FR3003613A1 - ROTATIONAL DRIVE SYSTEM FOR A MOTOR VEHICLE WHEEL - Google Patents

Abstract

The invention relates to a drive system for rotating a motor vehicle wheel, said system comprising: a rolling bearing having a rotating member (1) comprising means (3a) for associating the wheel; a transmission bowl (4) having a shell (6) integral in rotation with the rotating member (1) and a nut (7) pivotally mounted within said shell by rotating it; a driving shaft (5) integral in rotation with said nut by means of a reversible mounting device comprising complementary splines (12a, 12b) which are respectively integral with the shaft (5) and the nut (7) and a thrust bearing (16) which is disposed between said shaft and the nut, said stop being provided with a locking sleeve (17) which is reversibly movable between a locked position in which the balls (16) are constrained by said sleeve to prevent relative movement of the shaft (5) and the nut (7) and a mounting position in which the balls (16) are free to allow said relative movement.

Description

The invention relates to a drive system for rotating a motor vehicle wheel comprising a rolling bearing, a transmission bowl and a motor shaft.

The bearing has a rotating member rotatably mounted relative to a fixed member via at least one row of rolling bodies, the rotating member comprising means for associating the wheel and the fixed member comprising means of association with the structure of the vehicle.

Such a bearing allows the rotational mounting of a motor vehicle wheel which, when it is driving, can be rotated by a transmission bowl which is actuated in rotation by means of a shaft coupled to the motor of the motor. vehicle.

To compensate for misalignments between the bearing and the motor shaft during the advancement of the vehicle, the bowl may have a shell integral in rotation with the rotating member and a nut driven in rotation by the drive shaft, said nut being mounted pivoting inside said shell, in particular to form a homokinetic joint (CVJ) for example Rzeppa type. To ensure the transmission of the rotational torque between the nut and the motor shaft, it is known to use gear means integral respectively said nut and said shaft, for example formed of axial grooves which are engaged with each other. However, this type of transmission system is not entirely satisfactory, especially with regard to the ease of handling during assembly and the reversibility of said assembly to replace at least one element of said transmission system. In addition, for transmission systems in which the shell is integrated in the rotating member, these problems are all the more critical.

The invention aims to improve the prior art by proposing in particular a drive system in which the mounting of the motor shaft on the bowl can be performed reversibly and in a simplified manner, in particular in relation to a rotating member incorporating the shell in which nut is pivotally mounted. For this purpose, the invention proposes a system for driving a motor vehicle wheel in rotation, said system comprising: a rolling bearing having a rotating member rotatably mounted relative to a fixed member via a at least one row of rolling bodies, said rotating member comprising means for associating the wheel; - A transmission bowl having a shell integral in rotation with the rotating member and a nut pivotally mounted within said shell by driving it in rotation; a motor shaft integral in rotation with said nut by means of a reversible mounting device; the reversible mounting device comprising complementary splines which are respectively integral with the shaft and the nut, said splines being engaged with each other to allow transmission of a driving torque to the nut, said mounting device comprising a thrust bearing which is disposed between said shaft and the nut, said stop being provided with a locking sleeve which is reversibly movable between a locked position in which the balls are stressed by said sleeve to prevent relative movement of the shaft and the nut and a mounting position in which the balls are free to allow said relative movement. Other objects and advantages of the invention will appear in the description which follows, made with reference to the appended figures, in which: FIG. 1 is a partial representation in longitudinal section of a drive system according to an embodiment of the invention in which the locking sleeve is in the locked position, Figure 1a being a zoom of a portion of Figure 1; - Figure 2 is a partial exploded perspective representation of the drive system according to Figure 1; - Figures 3 and 4 are perspective representations respectively of the nut and the locking sleeve of the drive system according to Figure 1; FIG. 5 is a partial longitudinal sectional representation of the drive system according to FIG. 1 showing the locking bushing being moved between its locked and mounting positions; FIG. 6 is a partial longitudinal sectional representation of the drive system according to FIG. 1 showing the locking bush in the mounting position, FIG. 6a being a zoom of part of FIG. 6. In connection with these FIGS. , there is described below a drive system for rotating a motor vehicle wheel comprising a rolling bearing for mounting in rotation of said wheel.

To do this, the bearing has a rotating member 1 rotatably mounted relative to a fixed member 1 'via at least one row of rolling bodies B. In the embodiment shown, the inner member 1 is rotating in the outer member 1 'fixed by means of two rows of balls B spaced axially. However, the invention can be applied to a mounting in which the outer member is rotatable and the inner member is fixed. In the description, the terms "outside", "inside", "axial" and "radial" are defined with respect to the axis of rotation of the bearing, respectively for a remote location, close, following and perpendicular to said axis. The rotating member 1, for example made of steel, has a bore 2 and comprises means for associating the wheel which, in the figures, are formed of a flange 3 on which can be formed holes 3a for fixing the the wheel by screwing. In a manner not shown, the fixed member 1 'comprises means of association with the vehicle structure, for example means of association with a suspension element of said vehicle.

