FR3065522A1 - ROTARY DEVICE EQUIPPED WITH A TARGET AND METHOD OF MANUFACTURING SUCH A DEVICE - Google Patents

Abstract

The invention relates to a device for a transmission chain of a motor vehicle comprising: - a rotary element intended to be mounted in rotation about an axis of rotation X; and a target (4) intended to be arranged facing a sensor capable of delivering a signal representative of the angular position and / or the speed of the target (4), the target (4) being fixed on the rotary element and comprising: - a flange (5) which has a radial orientation; and - an annular ring (6) which extends axially from the flange (5), and is arranged circumferentially around a cylindrical skirt of the rotary member, the annular ring (6) having a plurality of windows (7, 19) separated by fingers (8), the annular ring (6) having undulations (10) which are directed radially inwards towards the cylindrical skirt and which are adapted to bear radially inwardly against the cylindrical skirt of the rotary member so as to limit the deformation of the annular ring (6).

Description

Technical area

The invention relates to the field of motor vehicle transmission chains and relates more particularly to a device of a motor vehicle transmission chain which is equipped with a target intended to be placed opposite a sensor.

Technological background

Document DE102011102001 discloses a primary flywheel of a double shock-absorbing flywheel equipped with a target. The target has a flange of radial orientation which is fixed against the primary flywheel and a plurality of fingers which extend axially from the external periphery of the flange, all around a cylindrical skirt of the primary flywheel. Thus, when the double damping flywheel is driven in rotation, the fingers generate variations in the magnetic field capable of being detected by a sensor positioned opposite the target. Such a sensor is thus capable of delivering a signal representative of the angular position and / or of the speed of the target. The distal end of each of the fingers is deformed radially inwards so as to bear against the cylindrical skirt of the primary flywheel. This prevents the fingers from deforming radially inward, for example when transporting the primary flywheel. However, such a target is not entirely satisfactory. Indeed, the fingers are liable to deform outward when they are subjected to significant centrifugal forces. In addition, although the fingers are in abutment against the cylindrical skirt of the primary flywheel, they are still liable to deform, in particular in the circumferential direction, during the transport of the double damping flywheel.

However, it is important that an accuracy of the geometry of the fingers is ensured and that the risks of deformation of the fingers are limited so as not to degrade the accuracy of the signal delivered by the sensor.

summary

One idea underlying the invention is to propose a device for a motor vehicle transmission chain, equipped with a target intended to be placed facing a sensor and in which the risks of deformation of the target are limits.

According to one embodiment, the invention provides a device for a motor vehicle transmission chain comprising:

- A rotary element intended to be mounted in rotation about an axis of rotation X, the rotary element comprising a cylindrical skirt of axial orientation; and

a target intended to be placed opposite a sensor capable of delivering a signal representative of the angular position and / or of the speed of the target, the target being fixed on the rotary element and comprising:

- a flange which has a radial orientation; and

- An annular ring which extends axially from the flange, and is arranged circumferentially around the cylindrical skirt of the rotary element, the annular ring comprising a plurality of windows distributed around the axis X and separated from each other by fingers, the annular crown having a distal edge, opposite the flange, which has an annular shape and has undulations, said undulations being directed radially inwards towards the cylindrical skirt, each being positioned circumferentially between two adjacent fingers and being able to bear radially inwards against the cylindrical skirt of the rotary element so as to limit the deformation of the annular ring.

Thus, in such an arrangement, the distal edge of the annular crown has a continuous annular shape around the axis X, which contributes to increasing the rigidity of the annular crown.

In addition, the corrugations provide a stop zone against the cylindrical skirt of the primary flywheel, which makes it possible to limit the risks of deformation in the event of an impact during the handling and / or transport of the device and also improves the geometry of the annular crown.

Finally, the corrugations improve the regularity of the geometry of the annular crown, especially when the target is made by folding a flat sheet. Indeed, the corrugations make it possible to compensate for the reduction in the diameter of the external periphery which is intended to form the distal edge of the annular crown when the annular crown is folded perpendicularly to the flange. The undulations thus limit the risks of local buckling of the annular crown when the reduction in diameter is not compensated for.

According to other advantageous embodiments, such a device can have one or more of the following characteristics.

According to one embodiment, one of the corrugations is positioned circumferentially in each interval between two adjacent fingers.

According to one embodiment, each corrugation is in contact with the cylindrical skirt of the rotary element.

