FR3142232A1 - Differential with satellite axle stop - Google Patents

Abstract

Title of the invention: Differential with satellite axis stop The present invention relates to a differential (1) of a motor vehicle comprising a housing (2) within which planetary gears and satellites (16, 18) are arranged, the differential (1) comprising a satellite axis (20) extending in a longitudinal direction, this satellite axis (20) having a first longitudinal end (22) and a second longitudinal end (24). According to the invention, the first longitudinal end (22) of the satellite axis (20) is deformed to provide a stop for longitudinal movement of the satellite axis (20). Abstract Figure: Figure 2

Description

Differential with satellite axle stop

The present invention relates to the field of differentials for motor vehicles, and more particularly to such differentials equipped with a system for blocking the translation of their satellite axis.

Within a motor vehicle, a differential is a transmission device whose function is to distribute a distinctive engine torque to each of the wheels. Such a distribution allows the wheels to be rotated at different speeds when necessary, for example when the motor vehicle begins a turn. The differential thus allows a different rotation speed between a wheel located on the right side of the vehicle and a wheel located on its left side.

A differential generally comprises a differential housing which is driven by a toothed ring secured to this housing. The case also contains different bevel gears, including two sun gears and two satellites which are opposed in pairs. Each of the sun gears is connected to one of the wheels of the same axle of the vehicle, via a transmission shaft at the end of which the sun gear is secured. Each sun gear is engaged with the planet gears so that the rotational drive of the differential housing by the ring gear generates the rotational drive of the planetary gears and subsequently the rotational drive of the planetary gears. In order to be able to transmit the torque in a differentiated manner to the planetary gears, the satellite gears are made integral with a satellite axis mounted free to rotate in the differential housing, this satellite axis having to be blocked in translation by appropriate means.

It is known from the prior art to block this satellite axis in translation within the differential housing via an elastic ring, or snap ring, or even a pin. When the satellite axis is held by the snap ring, it is necessary to make a groove in the housing to accommodate it. The movements within the gear train can, however, generate axial micro-displacements of the satellite axis forcing on the ring and tending to dislodge it from the groove. In the same way, when the satellite axis is blocked by a pin, it is necessary to carry out arrangements and machining to accommodate it, mainly drilling both the satellite axis and the housing, which can generate a weakening of the mechanical strength of the housing.

The present invention aims to overcome these drawbacks by proposing a means for blocking the satellite axis in translation in a reliable manner, without additional machining operation of the differential housing, and which makes it possible to save on additional parts such as the ring. stop or pin.

The main object of the present invention is thus a differential of a motor vehicle comprising a housing within which planetary gears and satellite gears are arranged, the differential comprising a satellite axis secured in rotation to the satellite gears and extending in one direction longitudinal, this satellite axis having a first longitudinal end and a second longitudinal end. According to the invention, the first longitudinal end of the satellite axis is deformed to produce a stop for longitudinal movement of the satellite axis.

The differential according to the invention is intended to equip a motor vehicle in order to distribute engine torque to the wheels of the vehicle, where appropriate at different rotation speeds. The differential comprises a housing whose internal housing, delimited by a peripheral wall, constitutes a receiving space for two planetary gears and two satellite gears. The two planetary gears are respectively associated with one of the wheels of a drive axle of the vehicle via a drive shaft, each shaft extending substantially along the same first direction. These planetary gears are arranged face to face within the housing. The two satellite gears are for their part fixed on the satellite axis which extends along a second direction, here a longitudinal direction, which is perpendicular, or substantially perpendicular, to the first direction, each satellite gear being in engagement with each of the two planetary gears.

The satellite axis extends between a first longitudinal end and a second longitudinal end. At least one of these ends, here the first longitudinal end, is deformed so as to form a stop for longitudinal movement of the satellite axis relative to the differential housing. In other words, the first longitudinal end is configured to form, due to its own shape obtained after deformation, a stopping system or blocking system in translation of the satellite axis within the differential. The deformation being carried out on the satellite axis, it is therefore not necessary to machine the differential housing which is a more imposing part. Furthermore, advantageously, no additional part, other than the satellite axis and the differential housing, is necessary to block the axial movements of one relative to the other.

