FR3076334A1 - CLUTCH PULLEY ASSEMBLY WITH IMPROVED IMPACT LIMITING - Google Patents

Abstract

The invention relates to an alternator pulley assembly (1; 20) comprising a pulley (10; 50) comprising an outer surface (10a) for a belt and an inner surface (10b; 56) delimiting a through opening along an axis X. The pulley assembly further includes a hub (11; 22) extending along the X axis in the opening and a movable support (122; 73) rotatably along the x axis relative to the pulley (10; 50) and the hub (11; 22) between a compressed position and an extended position. The assembly further comprises an abutment plate (39; 111) integral in rotation with the hub (11) comprising a base having a friction face (111D) opposite a friction face (122D) of the mobile support (122). The assembly includes an end stop (122A) extending axially from a friction surface (122D) of the base of the movable support or the base of the abutment plate and e in that the contact face of the movable or fixed end stop comprises a bevelled surface (122A1) in a plane such that the angle between the plane of the contact surface and a plane comprising the X axis passing the bevelled surface is at least 3 °.

Description

Clutch pulley assembly with improved shock limitation

TECHNICAL AREA

It is known a pulley assembly driven by a belt by a motor vehicle engine to transfer part of the mechanical power from the engine to an accessory or to give torque to the heat engine. It is known that several accessories are connected by the same belt. Typically, each accessory comprises an input drive shaft comprising a distal end connected to a hub shaft of a pulley assembly comprising a pulley driven by the belt. An example of such a belt driven accessory is an alternator.

It is also known to provide a freewheel clutch pulley assembly for decoupling and coupling the pulley with the alternator drive shaft to allow the alternator drive shaft to rotate at a speed slower and faster than the pulley due to the oscillations of the pulley speed due to the oscillations in the engine speed.

The invention relates to an improved clutch pulley assembly.

STATE OF THE ART

An example of a freewheel clutch pulley assembly is described in patent EP 1534972 B1. FIG. 2 shows a known pulley assembly 20, comprising a hub shaft 22 comprising an axis X. The hub shaft 22 comprises a first end 24 and a second end 26 axially opposite and a body 28 extending between the two ends, comprising an axial groove not visible in FIG. 2 on the side of its second end 26. A drive shaft of a rotor is intended to be mounted inside the hub shaft by threading.

The assembly includes a bearing 36 mounted on a portion of the hub on the side of the first end and is intended to be mounted on the drive shaft.

The assembly further comprises a pulley 50 mounted on the bearing and surrounding the hub shaft up to the second end 26. The pulley comprises an internal surface 56 surrounding the hub.

The pulley assembly 20 comprises a unidirectional clutch assembly 70 housed between the hub 22 and the pulley 50. The clutch assembly 70 comprises a helical clutch spring 71 and a support 75. The clutch spring 71 is adjusted by pressure in frictional engagement with the internal surface 56 of the pulley 50. The support 75 is rotatably mounted on the hub 22 and is made of plastic comprising kevlar or teflon. The support 75 comprises a hook slot not visible in FIG. 2 on a radial surface 751 configured to retain a proximal hook end 73 of the clutch spring 71. The support 75 further comprises a second slot not visible in FIG. 2 , on the radial face 751, generally helical.

The pulley assembly comprises a second spring called a helical torsion spring 90 which extends between the hub 22 and the slot on the radial face 751 of the support 75. The torsion spring 90 is compressed axially between the support 75 and the groove of the core to transfer the torque between the hub 22 and the support 75.

The pulley assembly further comprises a thrust washer mounted integrally on the hub on the side of the first end 24. The axial forces due to the compression of the torsion spring 90 hold the support 75 in abutment against the thrust washer 39. The torsion spring 90 also allows relative movement between the support 75 and the hub 22 to adapt to changes in the speed of the pulley 50 due to generally oscillating changes in the operating speed of the engine. The torsion spring 90 and the clutch spring 71 are wound in opposite directions.

In operation, the heat engine 10 visible in Figure 1 is started and the pulley 50 is accelerated and rotated in a direction driven by the belt 14 driven by the motor 10. The acceleration and rotation of the pulley 50 in the steering driven relative to the hub 22 produces friction between the internal surface 56 of the pulley 50 and the clutch spring 71.

