document <SEP> US-4986607 <SEP> of <SEP> perform <SEP> on <SEP> a <SEP> end
<tb> axial <SEP> chamfered <SEP> of <SEP> the <SEP> bore of the <SEP> says <SEP> hub, <SEP> a
<tb> set <SEP> of <SEP> teeth. <SEP> After <SEP> setting <SEP> place <SEP> of the <SEP> hub <SEP> on the insert, the metal of the end of the insert is plastically deformed so as to be folded over the conical part chamfer and to penetrate at least partially into the teeth. This is possible only because, in the document considered, to obtain the desired effects, the hub is large, and the chamfered and toothed area is located far from the raceway, on a solid part of the hub, suitable to withstand the high stresses generated during the discharge of the end of the insert without risk of deformation of said raceway. In addition to the design limitations that imposes for the assembly of bearing assemblies, this system has the disadvantage of requiring complicated machining, and therefore expensive, in particular to make the teeth on the conical seat of the chamfer, and to require, moreover, for a better efficiency, to be completed a plurality of centering shoulders between the hub and the insert. To overcome these drawbacks, US-5822860 proposes only to make the chamfer at the edge of the bore of the insert in a mounting similar to that of the previous document, or a simple bearing ring, but against make this chamfer so that it is off-axis with respect to the axis of rotation of the bearing. In this way, the depth of the chamfer varies on the periphery of the bore, presenting a diametrically opposite minimum and maximum. As in the previous case, a retention flange is formed by a plastic deformation of the end of the hub, folded over said chamfer. The insert or the bearing ring is then axially retained by the flange, and further insensitive to any crawling movement relative to the hub, since due to the asymmetry of the chamfer, the collar is itself asymmetrical, preventing the ring to turn. But this solution has the disadvantage of also requiring delicate machining because eccentric relative to the bore of the insert or ring. In addition, this results in a reduction of the bearing surface between the flange and the front face of the ring, which can cause a less good axial retention of the ring insert. Moreover, this support surface varying angularly, this creates an asymmetry of the axial forces at the contact level of the flange and the face of the reported ring. From these dissymmetries, it can result in forces that are not uniformly distributed circumferentially, which can lead to a parallelism of the runways. The document FR-2605557 shows a bearing mounting system using a kind of toothing arranged in particular on a front face of a bearing ring, or a supplementary insert reported, to ensure in particular a interconnection between this piece or a ring attached to the hub and a rotating drive part, such as for example a cup of a homokinetic transmission of conventional type. It is also provided that a similar link by interconnection can be provided between said ring or intermediate thrust member and the hub. In the systems described in the aforementioned documents, there is always the problem of preventing excessive forces exerted by the retaining flange on the inner ring from damaging said ring, or at least deforming it. This is what leads to the matting of the hub as far as possible from the raceway of the balls, on a portion as massive as possible, able to withstand significant forces without deformation. In the aforementioned EP-0475792, a solution is provided using a ring whose most solid part, between the raceway and the outermost face of the ring, is long enough for the matting of the collar to end of this massive part is not likely to deform the raceway. Another solution shown in this document is to support the bearing ring by the hub, and to use a complementary annular piece, placed inside a bore of the hub, and provided at one end with a preformed flange. to axially bear on the bearing ring, and the other axial end, said annular piece being then matted on the hub, at a distance from the bearing which can be important. But this solution requires the use of an additional piece, burdening the cost and the complexity of the assembly. The documents EP-0854303 and JP-10.95203 also show bearing assemblies using a flange obtained by plastic deformation to maintain a bearing inner race, and moreover impose a condition on a minimum axial distance to be respected between the rolling path and the bearing surface of the ring, so as to subtract the rolling area to the detrimental influence of the forces and deformations caused by matting of the collar, which leads to a need to use sufficiently long rings at the expense of weight and congestion, and creating additional dimensional constraints for the realization of bearing assemblies. The present invention aims to solve the problems mentioned above. It is particularly intended to provide a rolling assembly two rows of rolling bodies that allow use rings having general dimensional characteristics capable of responding to mechanical stresses of use of the bearing either in terms of mechanical strength or geometry, and possibly to the constraints of sealing, but without creating additional constraints on the only needs rigid retention of the ring on its shaft or hub. With these objectives in view, the invention relates to a rolling bearing of the type comprising at least one row of rolling bodies moving on a raceway of an inner ring which is fitted on a hub and held axially by a collar obtained by plastic deformation

a <SEP> part <SEP> device <SEP> of the <SEP> hub <SEP> after <SEP> than <SEP> the <SEP> ring
<tb> y <SEP> a <SEP> is <SEP> mounted, <SEP><SEP> is a <SEP> collar that has <SEP> a <SEP><SEP> face
<tb> retention, <SEP> applied <SEP> in <SEP> pressure <SEP> on <SEP> a <SEP> face
<tb> front <SEP> external <SEP> of <SEP> the <SEP> ring, <SEP> of <SEP><SEP> way to
<tb> immobilize <SEP> axially <SEP> the <SEP> called <SEP> ring, <SEP> in <SEP> thrust
<tb> axial <SEP> versus <SEP> a <SEP> element <SEP> of <SEP> stop <SEP> axial <SEP> linked <SEP> to
<tb> hub, <SEP>, or <SEP> vs <SEP> a <SEP> face <SEP> of a <SEP> second <SEP> ring
<tb> inside <SEP> the <SEP> case <SEP> where appropriate.