The first longitudinal end can be deformed to form an axial stop directly in contact with a wall of the differential housing, and more particularly an external face of this wall opposite the internal housing, or to form an axial stop on a washer interposed between the satellite axis and this wall of the differential housing.

This operation of deformation of the first longitudinal end can for example take the form of crimping. The deformation operation is notably implemented once the satellite axis is in position relative to the housing, that is to say once the satellite axis is cooperating with the satellite gears arranged within the internal housing of the housing of the differential. The deformation operation generates a boss, advantageously all around the satellite axis, which increases the radial dimension of the satellite axis at the level of a part which is arranged outside the housing, so as to block the position in a direction of the longitudinal direction of the satellite axis relative to the differential housing.

According to one characteristic of the invention, the first longitudinal end extends outside the housing. The deformation of the first longitudinal end of the satellite axis generates beads forming a local extra thickness of the satellite axis, these beads being formed outside the housing.

According to another characteristic of the invention, the two longitudinal ends extend outside the housing.

In other words, the first longitudinal end of the satellite axis, or even its two longitudinal ends, extend beyond the internal housing of the housing. More precisely, this or these longitudinal ends protrude from the housing and form a projection relative to its peripheral wall. When the deformation is carried out, it is thus not necessary to resort to modifying a space in the differential housing allocated to the other components thereof, the deformation being external to the housing.

As mentioned, the present invention is characteristic in that the first axial end of the satellite axis is deformed to generate a local extra thickness, outside the differential housing, so as to form an axial displacement stop. according to a direction of movement. In order to block the satellite axis in both directions of the axial direction, the second longitudinal end of the satellite axis is also configured to form an axial stop on the housing, on an external face of the housing opposite the face against which the deformation of the first longitudinal end abuts.

According to certain embodiments, the two longitudinal ends are deformed to form longitudinal stops, at opposite ends of the housing.

According to one characteristic, the second longitudinal end is equipped with a flange configured to provide a stop for longitudinal movement of the satellite axis.

The satellite axis then comprises a deformed longitudinal end and a longitudinal end carrying the flange. Such a collar can come into contact with the housing to operate the stop, thus preventing the translation of the satellite axis in a first direction.

According to one characteristic of the invention, an orifice is provided in the housing, this orifice being centered in the longitudinal direction, the satellite axis extending through the housing through this orifice.

In other words, this orifice is an orifice for the satellite axis to pass through the peripheral wall of the housing.

According to one characteristic, the orifice is a first orifice, the housing having a second orifice opposite the first orifice in the longitudinal direction, the satellite axis extending through these orifices.

Such a characteristic corresponds to an embodiment in which each of the longitudinal ends of the satellite axis extend outside the housing.

According to another characteristic of the invention, the first orifice and/or the second orifice have a chamfer.

This chamfer makes it possible, by gradually reducing the diameter of the orifice from the external face of the peripheral wall, to facilitate the insertion of the satellite axis through the orifice. And the first longitudinal end of the satellite axis, that is to say a longitudinal end which is deformed to form a longitudinal stop, can thus bear, once deformed, on the ramp formed by the chamfer.

According to one characteristic, the first longitudinal end is equipped with a washer configured to participate in the longitudinal movement stop of the satellite axis.

In other words, the deformation of the first longitudinal end allows a longitudinal movement stop by indirect contact on an external face of the differential housing, with the washer which is interposed between the deformation of the first longitudinal end and of the differential housing. differential. The washer is mounted on the satellite axis at the first longitudinal end, being associated with the satellite axis prior to deformation of the first longitudinal end. The washer has an outer diameter greater than a diameter of the satellite axle, so the washer increases the reach of the satellite axle. The presence of the washer associated with the deformation corresponds to a more robust embodiment than an embodiment presenting only the deformation, and more adapted to sustained constraints or efforts of the differential.