In the case of mounting a drive wheel, the rotational drive of said wheel can be achieved by a transmission bowl 4 which is actuated in rotation by means of a shaft 5 coupled to the vehicle engine. In particular, the transmission bowl 4 has a shell 6 integral in rotation with the rotating member 1 and a nut 7 mounted inside said shell by driving it in rotation. To transmit a driving torque to the rotating member 1 via the nut 7, the drive shaft 5 is integral in rotation with said nut, in particular by means of a mounting device which is reversible in order to facilitate mounting and replacing at least one element of the transmission system. Furthermore, the nut 7 is pivotally mounted inside the shell 6 in order to compensate for misalignments between the bearing and the drive shaft 5 during the advancement of the vehicle.

In particular, the bowl 4 can form a constant velocity joint (CVJ) of the Rzeppa type by providing a cage 8 provided with housings in which respectively a ball 40 is retained in rotation, said cage being mounted between the shell 6 and the nut 7 with each ball 40 disposed between two tracks 9, 10 respectively formed in said shell and said nut to guide the pivoting ensuring the rotational drive. In the embodiment shown in Figure 1, the rotating member 1 integrates the shell 6 in which the nut 7 is pivotally mounted. To do this, the bore 2 of the rotating member 1 has an annular bearing on which the raceways 9 are formed. Furthermore, the drive system comprises a sealing bellows 11 which has an end secured to the rotating member 1 and an end secured to the shaft 5 to protect the inside of the shell 6 of the external pollutants. Alternatively, the shell 6 may have reversible mounting means on the rotating member 1, said means being arranged to allow the transmission of a driving torque to said rotating member. In particular, the mounting means may comprise splines intended to be engaged in corresponding grooves of the rotating member 1.

The reversible mounting device of the shaft 5 on the nut 7 comprises complementary grooves 12a, 12b which are respectively integral with the shaft 5 and the nut 7, said grooves being engaged together to allow the transmission of a torque 7. In particular, the complementary grooves 12a, 12b may be helical and / or straight.

More specifically, the grooves 12a and the grooves 12b can be helical or straight. Alternatively, the grooves 12a may be helical or straight, the grooves 12b then being straight or helical. Indeed, the combination of complementary grooves 12a, 12b straight and helical is possible with a very small helix angle, for example from 10 'to 20', the assembly being made in force by eliminating the clearance between the grooves 12a, 12b. According to the embodiment shown, the shaft 5 comprises a free end portion 13 which has a bearing surface 14 on the periphery of which the grooves 12a are formed, said portion being mounted in a bore 15 integral with the nut 7 on which the grooves complementary 12b are formed. In the figures, the bore 15 is formed in the nut 7. Alternatively, it could be provided that the mounting device comprises a tip having a first end portion rotatably connected to the nut 7 and a second end portion. presenting the bore on which the grooves 12b are formed.

The reversible mounting device also comprises a thrust bearing 16 which is disposed between the shaft 5 and the nut 7, said stop being equipped with a locking sleeve 17 which is arranged to be able to present a locked position in which the balls 16 are constrained by said sleeve to prevent relative movement of the shaft 5 and the nut 7. Thus, the combination of complementary grooves 12a, 12b and the thrust bearing 16 allows the mounting of the shaft 5 on the nut 7 for its rotational drive by ensuring the axial attachment of said shaft relative to said nut. In particular, the mounting of the drive system can be achieved by relative translation between the shaft 5 and the nut 7 on an axial mounting stroke by engaging the complementary grooves 12a, 12b, the sleeve 17 being disposed in the locked position at the end mounting stroke.

In addition, the system can be disassembled by providing that the locking sleeve 17 is reversibly movable between its locked position and a mounting position in which the balls 16 are free to allow the relative movement of the shaft 5 and the nut 7 , in particular on a disassembly stroke in the opposite direction to that of the mounting stroke. In the embodiment shown, the bearing surface 14 of the free end portion 13 of the shaft 5 surrounds a bore 18 in which the locking sleeve 17 is mounted. In addition, the bearing surface 14 has through housings 19 in which respectively a ball 16 is retained in rotation. In particular, each housing 19 allows a radial clearance of the ball 16 between a retracted position and an outwardly projecting position, said housing having an inner seat 20 on which the ball 16 is internally retained so as not to fall into the bore 18. bushing 17 is mounted facing housing 19 to respectively block - the radial displacement of the balls 16 in said housing when said bushing is in the mounting position - respectively locked. To do this, the periphery of the bushing 17 has an alternating succession of high bearing surfaces 21 and low bearing surfaces 22, said bushing being movable in rotation to arrange the balls 16 on the low bearing surfaces 22 - respectively on the high bearings 21 - when said socket is in the mounting position - locked respectively. In the mounting position, the balls 16 are arranged in the retracted position on their seat 20 to allow movement of the free end portion 13 in the bore 15 on the mounting stroke. And, by rotation of the sleeve 17, the balls 16 are constrained in the projecting position by pressing on the high seats 21. In the figures, three balls 16 are provided to be arranged on bearing surfaces 21, 22 angularly separated by 120 °.