According to the <SEP> invention, <SEP> the <SEP> step <SEP> to <SEP> rolling <SEP> is
<tb> chars <SEP> in <SEP> this <SEP> that <SEP><SEP> ring <SEP> inner <SEP> includes <SEP> in
<tb> minus <SEP> a <SEP> discontinuity <SEP> of <SEP> form <SEP> in <SEP> a <SEP> zone
<tb> intermediate <SEP> connecting <SEP> the <SEP> so-called <SEP> face <SEP> front <SEP> external <SEP> to
<tb> the <SEP> surface <SEP> of <SEP> the bore <SEP> of <SEP> the <SEP> ring, <SEP> and <SEP> in <SEP> this <SEP> than <SEP> a
<tb> bump <SEP> of <SEP> material <SEP> constitutive <SEP> of <SEP> hub <SEP> is <SEP> inserted
<tb> to <SEP> less <SEP> partially <SEP> in <SEP> the <SEP> discontinuity,
<tb> bead <SEP> being <SEP> formed, <SEP> at <SEP> level <SEP> of <SEP> the <SEP> junction <SEP> between
<tb> the <SEP><SEP> cylindrical surface <SEP> of the <SEP> hub <SEP> and <SEP> the <SEP> face
<tb> retention <SEP> of <SEP> the <SEP> flange, <SEP> by <SEP> creep <SEP> of <SEP> says
<tb> material <SEP> in <SEP> the <SEP> discontinuity <SEP> when <SEP> of <SEP> obtaining <SEP> of
<tb> the <SEP> flange <SEP> by <SEP> deformation <SEP> plastic. The discontinuity or discontinuities according to the invention, preferably made in the form of notches which each extend in a radial plane and whose bottom extends obliquely with respect to the axis of rotation, make it possible to immobilize rotation. of the inner ring relative to the hub, since the bead formed during the realization of the collar fills, at least partially, the notch and opposes its resistance to shear and matting to any torque tending to rotate the ring relative at the hub. When several discontinuities are formed, they are distributed circumferentially on said intermediate zone, so that the forces exerted by the collar, both axially and radially as a result of the localized swelling of the collar during its forming, are uniformly distributed over the around the ring. The number of notches or discontinuities is determined so as to oppose a section of shear bead sufficiently large to overcome the creep torque generated by the loads applied to the bearing in all circumstances of use, and to avoid the matting that could result from shocks during use, caused by acceleration and braking of the vehicle or inversions of the direction of rotation.

Preferentially <SEP> also, <SEP> the <SEP> said <SEP> zone
<tb> intermediate <SEP> is <SEP> a <SEP> zone <SEP> with <SEP> at <SEP> less than <SEP>
<tb> toroidal <SEP> form, <SEP> of which <SEP><SEP> section <SEP> is <SEP> a <SEP> rounded
<tb> connecting <SEP> the <SEP> so-called <SEP> face <SEP> front <SEP> external <SEP> the <SEP> surface <SEP> of
<tb> bore <SEP> of <SEP> the <SEP> ring, <SEP> and <SEP> the <SEP> discontinuity <SEP> is
<tb> limited <SEP> to <SEP> the <SEP> so-called <SEP> zone, <SEP> without <SEP> encroach <SEP> on <SEP> the <SEP> face
<tb> frontal <SEP> nor <SEP> on <SEP> the <SEP> surface <SEP> cylindrical <SEP> of <SEP> the bore.

Thus, <SEP> the <SEP> discontinuity <SEP> or <SEP> notch <SEP> ne <SEP> changes
<tb> that <SEP> the <SEP><SEP> area of <SEP><SEP> connection between <SEP><SEP> surface
<tb> cylindrical <SEP> of <SEP> the bore <SEP> of <SEP> the <SEP> ring <SEP> inner <SEP> and <SEP> la
<tb> surface <SEP> front <SEP> of <SEP> the <SEP> so-called <SEP> ring, <SEP> but <SEP> ne <SEP> changes <SEP> neither
<tb> the <SEP> called <SEP> surface <SEP> cylindrical, <SEP> nor <SEP> said <SEP> face
<tb> frontal. <SEP> It <SEP> in <SEP> results <SEP> that <SEP> the <SEP> scope <SEP> of <SEP> the <SEP> ring <SEP> on
<tb> the <SEP> hub, <SEP> and <SEP> including <SEP> the <SEP> area of <SEP> the <SEP> surface <SEP> of
<tb> contact <SEP> between <SEP> ring <SEP> and <SEP> hub <SEP> is <SEP> not <SEP> influenced <SEP> by
<tb> the <SEP> presence <SEP> of <SEP> the <SEP> or <SEP> of discontinuous <SEP>. <SEP> It <SEP> in <SEP> is <SEP> likewise for the frontal surface of the ring on which the retention face of the flange applies, the area of the contact surface not being not more influenced by the presence of said discontinuities.