When the clutch spring 71 is fully engaged with the internal surface 56, the rotation of the pulley 50 rotates the support 75 in the driven direction which transfers the torque to the hub 22 by the torsion spring 90 so that generally the support 75, the thrust washer 39, the hub 22, and the drive shaft 15 of the accessory 16 driven by belt rotate with the pulley 50. In addition, the torsion spring 90 resiliently allows movement relative between the support 75 and the hub 22 to adapt to the oscillations of the speed of the pulley 50 due to the corresponding oscillations of the operating speed of the motor 10.

When the pulley 50 decelerates, the hub 22 driven by the inertia of the rotating drive shaft having a certain mass, turns inside the accessory 16 and continues to turn in the driven direction at a higher speed than the pulley 50. More precisely, the higher speed of rotation of the hub 22 with respect to the pulley 50 means that the clutch spring 71 contracts radially with respect to the internal surface 56 of the pulley 50. The spring clutch 71 can remain in friction engagement with the internal surface 56 while the pulley 50 decelerates relative to the clutch assembly 70 and to the hub 22. The turns of the clutch spring 71 begin to expand again against the surface internal 56 when the pulley 50 accelerates beyond the speed of the hub 22.

Such a pulley assembly therefore makes it possible to absorb, with the torsion spring, shocks which are due to the acyclisms of the heat engine causing changes in speed.

The torsion spring and the clutch spring are calibrated for a certain threshold of torque absorption and speed difference.

In the event of operation beyond one of these thresholds, the torsion spring can deform either by compressing whorl against whorl and compressing beyond its threshold of use or either by extending and pushing axially the thrust washer 39 by means of the support 75 which could damage the support or have the thrust washer 39 torn off. Such movement of the spring 90 can therefore cause excessive wear of the support or of the torsion spring and cause the assembly to fail .

Patent EP1692409 proposes a pulley assembly, the support 75 of which includes a radial or circumferential stop with the thrust washer. This makes it possible to limit the deformation of the torsion spring 75 whether it is compressing or stretching. After a predetermined threshold of use of the tension spring, the stop of the support 75 comes into contact with a stop of the thrust washer making it possible to transfer the torque, beyond the torque absorbed by the torsion spring 75, by the stops .

However, the mobile end-of-rotation stop can damage the friction surface of the support stop 75 when it leaves its housing in the event of an impact. In effect, the mobile support can move axially and by shock effect the mobile support can move towards the shoulder 22 of the hub and rotate, resulting in an exit from the fixed stop. This can also happen by moving back the support stop 75 which is mounted on the hub by deformation.

The invention improves the wear problem in the event of an impact while facilitating its manufacture and therefore its cost.

The invention therefore relates to a pulley assembly comprising a mobile support comprising a mobile end of rotation stop and a stop plate comprising a fixed end of rotation stop and in that the contact face of the mobile or fixed end of rotation stop rotation includes a beveled surface in a plane such that the angle between the plane of the contact surface and a plane comprising the axis X passing the beveled surface is at least 3 °.

The invention therefore relates to a pulley assembly for an alternator comprising:

• a pulley comprising an external surface for a belt and an internal surface delimiting a through opening along an axis X, • a hub extending along an axis X in the opening, • a support movable in rotation along the axis x by relative to the pulley and the hub between a compressed position and an extended position, the movable support comprising a base comprising a torsion stop, • a helical clutch spring mounted in the opening in contact with the internal surface and comprising one end integral in rotation with the mobile support, • a torsion spring comprising:

i. a movable end in contact with the torsion stop and ii. a hub end integral in rotation with the hub, • a stop plate integral in rotation with the hub comprising a base having a friction face facing a friction face of the movable support, and in that in position d extension of a contact face of the mobile end of rotation stopper is in contact with a contact face of the fixed end of rotation stopper, • an end of rotation stopper extending axially from a friction surface of the base of the mobile support or the base of the stop plate and in that the stop plate or the mobile support respectively comprises a housing in which the added stop is housed, characterized in that the contact face of the mobile stop or fixed end of rotation comprises a surface beveled in a plane such that the angle between the plane of the contact surface and a plane comprising the axis X passing the beveled surface is at least 3 °.

This makes it possible to limit, during the impact between these two faces, an effect of axial force of repulsion, resulting in a risk that the mobile end of rotation stop or the fixed end of rotation stop will come out of its housing.