The reversible mounting device comprises a groove 23 secured to the nut 7 in which the balls 16 are stressed by the sleeve 17 to prevent relative axial displacement of the shaft 5 and the nut 7. In the embodiment shown , the groove 23 is formed in the bore 15 at the rear of the grooves 12b to, at the end of the mounting stroke, arrange the balls 16 in projecting position in the groove 23 by preventing the axial displacement of the shaft 5 by placing abutting balls 16 on the back of said flutes. Advantageously, the locking sleeve 17 can be constrained in its locked position by a spring means 24, said sleeve being movable against said spring means to be arranged in the mounting position. The high bearings 21 may have a diverging profile which is arranged so that traction on the sleeve 17 increases the plating of the balls 16 in the groove 23.

In particular, at the end of the mounting stroke - respectively before the disassembly stroke - the sleeve 17 can be pulled out of the bore 18 against the spring means 24, in particular by means of a plug 25, to be turned at an angle corresponding to the passage under the balls 16 of the low bearing surfaces 22 to the high bearings 21 - respectively of the high bearings 21 towards the low bearing surfaces 22 - and then returned to said bore by retraction of the spring means 24. In the illustrated embodiment , a helical spring 24 is disposed in the bore 18 by being hooked on either side respectively to a lock washer 26 which is fixed in the bore 18 and to the sleeve 17 of locking. Furthermore, the locking washer assembly 26 - spring 24 locking sleeve 17 is carried by a housing 27 which extends between said washer and said locking sleeve, said housing including facilitating assembly of said assembly in the bore 18. The washer 26 is mounted on a support 28 via a mandrel 29 and a retaining ring 30, said support having orifices 31 in which a pin 32 attached to the end of the spring 24 is mounted. . In addition, two low lands 22 of the locking sleeve 17 have a hole 33 for fixing a pin 34 integral with the other end of the spring 24.

Claims (11)

REVENDICATIONS1. A system for rotating a motor vehicle wheel, said system comprising: - a rolling bearing having a rotatable member (1) rotatably mounted relative to a fixed member via at least one row of rolling bodies, said rotating member comprising means (3a) for associating the wheel; - A transmission bowl (4) having a shell (6) integral in rotation with the rotating member (1) and a nut (7) pivotally mounted within said shell by rotating it; - A drive shaft (5) integral in rotation with said nut by means of a reversible mounting device; said system being characterized in that the reversible mounting device comprises complementary splines (12a, 12b) which are respectively integral with the shaft (5) and the nut (7), said splines being engaged with each other to allow the transmission a driving torque to the nut (7), said mounting device comprising a thrust bearing (16) which is disposed between said shaft and the nut, said stop being provided with a locking sleeve (17) which is movable reversibly between a locked position in which the balls (16) are stressed by said sleeve to prevent relative movement of the shaft (5) and the nut (7) and a mounting position in which the balls (16) are free to allow said relative displacement. 2. Drive system according to claim 1, characterized in that the shaft (5) has recesses (19) through which respectively a ball (16) is retained in rotation, the sleeve (17) being mounted opposite said housing to allow - respectively block - the radial displacement of said balls in said housing when said sleeve is in the mounting position - respectively locked. 3. Drive system according to claim 2, characterized in that the reversible mounting device comprises a groove (23) integral with the nut (7) in which the balls (16) are stressed by the sleeve (17). to prevent relative axial displacement of the shaft (5) and the nut (7). 4. Drive system according to claim 2 or 3, characterized in that the periphery of the sleeve (17) has an alternating succession of high spans (21) and low spans (22), said sleeve being movable in rotation to arranging the balls (16) on the low seats (22) - respectively on the high seats (21) - when said sleeve is in the mounting position - respectively locked. 5. Drive system according to any one of claims 2 to 4, characterized in that the shaft (5) has a bearing surface (14) surrounding a bore (18), the locking sleeve (17) being mounted in said bore and the housings (19) being formed in said span. 6. Drive system according to any one of claims 1 to 5, characterized in that the sleeve (17) lock is constrained in its locked position by a spring means (24), said sleeve being movable against said spring means to be arranged in the mounting position. 7. Drive system according to any one of claims 1 to 6, characterized in that the shaft (5) comprises a free end portion (13) having a bearing surface (14) on the periphery of which the grooves (12a) are formed, said portion being mounted in a bore (15) integral with the nut (7) on which the complementary grooves (12b) are formed. 8. Drive system according to claim 7 when dependent on claim 2, characterized in that the groove (23) is formed in the bore (15) at the rear of the grooves (12b). 9. Drive system according to claim 7 or 8, characterized in that the bore (15) is formed in the nut (7). 10. Drive system according to any one of claims 1 to 9, characterized in that the complementary grooves (12a, 12b) are helical and / or straight. 11. Drive system according to any one of claims 1 to 10, characterized in that the rotating member (1) incorporates the shell (6) in which the nut (7) is pivotally mounted.