According to a particular embodiment of the invention, the inner ring comprises an axial recess between the outer end face and the toroidal-shaped zone. This recess ensures that the notch or not do not open on the front face of the ring.

According to another arrangement, the inner ring comprises, on the side of the outer end face, an annular portion of greater diameter than the bore to which it is connected by a shoulder. This shoulder allows, after the collar is formed as explained above, and being further expanded in said annular portion, to provide additional safety by forming an additional stop retaining the bearing ring in case of accidental breakage of the collar. In this arrangement, the notch may open into said annular portion, which does not provide a bearing function of the ring on the hub.

Compared to the solutions known in the prior art previously mentioned, and in contrast to them, the invention generally makes it possible to avoid crawling phenomena reliably without the need to increase the axial length of the ring. Indeed, as indicated above, the notches according to the invention can be made on bearing rings meeting the specifications imposed from the point of view of the resistance to forces, the internal geometry of the bearing and generally speaking. the size, without any need to modify the sizing of the rings. In other words, it is possible thanks to the invention to keep bearing assemblies identical to those previously used, without modifying the overall size of the bearing, but with a great improvement from the point of view of the reliability of the assembly of rolling, avoiding the problems of crawling and "fretting" previously mentioned.

Also, <SEP> since <SEP> the <SEP> cooperation <SEP> of
<tb> beads <SEP> and <SEP> of <SEP> notches <SEP> according to <SEP> the invention <SEP> allows
<tb> to ensure <SEP> the <SEP> blocking <SEP> in <SEP> rotation <SEP> of <SEP> the <SEP> ring
<tb> inner, <SEP> 1a <SEP> pressure <SEP> axial <SEP> to <SEP> exert <SEP> by <SEP> la
<tb> flange <SEP> can <SEP> be <SEP> reduced, <SEP> so <SEP><SEP> efforts <SEP> when
<tb> of <SEP> forming <SEP> of <SEP><SEP> so-called <SEP> flange <SEP> can <SEP> also
<tb> be <SEP> reduced, <SEP> this <SEP> which <SEP> reduces <SEP> by <SEP> the <SEP> risk <SEP> of
<tb> deformation <SEP> of <SEP> the <SEP> ring <SEP> by <SEP> swelling <SEP> of the <SEP> hub <SEP> during
<tb> of <SEP> forming <SEP> of <SEP> the <SEP> flange. <SEP> Also,
<tb><SEP><SEP> mount <SEP> interference between <SEP><SEP> ring and <SEP> hub <SEP> can
<tb> be <SEP> decreased <SEP> to <SEP> relieve <SEP> the <SEP> ring.

Finally, <SEP> the <SEP> presence <SEP> of <SEP> notches <SEP> according to
<tb> the invention <SEP> allows <SEP> of <SEP> to reduce <SEP> the <SEP> axial <SEP> constraints
<tb> and <SEP> radial <SEP> on <SEP> the <SEP> ring <SEP> of <SEP> bearing <SEP> and <SEP> on <SEP> on
<tb> hub, <SEP> allowing <SEP> thus <SEP> the <SEP> use of <SEP> say
<tb> notches <SEP> on <SEP><SEP> rings <SEP> of <SEP> bearing <SEP> practically
<tb> any, <SEP> without <SEP> that it <SEP> or <SEP> required <SEP> from <SEP> change <SEP> their

geometry <SEP> nor <SEP> that <SEP> of <SEP> the <SEP> collar, <SEP> nor <SEP> still <SEP> the
<tb> process <SEP> of <SEP> forming <SEP> of <SEP> the <SEP> flange. To ensure the best possible shear strength of the beads, the width of the notch may be greater than its maximum depth. The dimensions of the notches and the number of notches can be determined by calculating the strength of the materials, taking into account the maximum lengths and depths of the notches in order to satisfy the geometric constraints of non-encroachment on the functional surfaces of the ring, mechanical characteristics of the material (resistance to shear and matting), and the torque to oppose the rotation of the ring relative to the hub.

From <SEP> plus, <SEP> for <SEP> avoid <SEP> than <SEP> the <SEP> notch or <SEP> a
<tb> source <SEP> of <SEP> cracking, <SEP> its <SEP> section <SEP> is <SEP> of <SEP> form
<tb> general <SEP> rounded, <SEP> preferentially <SEP> again
<tb> ellipsoidal.