According to another embodiment, each undulation is spaced radially from said cylindrical skirt by a functional clearance less than a radial distance capable of causing plastic deformation of the fingers. This makes it easier to mount the target on the rotary element while limiting irreversible deformation of the annular ring. For example, the functional clearance is less than 1 mm, for example of the order of 0.5 mm.

According to one embodiment, the rotary element comprises a radial portion having an external periphery and the cylindrical skirt of the rotary element extends axially from the external periphery of the radial portion.

According to one embodiment, the flange is fixed to the rotary element.

According to one embodiment, the flange is in abutment against the radial portion.

According to one embodiment, the flange is fixed against the radial portion.

According to one embodiment, the flange is welded to the radial portion of the rotary element.

According to another embodiment, the flange is riveted on the radial portion of the rotary element.

According to one embodiment, the rotary element is a flywheel intended to be fixed to a shaft driving a motor vehicle.

According to one embodiment, the rotary element is a primary flywheel of a torsion damper.

According to one embodiment, the rotary element being a flywheel, in particular a primary flywheel of a torsion damper, intended to be fixed to a drive shaft of a motor vehicle, the flange and the portion radial of the rotary element are arranged axially on either side of the cylindrical skirt of the rotary element.

According to one embodiment, the flange is fixed against a front edge of the cylindrical skirt.

According to one embodiment, the flange is welded to the front edge of the cylindrical skirt.

According to one embodiment, the device further comprises:

- A web which is movable in rotation relative to the rotary element and which is interposed axially between the flange and the radial portion of the rotary element;

- elastic members which are housed in an annular chamber defined by the flange, the radial portion of the rotary element and the cylindrical skirt and which are each interposed circumferentially between a support tab integral in rotation with the web and a seat of integral support in rotation of the rotary element. Thus, the target flange has an additional function since in addition to contributing to the rigidity of the target and ensuring its fixation on the rotary element, it also ensures the definition of the annular chamber in which the elastic members are housed. .

According to one embodiment, each support seat integral in rotation with the rotary element comprises two facing bosses, respectively formed in the radial portion of the rotary element and in the flange of the target.

According to one embodiment, the target is made of a metal sheet. Thus, the annular crown generates variations in magnetic fields capable of being detected. The metal sheet is for example steel.

According to one embodiment, the metal sheet is a steel stamping sheet, such as DD 13 steel for example.

According to one embodiment, the annular ring has a proximal edge of annular shape between the windows and the flange.

According to one embodiment, the proximal edge has undulations which are directed radially inwards and are each positioned circumferentially between two adjacent fingers. This contributes in particular to compensate for the reduction in diameter during the folding of the annular crown and thus contributes to limiting the risks of local buckling.

According to one embodiment, the windows of the annular ring extend at the level of the external periphery of the flange. This increases the target's reading area.

According to one embodiment, one of the windows has a circumferential dimension different from those of the other windows so as to constitute a mark, such as a mark for top dead center for example.

According to one embodiment, the invention relates to an assembly comprising a said device and a sensor intended to be arranged radially opposite the annular ring.

According to one embodiment, the sensor is a sensor capable of detecting variations in magnetic fields, such as a hall effect sensor or a passive sensor.

According to one embodiment, the invention also provides a method of manufacturing a device comprising the following steps:

- Provide a rotary element intended to be mounted in rotation about an axis of rotation X, the rotary element comprising at least one cylindrical skirt of axial orientation; and

- fabricate a target intended to be placed opposite a sensor capable of delivering a signal representative of the angular position and / or of the speed of the target, the target comprising:

- a flange which has a radial orientation; and

an annular crown which extends axially from the flange, the annular crown comprising a plurality of windows distributed around the axis X and separated from one another by fingers, the annular crown comprising a distal edge, opposite the flange, which has an annular shape and comprises corrugations, said corrugations being directed radially inwards and each being positioned circumferentially between two adjacent fingers; and

fixing the target to the rotary element in a position in which the annular ring is arranged circumferentially around the cylindrical skirt of the rotary element and in which the undulations are able to bear radially inwards against the cylindrical skirt of the rotary element so as to limit the deformation of the annular ring.

According to other advantageous embodiments, such a method can have one or more of the following characteristics.

According to one embodiment, the production of the target successively comprises:

- Provide a flat sheet metal part of annular shape comprising an internal portion intended to form the flange and an external portion intended to form the annular crown;

- punching the external portion of the sheet metal part so as to produce the plurality of windows;

- deform the sheet metal part so that the outer portion of the sheet metal part is inclined with respect to the internal portion by an angle between 10 and 80 and so that the corrugations are made in the area of the portion external intended to form the distal edge of the annular crown ⁰ ;

- deform the sheet metal part so that the outer portion of the sheet metal part is arranged perpendicular to the internal portion so as to produce the annular ring extending perpendicular to the flange.