According to one embodiment, the surface is bevelled at an angle of less than 87 ° relative to the surface of strongly from which the end of rotation stop extends radially.

This provides an axial pulling effect between the stop plate and the movable support reducing the risk of the stop coming out of its housing.

According to one embodiment, the surface is bevelled at an angle less than 87 ° relative to a surface of the abutment opposite the axis of rotation, the surface is bevelled at an angle less than 87 ° by relative to a circumferential surface (122G) of the movable support (122) around the axis of rotation.

This makes it possible to accentuate the impact forces radially by reducing the impact forces axially, thereby limiting the risk that the stopper will come out of its housing axially.

Of course, the contact surface can also be inclined so as to have an angle of less than 87 ° relative to the strongly surface from which the end of rotation stop extends radially.

According to one embodiment, the stop comprises a dovetail shape forming at each of its sides inclined contact surfaces.

According to one embodiment, the end of rotation stop is added fixed to the base of the mobile support or to a base of the stop plate and in that the stop plate or the mobile support respectively comprises a notch forming the housing in which the attached stopper is housed.

This is to prevent the end of rotation stop from wearing out quickly. Indeed, this makes it possible to have an end of rotation stop having a hardness greater than the material of the base forming the torsion stop of the torsion spring. Indeed, the stop in contact with the torsion spring is biased according to a predetermined threshold which is not the case for the angular stop.

The end of rotation added stopper is of course made of a material having better impact resistance than the material of the base on which the added stopper is fixed. For example the end of rotation stop is of the same material as the base but has undergone a heat treatment making it more rigid than the base.

According to one embodiment, the added stop is fixed by being mounted tight on one of the two bases. In other words, one of the two bases includes a notch in which the added stop is mounted.

According to another embodiment, the added stop comprises a dovetail shape and the base comprises a notch of complementary shape in dovetail.

According to one embodiment, the notch forms a stop at the end of clockwise rotation and a stop at the end of counterclockwise rotation and in that the two stops have an oblique contact surface complementary to the beveled surface of the end stop. of rotation.

According to one embodiment, the mobile support comprises a notch forming two mobile angular end-of-rotation stops, and in that the stop plate comprises the reported end-of-rotation stop, called in the following mobile end-of-rotation stop, mounted on the base of the stop plate projecting radially with respect to the movable friction face, the movable support therefore being angularly movable between its two fixed end of rotation stops.

According to an example of the two previous embodiments, the pulley assembly comprises two reported end-of-rotation stops, an added stop is mounted on the base of the mobile support and the other added stop is mounted on the base plate.

According to one embodiment, the added stop is metallic. Having an attached stopper can be inexpensive while having good impact resistance.

According to one embodiment, the base is metallic and the reported end-of-rotation abutment has undergone a heat treatment making it possible to withstand impact better than the mobile support. The base may be the base of the movable support or the base of the stop plate. For example, the mobile support is metallic. In the case where the mobile end-of-rotation stop is additionally attached to the base of the mobile support, the mobile end-of-rotation stop has undergone a heat treatment making it possible to withstand impact better than the base of the mobile support.

This makes it possible to have a friction surface of the mobile support facing the stop plate comprising a coefficient of friction lower than the surfaces of the mobile end stop of rotation which has undergone a heat treatment to withstand shocks . In the case where the mobile end of rotation stop comes from material (monobloc) with the base of the mobile support (in this case it is the stop plate for example formed by a shoulder of the hub which includes the end stop insert rotation), the heat treatment may involve an increase in the coefficient of friction of this radial friction surface which comes into friction against a radial friction surface of the shoulder. Friction wears out surfaces and produces heat, but also reduces the efficiency of the device.

According to one embodiment, the end of rotation stop extends from a friction face of the mobile support forming a mobile end of rotation stop and in that the stop plate comprises a notch forming the housing of the mobile end-of-rotation stop and forming the fixed end-of-clockwise stop and the fixed end-of-counter-clockwise stop.

According to one embodiment, the pulley assembly further comprises a fixed support mounted integral in rotation on the hub, the fixed support comprising a torsion stop in abutment against the end integral in rotation with the torsion spring, and in that the stop plate is formed by a radial shoulder of the hub on its first end.

• The shoulder therefore includes a fixed end-of-rotation stop for the mobile support, and • the mobile support includes a mobile end-of-rotation stop, in which in the extended position the mobile end-of-rotation stop is in contact with the fixed end stop of rotation of the hub shoulder.