Also <SEP> for <SEP> limit <SEP> these <SEP> risks, <SEP> the notch
<tb> is <SEP> formed <SEP> by <SEP> deformation <SEP> plastic, <SEP> when <SEP> of
<tb> forging <SEP> of <SEP> the <SEP> ring <SEP> or <SEP> by <SEP> a <SEP> deformation
<tb> later. <SEP> This <SEP> deformation <SEP> plastic <SEP> presents
<tb> advantage, <SEP> by <SEP> report <SEP> to <SEP> a <SEP> realization <SEP> of
<tb> notch <SEP> by <SEP> machining, <SEP> to harden <SEP> the <SEP> distorted <SEP> area. <SEP> He
<tb> in <SEP> results <SEP> that, <SEP> at <SEP> neighborhood <SEP> of <SEP> the notch, <SEP> the <SEP> topic
<tb> of <SEP><SEP> ring <SEP> is <SEP> subject <SEP> to <SEP> of <SEP><SEP> local <SEP> constraints of
<tb> compression <SEP> which <SEP> is opposed <SEP> to <SEP> constraints <SEP> of <SEP> traction
<tb> generated <SEP> by <SEP> a <SEP> swelling <SEP> of <SEP> the <SEP> ring <SEP> when <SEP> of
<tb> forming <SEP> of <SEP> the <SEP> flange. <SEP> Thus, <SEP> i1 <SEP> is <SEP> possible <SEP> of
<tb> realize <SEP><SEP> notches <SEP> or <SEP> other <SEP> discontinuities <SEP> of

dimensions <SEP> relatively <SEP> more <SEP> important, <SEP> for
<tb> contrast <SEP> with <SEP> of <SEP> pairs <SEP> of <SEP> reptation <SEP> plus <SEP> important.

<SEP> general <SEP> way, <SEP> the invention <SEP> allows <SEP> so <SEP> of
<tb> realize <SEP> a <SEP> set <SEP> of <SEP> rolling <SEP> of <SEP> type <SEP>"<SEP> ready <SEP> to
<tb> job <SEP>",<SEP> where <SEP> the <SEP> ring <SEP> inside <SEP> reported <SEP> is
<tb> fixed <SEP> in <SEP> rotation, <SEP> without <SEP> than <SEP> that <SEP> sets <SEP> one
<tb> additional <SEP> constraint <SEP> in <SEP><SEP> sizing <SEP> of
<tb> ring, <SEP> the <SEP> choice <SEP> of the <SEP> material, <SEP> or <SEP> the <SEP> treatments
<tb> thermal, <SEP> when <SEP> of <SEP><SEP> design <SEP> of <SEP> ring
<tb> inner, <SEP> and <SEP> without <SEP> complicate <SEP> the <SEP> manufacture <SEP> by <SEP> of
<tb> complementary <SEP> machining, <SEP> and <SEP> also <SEP> without <SEP> than <SEP> the
<tb> hold <SEP> axial <SEP> of <SEP> the <SEP> ring <SEP> ne <SEP> or <SEP> assigned.

According to <SEP> a <SEP> variant <SEP> of <SEP> realization, <SEP> the <SEP> tier
<tb> has <SEP> a <SEP> second <SEP><SEP> inner ring <SEP> with <SEP> one
<tb><SEP> path of <SEP> rolling <SEP> for <SEP> a <SEP> second <SEP> row <SEP> body
<tb> rolling, <SEP> and <SEP> on <SEP> which <SEP> the <SEP> first <SEP> ring <SEP> is
<tb> applied <SEP> in <SEP> stop <SEP> axial, <SEP> the <SEP> second <SEP> ring <SEP> being
<tb> itself <SEP> in <SEP> stop <SEP> against <SEP> the <SEP> says <SEP> element <SEP> stop
<tb> Axis <SEP> linked <SEP> to the <SEP> hub.

Preferentially <SEP> then, <SEP> for <SEP> immobilize
<tb> also <SEP> the <SEP> second <SEP> ring <SEP> in <SEP> rotation, <SEP> the <SEP> plan <SEP> of
<tb>'anointed<SEP> between <SEP> the <SEP> first <SEP> and <SEP> the <SEP> second <SEP> ring
<tb> inner <SEP> is <SEP> not <SEP> orthogonal <SEP> to <SEP> the <SEP> axis of <SEP> rotation.
<tb> in <SEP> results <SEP> a <SEP> offset <SEP> axial <SEP> of the <SEP> plan <SEP> of <SEP> joint
<tb> between <SEP> two <SEP> opposite <SEP> diametrically <SEP> points. <SEP> This <SEP> offset
<tb> would tend <SEP> to <SEP> remove <SEP> axially <SEP><SEP> rings <SEP> one <SEP> from
<tb> other <SEP> in <SEP> case <SEP> of a <SEP> relative <SEP> rotation, <SEP> but <SEP> as <SEP> a
<tb> such <SEP> displacement <SEP> axial <SEP> is <SEP> prevented <SEP> from <SEP> makes <SEP> that <SEP>
<tb><SEP> rings are <SEP> maintained <SEP> between <SEP><SEP><SEP> element
<tb> Axial <SEP> of the <SEP> hub <SEP> and <SEP> the <SEP> flange, <SEP> a <SEP> such <SEP> rotation
<tb> relative <SEP> is <SEP> not possible, <SEP> and <SEP> as <SEP> the <SEP> first <SEP> ring is immobilized in rotation by the notches and beads the second ring is thus also blocked in rotation. The subject of the invention is also an inner rolling bearing ring, in particular intended for a bearing as defined above, comprising a bore intended to be fitted on a hub, and an external end face intended to constitute a bearing face. for a retaining face of a collar for axial retention of the ring on said hub, characterized in that it comprises at least one discontinuity of shape in an intermediate zone connecting said outer end face to the surface of the bore of the ring, intended to receive bead of the material constituting the hub, this bead being formed by creep of said material in the discontinuity when obtaining the flange by plastic deformation.