According to one characteristic, the satellite axis comprises a tube within which a cylinder is housed, the cylinder protruding longitudinally from the tube at least at the level of the first longitudinal end.

In other words, the tube forms a sheath for the cylinder, the satellite axis being formed by the association of the cylinder and the tube. This cylinder has a longitudinal dimension, that is to say a length, greater than the tube; it therefore protrudes from it at least on the side of the first longitudinal end. This difference between the respective longitudinal dimensions of the cylinder and the tube can make it possible both to carry out the deformation on the cylinder, and to facilitate the mounting of a washer around the cylinder and abutting on the tube. The separation of the satellite axis into two elements makes it possible to facilitate machining operations and in particular deformation of the satellite axis, avoiding that the satellite axis has a large diameter which is difficult to stamp.

Alternatively, the satellite axis can be made in one piece.

According to one characteristic of the invention, the washer rests on a shoulder formed at the junction between the tube and the cylinder of the satellite axis.

According to another characteristic of the invention, the housing and the satellite axis are made of cast iron.

According to an alternative characteristic, the satellite axis is made of steel covered with a heat treatment material.

We understand that these are two alternative embodiments: either the housing and the satellite axis are both made of the same material, for example cast iron, or only the housing is made of cast iron while the Satellite axis is made of steel coated with heat treatment. The steel used to make the satellite axis is for example AFNOR 16MC5 steel or AFNOR 20MC5 steel.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description which follows on the one hand, and examples of embodiment given for informational and non-limiting purposes with reference to the appended drawings on the other hand. , on which ones :

illustrates, schematically, a perspective view of a differential according to a first embodiment of the invention, in which the planetary gears and the associated drive shafts have not been represented to make the satellite gears more particularly visible at within the differential housing;

illustrates, schematically, a sectional view of the differential of the , again without the associated planetary gears and drive shafts, in a configuration where the end of a satellite axis is not yet deformed to form a longitudinal displacement stop;

is a view similar to that of the , in a configuration where the end of the satellite axis is this time deformed and forms a stop for longitudinal movement of the satellite axis within the differential housing;

schematically illustrates a second embodiment of the invention, in a configuration similar to that of the with one end of the satellite axis which is deformed and forms a stop for longitudinal movement of the satellite axis within the differential housing;

illustrates, schematically, a close-up view of the section of the , in particular to make visible a chamfer formed in the orifice to receive the satellite axis.

The characteristics, variants and different embodiments of the invention can be associated with each other, in various combinations, to the extent that they are not incompatible or exclusive with respect to each other. In particular, it will be possible to imagine variants of the invention comprising only a selection of characteristics described subsequently in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage and/or to differentiate the invention. compared to the prior art.

In the figures, elements common to several figures retain the same reference.

Figures 1 to 5 thus illustrate, schematically, a differential 1 according to several embodiments of the invention. This differential 1 is intended to equip a motor vehicle, within which its role is to transmit and distribute to the drive wheels a torque generated by the engine, so as to authorize these drive wheels to rotate at different speeds.

The torque of the engine is transmitted to the differential 1 from a transmission shaft, not shown here, which rotates a housing 2 of the differential 1 via an input ring gear 4. The input ring gear is integral with housing 2, which therefore rotates with it.

Housing 2 can be made of cast iron. Within this housing 2 are provided two clearances 6, 8, with a first clearance 6 and a second clearance 8, respectively configured to each receive a drive shaft made integral with one of the drive wheels previously mentioned. The first clearance 6 and second clearance 8 are aligned with each other and are centered around a first direction D1. For example, the first clearance 6 is crossed by a drive shaft associated with the left drive wheel, the second clearance 8 being crossed by a drive shaft associated with the right drive wheel.

Each of the drive shafts is associated with a planetary pinion of differential 1, at the end opposite the drive wheels. There is thus a first planetary pinion and a second planetary pinion, which although they are not shown in the figures are both arranged within the housing 2 of the differential 1. The two planetary pinions are arranged face to face considering the first direction D1 and they each face one of the clearances 6, 8. The planetary gears are more particularly arranged within an internal housing 12 of the housing 2 which corresponds to a recess within it, this internal housing 12 being delimited by a peripheral wall 14 of the housing 2.