The added stop can therefore be either attached to the shoulder or to the movable support or to both as described in previous embodiments. According to one example, a notch can be formed in the shoulder forming two fixed end-of-rotation stops and the added stop is mounted on the mobile support.

Thus, the fixed part which undergoes the most torsion is part of the hub. In fact, in this embodiment, the shoulder serves as an axial abutment washer but also as an angular abutment at the end of rotation and is part of the hub, in other words it is made of material with the hub. The shoulder which comprises a fixed end-of-rotation stop for the mobile support therefore comprises a tear resistance greater than that of a support fixed to the hub because the fixed end-of-rotation stop comes from a shoulder. of the hub and therefore comes from material of the hub. The stresses of the torsion spring on the support fixed to the hub are limited to the stresses of the torsion spring when the mobile support comprises its mobile end of rotation stop against the fixed end of rotation stop of the shoulder of the hub. Thus the stresses on the fixed support are predetermined. It follows that there is little risk of tearing or premature wear of the fixed support or the shoulder.

Furthermore, in the prior art, the hub includes a groove which is in contact with the torsion spring. This groove is also more difficult to machine than the shoulder of the invention which can be produced by machining but also by molding or striking. In addition, the shoulder does not cause or causes less loss of material compared to the groove machined on the hub in the prior art.

In addition, there is even less risk than in the event of an impact that the shoulder moves leaving more play in the mobile support and therefore a risk that the mobile end of rotation stop comes out of its housing.

Thus, the invention makes it possible to have a pulley assembly which is more reliable, more robust and simpler to manufacture than that of the prior art.

According to one embodiment, at least one groove opens onto the notch forming the housing of the mobile end-of-rotation stop. This allows when the movable end of rotation stop moves to achieve a grease pumping effect located in the notch towards the groove to supply the groove with fat.

According to one embodiment, the pulley assembly further comprises grease supplied between the friction face of the stop plate and the friction face of the movable support and in that at least one of the two friction faces comprising grooves to form fat reservoirs. According to one example, the two radial friction faces include grooves for producing grease reservoirs.

This reduces friction between the two surfaces to reduce heat and wear in a simple way. In addition, such a reserve makes it possible to increase the efficiency of the pulley assembly (mechanical power of the pulley towards the mechanical power of the hub). This reduction in friction increases the average mechanical power received at the hub. Thus for an alternator, this reduces the current sent to the rotor and therefore a reduction of CO2 for the car.

According to one embodiment, at least one groove opens onto the notch forming the housing of the mobile end-of-rotation stop. This allows when the movable end of rotation stop moves to achieve a grease pumping effect located in the notch towards the groove to supply the groove with fat.

According to one embodiment, the pulley assembly further comprises a washer, of plastic having a friction face having a lower coefficient of friction than a radial face of the base of the movable support on the side of the stop plate or / and of a radial face of the base of the stop plate on the side of the mobile support, molded on the base respectively of the stop plate and / and of the mobile support.

The invention also relates to an electric machine comprising the function of an alternator for a motor vehicle comprising a rotor and a pulley assembly according to one of the embodiments, the hub of which is mounted in rotation with one end of the rotor.

The invention and its various applications will be better understood on reading the description which follows and on examining the figures which accompany it.

BRIEF DESCRIPTION OF THE FIGURES

These are presented for information only and in no way limit the invention. The figures show:

- Figure 1, already described, shows a diagram of an engine assembly driving an accessory with a belt;

- Figure 2 shows an exploded pulley assembly according to the prior art;

FIGS. 3 and 4 show an exploded view of a pulley assembly according to an example of the invention.

- Figure 5 shows an example of a hub of a belt assembly according to the invention.

- Figure 6 shows a three-dimensional view of an example of a movable support of a belt assembly according to the invention.

- Figures 7a and 7b show a three-dimensional view and a view perpendicular to the axis X of another example of a mobile support of an embodiment of a belt assembly according to the invention

- Figures 8a and 8b show a view perpendicular to the X axis and a view of the X axis of another example of a mobile support of an embodiment of a belt assembly according to the invention

FIG. 9 represents a three-dimensional view of an example of a fixed support of an embodiment of a belt assembly according to the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

The various elements appearing in several figures will have kept, unless otherwise specified, the same reference.