Other features and advantages will appear in the description that will be made of a rolling bearing with two rows of balls.

conforming <SEP> to <SEP> invention.
<tb> On <SEP> will report <SEP> to <SEP> drawings <SEP> appended <SEP> in
<tb> which ones
<tb> - <SEP> The <SEP> figure <SEP> 1 <SEP> is <SEP> a <SEP><SEP> view in <SEP><SEP> perspective of a
<tb> tier <SEP> compliant <SEP> to <SEP> the invention <SEP>;
<tb> - <SEP> the <SEP> figure <SEP> 2 <SEP> is <SEP> a <SEP><SEP> view in <SEP><SEP> axial <SEP> cut of the
<tb> step <SEP> of <SEP> figure <SEP> 1 <SEP>;
<tb> - <SEP> the <SEP> figure <SEP> 3 <SEP> is <SEP> a <SEP> view <SEP> to <SEP> scale <SEP> maximized <SEP> from
<tb> detail <SEP> A <SEP> of <SEP> the <SEP> figure <SEP> 2 <SEP>; Figure 4 is a perspective view of the bearing inner race of the bearing; - Figure 5 is a half-sectional view along the line VV of Figure 4; - Figure 6 is a half-sectional view along the line VI-VI of Figure 4; Figures 7 and 8 are views corresponding to Figures 5 and 6, in section, in the case of an alternative embodiment of the intermediate zone between the end face and the bore ring; - Figure 9 is a sectional view of a bearing according to another arrangement, with two inner rings. The bearing illustrated in the drawings of Figures 1 and comprises an outer race 1 provided with a flange ring 11 provided with lugs 12 for attachment to any structural element, not shown, for example by means of screws passing through holes 13 in the ears.

tier <SEP> has <SEP> also <SEP> a <SEP> hub <SEP> 2 <SEP> also
<tb> provided <SEP> with <SEP> flange <SEP> 21, <SEP> on <SEP> which <SEP> can <SEP> with <SEP> example
<tb> be <SEP> Rise <SEP> a <SEP> rim <SEP> of <SEP> wheel.
<tb> Between <SEP> the <SEP> hub <SEP> 2 <SEP> and <SEP> the <SEP><SEP> outer ring <SEP> 1 <SEP> are
<tb> placed <SEP> two <SEP> rows <SEP> of <SEP> balls <SEP> 3, <SEP> 4. <SEP> The <SEP> first
<tb> row <SEP> of <SEP> balls <SEP> 3 <SEP> rolls <SEP> between <SEP> a <SEP> first <SEP> outer rolling track 14 made in outer ring 1 and a first track of inner race 51 arranged on an inner ring 5. second row of balls 4 is located between a second outer race 15 of the outer ring 1 and a second inner race 22 arranged directly on the body 23 of the hub. The inner ring 5 is fitted, a cylindrical bore 53, on a bearing surface 24 of the hub body 23, of reduced diameter relative to the portion 25 carrying the second inner race 22, abutting against a shoulder 26 of the hub body.

<SEP> set of <SEP> pieces <SEP> which <SEP> comes <SEP> to be <SEP> described
<tb> constitutes <SEP> thus <SEP> a <SEP> roll <SEP> to <SEP> two <SEP> rows <SEP> of <SEP> balls
<tb> to <SEP> contact <SEP> oblique, <SEP> of <SEP> type <SEP> general <SEP> well <SEP> known. <SEP> The
<tb> ring <SEP> inner <SEP> 5 <SEP> is <SEP> maintained <SEP> axially <SEP> pressed <SEP> in
<tb> stop <SEP> against <SEP> shoulder <SEP> 26 <SEP> by <SEP> a <SEP> collar <SEP> 27
<tb> annular <SEP> formed <SEP> by <SEP> deformation <SEP> plastic <SEP> of a
<tb> part <SEP> device <SEP> 28 <SEP> of <SEP> the <SEP> end of <SEP> body <SEP> of
<tb> hub <SEP> which, <SEP> for <SEP> facilitate <SEP> this <SEP> deformation
<tb> plastic, <SEP> has <SEP> a <SEP> release <SEP> central <SEP> The
<tb> collar <SEP> thus <SEP> folded <SEP> radially <SEP> against <SEP> the <SEP> face
<tb> frontal <SEP> external <SEP> 52 <SEP> of <SEP> the <SEP> inner <SEP> ring <SEP> 5,
<tb> determines <SEP> a <SEP> face <SEP> of <SEP> retention <SEP> 29 <SEP> which <SEP> constitutes <SEP> a
<tb> stop <SEP> for <SEP> the <SEP> ring <SEP> inside <SEP> 5, <SEP> preventing <SEP> any

<SEP> axial movement <SEP> of <SEP> the <SEP> ring <SEP> after <SEP> forming <SEP> la
<tb> collar.