Within the internal housing 12 of the housing 2 are also arranged two satellite gears 16, 18, including a first satellite 16 and a second satellite 18. These satellites 16, 18 are arranged face to face considering a second direction D2 which is perpendicular to the first direction D1 and which corresponds to a longitudinal direction. The planetary gears 16, 18 and the planetary gears are bevel gears which mesh with each other. It is thus understood that the planetary gears and the satellite gears 16, 18 are opposed two by two, each planetary gear being arranged between the two satellite gears 16, 18 and engaging with them, and in the same way each satellite gear 16 , 18 is arranged between the two planetary gears and engages with them.

The first and second satellite gears 16, 18 are both mounted on a satellite axle 20. This satellite axle 20 can be made of cast iron, like the housing 2 of the differential 1, or else be made of steel covered with 'a heat treatment material. The satellite axis 20 extends mainly in the second direction D2 or longitudinal direction, from a first longitudinal end 22 to a second longitudinal end 24 opposite each other.

The satellite axis 20 can be made in one piece, as is visible in Figures 4 and 5, or alternatively and as shown in Figures 2 and 3 in particular, be formed from an association of several components . In the example illustrated, the satellite axis 20 thus comprises a tube 26 within which a cylinder 28 is housed. The tube 26 and the cylinder 28 are both centered in the longitudinal direction. The tube 26 has a larger diameter than the cylinder 26 which it receives.

At least the first longitudinal end 22 of the satellite axis 20 extends outside the housing 2. In the embodiments illustrated here and as is particularly visible at the , each of the first longitudinal end 22 and the second longitudinal end 24 extends outside this housing 2. Here we mean “outside the housing 2” that the corresponding longitudinal end of the satellite axis 20 of one part extends beyond the internal housing 12 of the housing, and on the other hand forms a projection relative to the peripheral wall 14 thereof, towards the outside of the housing.

For this purpose, the housing 2 has at least one orifice which allows the passage of the satellite axis 20, that is to say both the tube 26 and the cylinder 28, through the peripheral wall 14. In the example illustrated, the housing 2 has more particularly a first orifice 30 and a second orifice 32, which are particularly visible at the .

The first orifice 30 is an orifice through which the satellite axis 20 extends near its first longitudinal end 22, while the second orifice 32 is that with which the satellite axis 20 cooperates in the vicinity of its second longitudinal end 24. For this purpose, the first orifice 30 and the second orifice 32 are opposite considering the longitudinal direction.

The two orifices 30, 32 are through orifices, that is to say they are provided within the peripheral wall 14 from an internal face 34 which faces the internal housing 12 to an external face 36 which is opposite this internal face 34. According to the invention, at least the first orifice 30 is through so that the first end of the satellite axis can form a projection outside the housing and can be deformed to be pressed against the external face of the differential housing.

The first orifice 30 and/or the second orifice 32 can be made so as to present, at least at the junction with the external face of the peripheral wall of the housing, a chamfer 38, which tends to flare the orifice at its ends, in particular to facilitate the insertion of the satellite axis through the corresponding orifice.

According to the invention, the first longitudinal end 22 of the satellite axis 20 is deformed to produce a longitudinal movement stop of this satellite axis 20. In other words, this deformation allows blocking in translation of the satellite axis 20 within the differential housing 1, in a direction S2 of the longitudinal direction.

The deformation of the first longitudinal end 22 is configured to generate a boss, or more particularly beads 21, forming radial extra thicknesses around the satellite axis. In this way, the diameter of a longitudinal end of the axis is locally increased, once it is in position in the housing and cooperating with the satellite gears, with said end projecting outside the housing.

The deformation corresponds to an enlargement of the satellite axis, of radial dimension greater than the corresponding radial dimension of the first orifice 30. Such deformation extends for example circumferentially over an entire circumference of the satellite axis 20.