Figure 4 shows an exploded three-dimensional view of a belt assembly 1 according to the invention.

The pulley assembly for alternator comprises a pulley 10 comprising an external surface 10a for a belt 14 and an internal surface 10b delimiting a through opening along an axis X.

The external surface includes ridges so that it can be driven by the belt 14.

The pulley assembly further includes a hub 11 which also extends along the X axis in the opening. In other words, the pulley 10 surrounds at least part of the hub 11.

This hub is intended to be mounted integral in rotation at least in the direction of rotation of drive from the pulley 10 to the hub 11 explained later. This direction of drive rotation can be clockwise or counterclockwise by looking in the axis of the pulley side, that is to say that the accessory is located behind the pulley assembly.

The pulley assembly also includes a clutch assembly 12 mounted between the pulley 10 and the hub 11 for coupling them in rotation in the direction of drive rotation. The clutch assembly 12 includes a coil clutch spring 121 hereinafter called the clutch spring 121, and a movable support 122. The movable support 122 is movable in rotation along the axis x relative to the pulley and the hub. between a compressed position and an extended position at an angle, for example 120 °. Thus, the mobile support does not rotate 360 ° but is locked in rotation. The mobile support 122 therefore comprises a mobile end of rotation stop 122A. The mobile end of rotation stop 122A protrudes in this case from a friction surface 122D of the mobile support. In this case, the turns of the clutch spring are of rectangular section. The movable support 122 comprises, axially opposite the friction surface 122D, a hooking notch 122B visible in FIG. 6 representing an embodiment of the movable support 122. The clutch spring 121 therefore comprises one end latching 121B located in the notch of the spring 122B. The clutch spring 121 is therefore mounted in the opening of the pulley and at its other end (not shown) in contact in the rest position and in the engaged position with the internal surface 10b.

Thus when the pulley 10 starts to rotate in the direction of rotation of the drive, the clutch spring 121 is rotated by friction with its end possibly being a turn or more. The clutch spring 121 is wound and positioned in the pulley in the direction allowing it to extend by centrifugal force in the direction of rotation. On the contrary, when the movable support 122 rotates faster than the pulley, the clutch spring 121 is compressed and its turns are unstuck so that there is more friction or not enough friction to drive the pulley 10 in rotation.

The mobile support 122 also comprises a torsion stop 122C visible also in FIG. 6 from the side of the hooking notch 122B. In this example, the mobile support comprises a ring 1221 projecting axially from a base 122F of the mobile support surrounding a torsion contact surface 122J of this base 122F. This torsional contact surface is in the form of a spiral. The attachment notch 122B is located in this example by passing through the ring 122i which is therefore open at the level of the notch and ends on the torsion contact surface of the base 122f having the greatest thickness, that is to say where the ring 122i has the least axial length relative to the torsion contact surface 122J.

This ring 1221 acts as a center for the clutch spring 121.

The pulley assembly 1 further comprises a torsion spring 13 comprising a movable end 13C in contact with the torsion stop 122C and a hub end integral in rotation with the hub 11. The torsion spring can be mounted prestressed between the fixed support and the mobile support in the extended position. The torsion spring 13 is mounted inside the clutch spring. This saves axial space.

The pulley assembly 1 comprises a fixed support 15 also shown in FIG. 9, mounted integral in rotation on the hub 11. The fixed support 15 comprises a torsion stop 15A, also called angular torsion stop, abutting against the end integral in rotation with the torsion spring 13. In this example, the fixed support 15 is tightly mounted on the hub 11, in this case on a shoulder 115 of the hub but can also be screwed with brake or welded, or by means of '' a bayonet type notch. The fixed support comprises a contact surface 15B of the torsion spring. In this example, the contact surface has a spiral or helical shape. The fixed support 15 further comprises a ring 15C extending axially projecting from the contact surface 15B for centering the torsion spring.

The fixed support could also, as in FIG. 2, be a shoulder of the hub.

The pulley assembly further comprises a stop plate 111, integral in rotation with the hub 11 comprising a base having a friction face 111D facing a friction face 122D of the movable support 122. The stop plate in this example is formed by a radial shoulder of the hub on its first end but could also be a washer mounted tightly on the hub as in FIG. 2.

The end of rotation stop will now be described in more detail.