<SEP> seals <SEP> sealing <SEP> 61, <SEP> 62 <SEP> are <SEP> places <SEP> of
<tb> every <SEP><SEP> side of the <SEP> roll, <SEP> respectively <SEP> of a <SEP> share
<tb> between <SEP> outer <SEP> ring <SEP> 1 <SEP> and <SEP> on the <SEP> hub, <SEP> and <SEP> on other
<tb> share <SEP> between <SEP><SEP><SEP> outer ring <SEP> and <SEP><SEP> inner <SEP> ring
<tb> 5, <SEP> the <SEP> scope <SEP> of the <SEP> join <SEP> 62 <SEP> on <SEP> this <SEP> ring <SEP> being
<tb> makes <SEP> on <SEP> the <SEP> surface <SEP> cylindrical <SEP> outside <SEP> 58 <SEP> of
<tb> the <SEP> part <SEP> the <SEP> more <SEP> massive <SEP> 59 <SEP> from <SEP> the <SEP> inner <SEP> ring
<tb> 5.

In <SEP> the <SEP> mode <SEP> of <SEP> realization <SEP> of <SEP> figures <SEP> 1 <SEP> to <SEP> 6,
<tb> the <SEP> area <SEP> intermediate <SEP> connecting <SEP> the <SEP> face <SEP> external face 52 and the surface of the bore 53 of the ring 5 comprises, starting from the bore an annular portion 54, with a diameter slightly greater than that of the bore 53, to which it is connected by a chamfered shoulder 55, a rounded connection 56 constituting a zone of toroidal shape, and an axial recess 57, clearly visible. in FIGS. 5 and 6, such that the edge of the flare 56 is slightly set back from the plane of the outer end face 52. The increased diameter of the portion 54 relative to the bore 53 allows that, at the moment the embodiment of the collar 27, a portion of the metal of the end of the hub is pushed into the recess formed by this increase in diameter, and provides, in addition to the collar itself, a complement of axial retention of the inner ring 5, forming a stop for the shoulder 55. It should be noted that this portion 54 contributes to the axial retention of the ring, but does not provide a bearing function, which is entirely provided by the cylindrical surface 53 of the bore. The inner ring 5 has several discontinuities, constituted in the example shown by notches 7, four in number, circumferentially distributed, made in the intermediate zone between the outer end face 52 and the bore 53 of the ring. As can be seen in FIGS. 3 and 5, the notches 7 are inclined with respect to the axis of rotation of the bearing, at an angle close to, for example, 45. The notches 7 preferably have, in section, a rounded shape, for example semi-ellipsoidal, as can be seen in FIG. 4. It will be noted that the notches 7 do not open either into the external frontal surface 52 or into the cylindrical surface of the bore. 53 that is to say that they are totally included in the intermediate zone having no cylindrical bearing function or axial stop, so as not to modify the characteristics relating to these functions with respect to assemblies using rings of the same size. As can be seen in particular in FIG. 5, the notch 7 opens on the side of the front face at the limit of the rounding 56, or possibly below, and therefore below the recess 57, thus without interfering with the front surface 52. Also, the notch opens out on the bore side in the increased diameter portion 54, without interfering with the bearing surface 53 of the bore. As will have already been understood, during the forming of the collar 27, the deformed metal flows into said notches by forming a bead 30 under the pressure exerted on the edge of the hub to fold it against the end face 52 in the form of the flange 27. The discontinuities or notches 7 are formed on the solid annular portion 29 which forms the heel of the ring, this portion having a section which can be defined by a rectangle of length L, corresponding to the axial length of the surface 58 jointed bearing surface, and height H, corresponding to the overall thickness of the solid part 59, as shown in FIG. 5. Typically, the area of this rectangle is greater than 16 mm 2, and the volume of said solid part is greater than at 2800 mm3, these conditions making it possible to ensure sufficient rigidity the solid part 29, avoiding any risk of deformation of the ring during the production of the flange and obtaining the beads FIGS. 8 show an alternative embodiment of the ring 5 ', in which the intermediate zone in which the notches 7 are made comprises only the connecting flange 56 and the recess 57, that is to say without the zone of increased diameter. of the previous embodiment. Note that in this case also, the notch 7 is made so as not to open into the bearing surface of the ring, and is entirely in the rounding 56. In this case, the angle of inclination of the bottom of the notch relative to the axis may also be increased. The bearing shown in FIG. 9 differs from that of FIG. 2 by the use of a second inner ring 6 carrying the raceway for the second row of balls 4. The second inner ring 6 is fitted on the body of the hub, in stop against a shoulder 64, and the first inner ring 5 is itself pushed in axial abutment against said second ring 6 by the flange 27. In order also to lock this second ring in rotation, the end faces in contact of the two rings are made with a slight bias with respect to the plane orthogonal to the axis, for example with an angle B between 85 and 89, so as to create an axial offset between two diametrically opposite points at the level of the joint plane P between the two inner rings . This offset creates wedge effect, preventing the rotation of the second ring relative to the first, and therefore relative to the hub. In the case of the assembly of Figure 9, it will also be noted that the outer ring is here a simple ring with a cylindrical outer surface intended to be mounted in a bearing machined in any support piece. The invention is not limited to the embodiments and variants illustrated in the examples described above. In particular, other forms of section of the intermediate zone between the outer end face and the bore may be used. The discontinuities according to the invention may also be made in different forms but functionally equivalent to the notches shown in the examples. Also, in case of an assembly with two inner rings reported, the second ring can be maintained only by the axial pressure exerted on it by the first ring, only then to be locked in rotation, or by the ring / hub interference of the mounting.