The deformation is for example a crimping.

The second longitudinal end 24 of the satellite axis 20 comprises a flange 40 which forms a radial projection of the satellite axis and which constitutes a stop for longitudinal movement of the satellite axis 20, in a direction opposite to that mentioned previously, here an S1 direction. The flange 40 takes for example the shape of a disc which extends in a plane substantially perpendicular to the second direction D1 and which has a diameter greater than a diameter of the satellite axis 20. The flange 40 rests at least partly against the external face 36 of the peripheral wall 14 of the housing 2. When the satellite axis comprises a tube and a cylinder, the collar can be made integrally with the cylinder 28, the collar 40 being in contact with the corresponding end of the tube 26.

The corresponding assembly process may in particular be as follows. The gears are inserted into the internal housing 12 of the differential housing, through a lateral opening of appropriate dimensions, and the satellite axle is then inserted in the second direction D2, or longitudinal direction, through the housing to cooperate with the satellite gears 16, 18. The satellite axle is inserted into the housing through the second hole and is guided successively through each of the planet gears. The insertion of the axis continues until the collar 40 comes into contact with the external face 36 of the peripheral wall 14 of the housing and forms an axial stop to movement in a first direction S1 of the longitudinal direction. In this stop position, the first longitudinal end 22 of the satellite axis, opposite the flange 40, protrudes outside the housing, having passed through the first orifice 30 to exit the internal housing. There illustrates this stop position, with a first longitudinal end which is not yet deformed.

The assembly process then continues with the deformation, for example by stamping, of the part of the satellite axis protruding from the housing, here the first longitudinal end 22. The deformation is carried out in the direction of the housing, to push the material against the peripheral wall of the housing. The deformation carried out, visible on the , generates beads 21 which locally enlarge the radial dimension of the satellite axis 20 and which contribute to forming a stop to the axial clearance of the satellite axis through the first orifice 30. The beads 21 bear against a portion of peripheral wall delimiting the contours of the first orifice 30, whether directly, as visible in Figures 4 and 5, or indirectly, as visible in Figures 2 and 3.

It is thus understood that the deformation of the first longitudinal end 22 allows, by a simple means, without insert parts in particular, to generate an axial stop in a defined direction, participating in blocking the longitudinal movement of the satellite axis within the differential housing. . It is not necessary to ensure the position of the satellite axis during assembly, since the satellite axis can be fully inserted in a first direction, the collar ensures a stop in this first direction , then distorted in a second direction. It is only necessary to provide counter-support on the collar, opposite the housing, when the first longitudinal end is deformed in order to ensure that the satellite axis does not escape through the second orifice under the effort required for deformation. Furthermore, it is not necessary to ensure a particular angular position of the satellite axis around the longitudinal direction, since the assembly process involves axial stops and an axial deformation step, and not a pin. for example for which it is appropriate to place the pin and a suitable hole formed on the satellite axis.

In a variant embodiment, here not illustrated, each of the longitudinal ends 22, 24 has a deformation similar to what was described previously for the first longitudinal end, the deformations forming blockages in translation in opposite directions S1, S2 along of the longitudinal direction. It is understood that a bead forming a local extra thickness at the level of the second longitudinal end replaces the collar in this variant. The deformations are carried out successively on each longitudinal end, once the satellite axis is in place, that is to say cooperating with the satellite gears and with longitudinal ends protruding outside the housing.

According to the invention, at least the first longitudinal end 22 is deformed to form a longitudinal stop to the movement of the satellite axis relative to the differential housing, whether by deformation of the axis directly in contact with the external face of the housing or indirectly in contact via an attached part, such as a washer.

In the first embodiment illustrated in Figures 2 and 3 in particular, the satellite axis 20, at the level of the first longitudinal end 22, is equipped with a washer 42 configured to participate in the longitudinal movement stop of the axis satellite 20 in the second direction S2. The washer 42 participates in blocking the translation of the satellite axis 20, by increasing the support surface and the transmission of forces between the deformed axial end of the satellite axis and the peripheral wall of the differential housing. This ensures that a force is correctly applied to the housing to limit movement.