The end of rotation stop 122A therefore extends axially from the friction surface 122D of the base 122F of the movable support but could also extend from the base of the stop plate which is in this embodiment shoulder 111 In this example the shoulder comprises a notch 1111 forming the end of rotation stop 111A but of course the movable support could have this notch in which a stop projecting axially from the stop plate would be housed.

Thus in the position of extension of the mobile support, a contact face of the mobile stop 122A at the end of mobile rotation is in contact with a contact face of the fixed stop at end 111 D.

The notch 1111 therefore forms two fixed end-of-rotation stops 111A, a fixed end-of-clockwise stop and a fixed end-of-counter-clockwise stop.

The mobile end-of-rotation stop 122A of the mobile support 122 is in contact against the fixed end-of-rotation stop extension 111A (which may be the fixed end-of-clockwise or counter-clockwise stop). The shoulder 111 therefore includes a radial friction face 111D against which the friction face 122D of the movable support 122 is pressed.

According to another embodiment not shown, the movable support 122 comprises the notch forming two movable stops at the end of rotation, a movable stop at the end of clockwise rotation and a movable stop at the end of counterclockwise rotation and the hub then comprises a fixed stop which extends from the radial friction face opposite the radial friction face of the movable support.

In these two embodiments, the end of rotation stop which extends axially from a friction face is housed in the notch forming a housing for this radial stop.

The shoulder 111 can be produced by machining but also by molding or striking.

The torsion spring 13 therefore makes it possible to transfer the rotation of the mobile support 122 to the hub and vice versa when the mobile support 122 rotates between the extension position and the compression position. This allows to dampen the acyclisms of the heat engine.

The movable torsion stop 122C can comprise a surface having an axial depth making it possible to compensate for the play of the torsion spring 13 when it is compressed in the case where the movable support 122 does not move axially.

During a rotation beyond the damping of the torsion spring this can cause a shock between the mobile end of rotation stop 122A and the fixed end of rotation stop 111A.

The shoulder 111 therefore acts as an axial stop for the mobile support 122 as well as a radial stop for the mobile support 122. Thus, in the extension position of the torsion spring, the mobile end of rotation stop 122A is in contact with the stop. fixed end of rotation 1.

FIG. 4 includes arrows in bold representing the path of the torque from the pulley 10 to the hub 11. Thus it can be seen that the torque from the pulley 10 is transferred to the clutch device 12 by means of the clutch spring 121 which retransmits by its hooking end to the mobile support 122 then the torque is transmitted successively to the torsion spring 13 by its end 13C then to the fixed support 15 and finally to the hub 11. In the case of a higher speed of the hub, the path reverses except in that the clutch spring retracts due to its winding and no longer transfers the torque to the pulley if the turns are no longer in contact or transfers little torque with friction of the torque to the pulley. 11A of the shoulder 111 of the hub 11.

In FIG. 6, the contact surface of the movable contact stop 122A is not very clearly distinguished.

FIG. 7a represents a portion of the mobile support 122 comprising the mobile end of rotation stop 122A extending axially according to one embodiment. In this example, we can see that the mobile end of rotation stop

122A includes a beveled surface on the contact face of the movable stop

122A1 in a plane such that the angle between the plane of the contact surface and a plane including the X axis passing the beveled surface is at least 3 °.

In FIG. 7b, it can be seen that the contact abutment surface 122A1 is inclined by a bevel at an angle a less than 90 ° for example between 45 ° and 87 ° relative to the surface of strongly 122D from which the end of rotation stop extends radially.

In this example, the mobile end of rotation stop 122A is made of one piece with the base 122F but could be added.

According to another example of the invention shown in FIG. 8b, the contact abutment surface is bevelled such that an angle β between a circumference surface 122G of the mobile support 122 and the beveled contact abutment surface 122A1 is less than 87 °. The circumference surface being circular, we take the tangent to the point of intersection on the circumference surface 122G. Figure 8a shows the same view as the example in Figure 7b but with the example in Figure 8b.

According to another example shown in FIG. 8b, the contact abutment surface is bevelled such that an angle β between a circumference surface 122G of the mobile support 122 and the beveled contact abutment surface 122A1 is less than 87 °. The circumference surface being circular, we take the tangent to the point of intersection on the circumference surface 122G. Figure 8a shows the same view as the example in Figure 7b but with the example in Figure 8b.

In this example, the mobile end of rotation stop 122A is attached to the base 122F but could also be made of material.