1. <SEP><SEP> Bearing <SEP> Bearing of <SEP> Type <SEP> with <SEP> at
<tb> minus <SEP> a <SEP> row <SEP> of <SEP> body <SEP> rolling <SEP> (3, <SEP> 4) <SEP> is
<tb> moving <SEP> on <SEP> a <SEP><SEP> path of <SEP> rolling <SEP> (51) <SEP> of a <SEP> ring
<tb> inner <SEP> (5) <SEP> which <SEP> is <SEP> enabled <SEP> on <SEP> a <SEP> hub <SEP> (2) <SEP> and
<tb> maintained <SEP> axially <SEP> by <SEP> a <SEP> flange <SEP> (27) <SEP> obtained

Claims (1)

Claims by plastic deformation of a peripheral portion (28) of the hub after the ring has been mounted, the collar (27) having a retention face, (29) applied in pressure on an outer end face (52) of the ring, so as to axially immobilize said ring, in axial thrust against an axial abutment element (26) connected to the hub, characterized in that the inner ring (5) comprises at least one discontinuity of shape (7) in a zone intermediate connecting said outer end face <SEP> (52) <SEP> to <SEP> <SEP> surface <SEP> of <SEP> bore <SEP> (53) <SEP> of <SEP> < tb> ring <SEP> (5), <SEP> and <SEP> in <SEP> this <SEP> than <SEP> a <SEP> bead <SEP> (30) <SEP> of <SEP> material <tb > constitutive <SEP> of the <SEP> hub <SEP> is <SEP> inserted <SEP> at <SEP> less <tb> partially <SEP> in <SEP> the <SEP> discontinuity <SEP> of <SEP> la <SEP> ring, <SEP> this <tb> bead <SEP> being <SEP> formed, <SEP> a u <SEP> <SEP> level of <SEP> <SEP> <SEP> join between <tb> <SEP> <SEP> <SEP> surface <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> and <SEP> the <SEP> face <SEP> of <tb> retention <SEP> (29) <SEP> of <SEP> the <SEP> flange <SEP> (27), <SEP> by <SEP> creep <SEP> of the <tb> said <SEP> material <SEP> in <SEP> the <SEP> discontinuity <SEP> (7) <SEP> when <SEP> of <tb> obtaining <SEP> of <SEP > the <SEP> flange <SEP> by <SEP> deformation <tb> plastic. <tb> 2. <SEP> Tier <SEP> to <SEP> rolling <SEP> according to <SEP> the <SEP> claim <SEP> 1, <tb> characterized <SEP> in <SEP> this <SEP> as <SEP> The <SEP> so-called <SEP> <SEP> Intermediate <tb> zone has <SEP> a <SEP> <SEP> zone of <SEP> <SEP> Toroidal <SEP> form (56), <SEP> of which <SEP> the <tb> section <SEP> is <SEP> a <SEP> rounded <SEP> connecting <SEP> the so-called <SEP> <SEP> face <SEP> front <tb> external <SEP> (52 ) <SEP> at <SEP> the <SEP> surface <SEP> (53) <SEP> of <SEP> 'The <SEP> bore of <SEP> the <SEP> (5), <SEP> ring and <SEP> The <SEP> discontinuity <SEP> (7) <SEP> is <SEP> limited <SEP> to <SEP> the <tb> so-called <SEP> zone, <SEP> without <SEP> encroach <SEP> on <SEP> the <SEP> face <SEP> frontal <SEP> external <tb> (52) <SEP> nor <SEP> on <SEP> the <SEP> surface <SEP> cylindrical <SEP> (53) < SEP> from <SEP> the bore. <tb> 3. <SEP> Tier <SEP> to <SEP> rolling <SEP> according to <SEP> <SEP> claim <SEP> 1, <tb> characterized <SEP> in <SEP> this <SEP> as <SEP> the <SEP> ring <SEP> (5) <SEP> has <SEP> several <tb> of <SEP> say <SEP> discontinuities <SEP> (7), <SEP> distributed <tb> circumferentially. <tb> 4. <SEP> Tier <SEP> to <SEP> rolling <SEP> according to <SEP> the <SEP> claim <SEP> 1, <tb> characterized <SEP> in <SEP> this <SEP> as <SEP> the <SEP> or <SEP> the <SEP> discontinuities <SEP> (7) <tb> are <SEP> formed <SEP> by <SEP> deformation <SEP> plastic <SEP> when <SEP> of <tb> forging <SEP> of <SEP> the <SEP> ring <SEP> (5). <tb> 5. <SEP> Tier <SEP> to <SEP> rolling <SEP> according to <SEP> <SEP> claim <SEP> 1, <tb> characterized <SEP> in <SEP> this <SEP> as <SEP> the <SEP> discontinuity <SEP> a <tb> notch <SEP> (7) <SEP> where <SEP> the <SEP> background <SEP> extends <SEP> obliquely <SEP> by <tb > report <SEP> to <SEP> the <SEP> axis of <SEP> rotation. <tb> 6. <SEP> Range <SEP> to <SEP> turnover <SEP> according to <SEP> <SEP> claim <SEP> 5, <tb> characterized <SEP> in <SEP> <SEP> that <SEP> the <SEP> (7) <SEP> a <SEP> slot has a <SEP> section <SEP> of <tb> semi-ellipsoidal <SEP> form. <tb>. <SEP> Bearing <SEP> to <SEP> bearing <SEP> according to <SEP> <SEP> claim <SEP> 5, <tb> characterizing <SEP> in <SEP> this <SEP> than <SEP> < SEP> width <SEP> of <SEP> the notch <SEP> (7) <SEP> is <tb> greater <SEP> than <SEP> its <SEP> maximum <SEP> maximum. <tb>. <SEP> Range <SEP> to <SEP> turnover <SEP> according to <SEP> <SEP> claim <SEP> 2, <tb> characterized <SEP> in <SEP> that <SEP> than <SEP> < SEP> ring <SEP> inside <SEP> (5) <tb> contains <SEP> a <SEP> recess <SEP> axial <SEP> (57) <SEP> between <SEP> the <SEP> face <tb> external <SEP> external <SEP> (52) <SEP> and <SEP> the <SEP> zone <SEP> of <SEP> <SEP> toroidal <tb> form (56). Rolling bearing according to Claim 2, characterized in that the inner ring (5) has, on the side of the outer end face (52), an annular portion (54) of larger diameter than the bore (53). to which it is connected by a shoulder (55), and the notch (7) opens into said annular portion. 10. Rolling bearing according to Claim 1, characterized in that it comprises a second inner race (6) comprising a raceway for a second row of rolling bodies (4), and on one face of which the first race ( 5) is applied in axial abutment, the second ring (6) itself being in abutment against an axial abutment element (64) connected to the hub. . Roller bearing according to claim 10, characterized in that the joint plane (P) between the first (5) and the second (6) inner ring is orthogonal to the axis of rotation. 12. Rolling bearing according to Claim 11, characterized in that the angle (B) between the joint plane and the axis is between 85 and 89.     13. <SEP> Inner <SEP> ring <SEP> (5) <SEP> of <SEP> bearing <SEP> to <SEP> bearing, <tb> with <SEP> a <SEP> bore <SEP> (53) <SEP> for <SEP> to <SEP> be <SEP> enabled <tb> on <SEP> a <SEP> hub, <SEP>, and <SEP> a <SEP> face <SEP> front <SEP> external <SEP> (52) <tb> destined <SEP> to <SEP> constitute <SEP> a <SEP> <SEP> face of <SEP> support for <SEP> face <tb> of <SEP> retention <SEP> of a <SEP> flange <SEP> of <SEP> maintenance <SEP> axial <SEP> of <SEP> la <tb> ring <SEP> on <SEP> the <SEP> says <SEP> hub, <SEP> characterized <SEP> in <SEP> this <SEP> 'it <tb> has <SEP> at <SEP> minus <SEP> a <SEP> discontinuity <SEP> of <SEP> form <SEP> (7) <SEP> in <tb> an <SEP> <SEP> Intermediate <SEP> zone joining <SEP> the <SEP> so-called <SEP> front <SEP> face

    external <SEP> (52) <SEP> to <SEP> the <SEP> surface <SEP> of <SEP> the bore <SEP> (53) <SEP> of <SEP> <tb> ring <SEP> (5), <SEP> intended <SEP> to <SEP> to receive <SEP> a <SEP> bead <SEP> (30) <SEP> from <tb> material <SEP> constitutive <SEP> of the <SEP> hub, <SEP> this <SEP> bead <SEP> being <tb> formed <SEP> by <SEP> creep <SEP> of <SEP> says <SEP> material <SEP> in <SEP> la <tb> discontinuity <SEP> (7) <SEP> when <SEP> of <SEP> obtaining <SEP> of <SEP> <tb> flange <SEP> by <SEP> deformation <SEP> plastic.