The washer is inserted around the satellite axis once it is in place in the housing, that is to say with a first longitudinal end which protrudes from the housing. The washer 42 has an annular shape which extends mainly perpendicular to the longitudinal direction. It has an external diameter greater than the diameter of the satellite axis 20 and an internal diameter which allows its insertion around the axis. In the case of a satellite axis with a tube and a cylinder, the washer 42 is arranged around the tube 26 and against the end of the cylinder 28.

The second embodiment, illustrated in Figures 4 and 5, differs from what has been described previously in particular in that the first longitudinal end is not equipped with a force absorbing washer. The deformation of this first longitudinal end, and the resulting beads 21, are directly in contact with the external face of the peripheral wall of the housing.

It should be noted that this second embodiment is shown here with a satellite axis 20 made in one piece, but that it could just as easily be implemented with a satellite axis formed of a cylinder and a tube as previously mentioned, just as the first embodiment could be implemented with an axis formed in one piece.

In this context of direct contact between the housing and the beads 21 generated by the deformation of the first longitudinal end of the satellite axis, without an interposed washer, it may be interesting to increase the dimension of the chamfer 38, so that such that this is visible on the , the beads 21 match the shape of the chamfer 38 equipping the orifice(s) 30, 32 through which the satellite axis 20 extends.

The present invention as it has just been described achieves the goals it set for itself by proposing a differential whose satellite axis is blocked in translation reliably, without requiring additional means distinct from the axis. satellite and differential housing.

The present invention cannot, however, be limited to the means and configurations described and illustrated here and it also extends to any equivalent means and configuration as well as to any technically effective combination of such means.

Claims (12)

Differential (1) of a motor vehicle comprising a housing (2) within which planetary gears and satellite gears (16, 18) are arranged, the differential (1) comprising a satellite axle (20) integral in rotation with the gears satellites and extending in a longitudinal direction, this satellite axis (20) having a first longitudinal end (22) and a second longitudinal end (24), the differential (1) being characterized in that the first longitudinal end (22) of the satellite axis (20) is deformed to produce a longitudinal movement stop of the satellite axis (20). Differential (1) according to the preceding claim, in which the first longitudinal end (22) extends outside the housing (2). Differential (1) according to any one of the preceding claims, in which the two longitudinal ends (22, 24) extend outside the housing (2). Differential (1) according to any one of the preceding claims, in which the second longitudinal end (24) is equipped with a flange (40) configured to provide a stop for longitudinal movement of the satellite axis (20). Differential (1) according to any one of the preceding claims, in which an orifice (30, 32) is provided in the housing (2), this orifice (30, 32) being centered on the longitudinal direction, the satellite axis ( 20) extending through the housing (2) through this orifice (30, 32). Differential (1) according to the preceding claim, in which the orifice (30, 32) is a first orifice (30), the housing (2) having a second orifice (32) opposite the first orifice (30) in the longitudinal direction , the satellite axis (20) extending through these orifices (30, 32). Differential (1) according to the preceding claim, in which the first orifice (30) and/or the second orifice (32) have a chamfer (38). Differential (1) according to any one of the preceding claims, in which the first longitudinal end (22) is equipped with a washer (42) configured to participate in the longitudinal movement stop of the satellite axis (20). Differential (1) according to any one of the preceding claims, in which the satellite axis (20) comprises a tube (26) within which a cylinder (28) is housed, the cylinder (28) projecting longitudinally from the tube at least at the first longitudinal end (22) of the satellite axis (20). Differential (1) according to the preceding claim in combination with claim 8, in which the washer (42) rests on a shoulder (44) formed at the junction between the tube and the cylinder of the satellite axis. Differential (1) according to any one of the preceding claims, in which the housing (2) and the satellite axle (20) are made of cast iron. Differential (1) according to any one of claims 1 to 10, in which the satellite axis (20) is made of steel covered with a heat treatment material.