According to another example not shown, the contact surfaces of the end of rotation stops are both inclined relative to the friction surface of the movable support opposite the shoulder of the hub such that the angle between the radial friction surface and the beveled surface of the movable stop is less than 87 ° and both beveled such that the angle between the surface forming the circumference of the movable support and the beveled contact surface is less than 87 °.

According to another example not shown, the contact surface of the end-of-rotation stops are both inclined relative to the friction surface of the movable support opposite the shoulder of the hub such that the angle between the radial friction surface and the beveled surface of the movable stop is less than 87 ° and both beveled such that the angle between the surface forming the circumference of the movable support and the beveled contact surface is less than 87 °.

The mobile end-of-rotation stop in this example forms a dovetail forming at each of its sides inclined contact surfaces.

The contact surfaces of each of the fixed end-of-rotation stops of the notch 1111 of the shoulder 111 may comprise an inclined surface corresponding to the contact surfaces of the mobile end-of-rotation stop 122A. According to another example, the contact surface of the fixed stop 111 A of the notch 1111 can be perpendicular to the friction surface 111 D. In this case, at each impact, the contact surface of the stop of the notch may deteriorate so as to correspond over time to the inclined surface of the movable stop 122A.

In this example, the mobile end of rotation stop 122A is metallic. In particular, the movable stop 122A is attached to a base 122F of the movable support 122. In this example, preferably the attached stop 122A comprises a hardness greater than the material of the base 122F.

For example, the added stop 122A is fixed by being mounted tightly on the base 122F, that is to say is mounted in a notch in the base. In particular the added stop 122A comprises a dovetail shape and the base includes a notch of complementary shape in dovetail whose angle can be between 91 and 96 °.

In this example shown, the mobile support 122 is metallic. In the case where the mobile end-of-rotation stopper 122A is also attached to the base of the mobile support 1222, the mobile end-of-rotation stopper 122A has undergone a heat treatment making it possible to withstand impact better than the base 122F of the mobile support .

In this example shown, the pulley assembly 1 comprises grease, not shown, situated between the friction face 122D of the movable support 122 and the friction face 111D of the shoulder 111. The surface of the friction face 111D of the hub comprises , in this example shown in Figure 5, in particular grooves 111D1 to form a reserve of grease. In this case, three cylindrical grooves around the axis X and an axial depth in the form of a V. In particular, one of the grooves 111D1 opens onto the notch 111, therefore onto the housing of the mobile end of rotation stop 122A. This allows when the movable stop 122A moves to achieve a pumping effect of the fat located in the notch towards the groove 111D1 to supply the groove with fat.

According to another example, the grooves are on the radial friction face of the movable support (122).

According to another example not shown, a plastic washer mounted between the two radial surfaces of the base of the movable support and the shoulder. The washer can for example be overmolded on the base 122F of the mobile support.

In the case of a mobile end-of-rotation stopper added to the base of the mobile support, overmolding on the base can be carried out before mounting the added stopper.

In another example not shown, the washer is molded onto a base of the shoulder. In this case, the overmolded washer forms a friction surface of the shoulder, the base of which comes from the material with the hub. So we always limit the risk of tearing and the fixed end of rotation stop is always part of the hub.

The pulley assembly 1 further comprises in this example, a washer 17 forming a bush located radially between the fixed support and the internal surface 10b of the pulley. The washer 17 socket can be made of brass or plastic and can be mounted with radial clearance to form the bearing between the fixed support and the pulley.

The washer 17 is for example mounted tight against the internal face of the pulley 10 forming its opening and is situated in a groove 15D on a circumferential surface of the fixed support 15. This makes it possible to maintain the pulley 10 axially with the hub 11.

The pulley assembly 1 further comprises in this example a bearing 18 of the ball or roller bearing type comprising its external part mounted tightly in the internal surface 10b of the pulley and its internal part mounted tightly around a surface of the hub. 11 and in axial abutment against a radial surface of the shoulder 111 opposite to the friction surface 111D of the shoulder 111.

The pulley assembly 1 further comprises in this example a cover 19 closing the opening of the pulley 10 making it possible to prevent foreign bodies such as dust from entering at the level of the bush 17.

In this example, the hub comprises an internal surface forming a shaft housing for receiving the shaft of the accessory 15. In this example, the internal surface comprises teeth to be force fitted on the shaft of the accessory . Of course, the pulley assembly may also have an adapter, not shown, mounted in this shaft housing or around the hub.

The invention also relates to an electric machine comprising the function of an alternator for a motor vehicle comprising a rotor and a pulley assembly 1, the hub 11 of which is rotatably mounted on one end of the rotor.

Of course, the invention is not limited to the embodiments which have just been described.

The present invention has been described and illustrated in the present detailed description and in the figures of the appended drawings, in possible embodiments. The present invention is not limited, however, to the embodiments presented. Other variants and embodiments can be deduced and implemented by a person skilled in the art on reading this description and the attached drawings.

In the claims, the term include or include does not exclude other elements or other steps. The various features presented and / or claimed can be advantageously combined. Their presence in the description or in different dependent claims does not exclude this possibility. The reference signs should not be understood as limiting the scope of the invention.

Claims (10)

claims 1. Pulley assembly (1; 20) for alternator comprising: • a pulley (10; 50) comprising an external surface (10a) for a belt and an internal surface (10b; 56) delimiting a through opening along an axis X, • a hub (11; 22) extending along the axis X in the opening, • a mobile support (122; 73) rotating along the axis x with respect to the pulley (10; 50) and the hub (11; 22) between a compressed position and an extension position, the mobile support (122; 73) comprising an angular torsion stop (15A), • a helical clutch spring mounted in the opening in contact with the internal surface and comprising an end integral in rotation with the mobile support, • a torsion spring comprising: i. a movable end in contact with the torsion stop and ii. a hub end integral in rotation with the hub, • a stop plate (39; 111) integral in rotation with the hub (11) comprising a base having a friction face (111 D) opposite a face of friction (122D) of the mobile support (122), • an end of rotation stop (122A) extending axially from a friction surface (122D) of the base of the mobile support or of the base of the stop plate and in that respectively the stop plate (39, 111) or the mobile support (122) comprises a housing in which the added stopper is housed, and in that in the extended position a contact face of the mobile stopper (122A) at the end of mobile rotation is in contact with a contact face of the fixed end of rotation stop (111D), characterized in that the contact face of the mobile or fixed end of rotation stop comprises a bevelled surface (122A1) in a plane such that the angle between the plane of the contact surface and a plane including the X axis passing the beveled surface is at least 3 °. 2. The assembly of claim 1 wherein the surface (122A1) is bevelled at an angle of less than 87 ° relative to the surface of strongly (122D; 111 D) from which the end of rotation stop extends radially. 3. The assembly of claim 1 or 2 wherein the surface is bevelled at an angle less than 87 ° relative to a circumferential surface (122G) of the movable support (122) around the axis of rotation. 4. An assembly according to one of claims 1 to 3, wherein the end of rotation stop (122A) comprises a dovetail shape forming at each of its sides inclined contact surfaces. 5. Assembly according to one of claims 1 to 4, wherein the end of rotation stop (122A) is attached fixed on the base of the movable support or on a base of the stop plate and in that respectively the plate stop (111) or the movable support comprises a notch (1111) forming the housing in which the added stop is housed. 6. The assembly of claim 5, wherein the notch (1111) forms a stop end of clockwise rotation and a stop end of counterclockwise rotation and in that the two stops have a complementary oblique contact surface with the beveled surface of the end of rotation stop. 7. The assembly of claim 6, wherein the end of rotation stop (122A) extends from a friction face of the movable support forming a movable end of rotation stop (122A) and in that the plate stop (111) comprises a notch (1111) forming the housing of the mobile end of rotation stop and forming the fixed end of clockwise end stop and the fixed end of counterclockwise end stop. 8. Pulley assembly according to any one of the preceding claims, further comprising a fixed support (15) mounted integral in rotation on the hub (11), the fixed support comprising a torsion stop in abutment against the end integral in rotation of the torsion spring, and in that the stop plate is formed by a shoulder (111) radial of the hub (11) on its first end. 5 9. Assembly according to one of claims 1 to 8, further comprising grease supplied between the friction face (111 D) of the stop plate (111) and the friction face (122D) of the movable support and in that at least one of the two friction faces includes grooves to form grease reservoirs. 10. Electric machine comprising the function of an alternator for a motor vehicle comprising a rotor and a pulley assembly according to one of the preceding claims, the hub of which is mounted in rotation with one end of the rotor.