According to one embodiment, the deformation phase during which the external portion of the sheet metal part is inclined relative to the internal portion and the corrugations are provided is carried out during a single stamping step.

According to another embodiment, the deformation phase during which the external portion of the sheet metal part is inclined relative to the internal portion and the corrugations are provided is carried out in several stamping stages.

Brief description of the figures

The invention will be better understood, and other objects, details, characteristics and advantages thereof will appear more clearly during the following description of several particular embodiments of the invention, given solely by way of illustration and without limitation. , with reference to the accompanying drawings.

- Figure 1 is a half-sectional view of a torsion damper equipped with a target according to a first embodiment.

- Figure 2 is a detailed view of the torsion damper of Figure 1.

- Figure 3 is a view similar to that of Figure 2 according to an alternative embodiment.

- Figure 4 is a perspective view of the target fitted to the torsion damper of Figures 1 and 2.

- Figure 5 is a perspective view of a target according to a second embodiment.

- Figure 6 is a perspective view of a target according to a third embodiment.

- Figure 7 is a half-sectional view of a torsion damper equipped with a target according to a fourth embodiment.

- Figure 8 is a front perspective view of the torsion damper of Figure 7.

- Figure 9 is a perspective view of the target of the torsion damper of Figures 7 and 8.

- Figure 10 is a partial sectional view of a torsion damper according to a fifth embodiment.

- Figure 11 is a partial sectional view of a torsion damper equipped with a target according to a sixth embodiment.

Figures 12 and 13 are perspective views illustrating two successive states of the target of Figure 4 during its manufacturing process.

Detailed description of embodiments

In the description and the claims, the terms external and internal as well as the axial and radial orientations will be used to designate, according to the definitions given in the description, elements of the device. By convention, the radial orientation is directed orthogonally to the axis X of rotation of the device determining the axial orientation and, from the inside towards the outside while moving away from said axis, the circumferential orientation is directed orthogonally to the axis of the device and orthogonal to the radial direction. The terms external and internal are used to define the relative position of an element with respect to another, with reference to the axis of rotation of the device, an element close to the axis is thus qualified as internal as opposed to an external element located radially on the periphery. Furthermore, the terms rear AR and front AV are used to define the relative position of one element with respect to another in the axial direction, an element intended to be placed close to the heat engine being designated by rear and an element intended to be placed close to the gearbox being designated by front.

In connection with FIG. 1, there is a device 1 of a transmission chain which is equipped with a target 4 intended to be placed facing a sensor, not shown. The sensor makes it possible to deliver a signal representative of the angular position and / or of the speed of the target 4. Such a sensor is in particular capable of informing the vehicle computer of the crankshaft position, which allows the vehicle computer to control correctly injecting fuel and, for petrol engines, igniting the spark plugs.

In Figure 1, the device 1 is a torsional damper. This comprises a primary element 2 and a secondary element 20 which are mounted so as to be able to rotate relative to one another about the axis X. The torsion damper also comprises elastic members 15 which are arranged to transmit a torque and dampen the rotation acyclisms between the primary element 2 and the secondary element 20.

The primary element 2 here is a primary flywheel intended to be fixed to the end of a crankshaft of an engine. It comprises a hub 21, a radial portion 11 which extends radially outward from the hub 21 and a cylindrical skirt 3 of axial orientation which extends forward from the outer periphery of the radial portion 11. The primary element 2 also includes a cover 22 fixed on the front end of the cylindrical skirt 3. The cover 22 defines, with the radial portion 11 and the cylindrical skirt 3, an annular chamber 14 in which the elastic members 15 are housed. The elastic members 15 are, for example, curved coil springs which are circumferentially distributed around the axis X. Each of the elastic members 15 extends circumferentially between two support legs of a web 16 integral in rotation with the secondary element 20 and two support seats carried by the primary element 2. Each support seat carried by the primary element 2 is, for example, constituted by two bosses ges, not shown, which are respectively formed in the radial portion 11 of the primary element 2 and in the cover 22. Thus, in operation, each of the elastic members 15 bears, at a first end, against a supported support seat by the primary element 2 and, at a second end, against a support lug carried by the web 16, so as to ensure the transmission of the torque between the primary element 2 and the secondary element 20.

According to a variant embodiment not illustrated, the web 16 is not fixed to the secondary element 20 but movable in rotation about the axis X relative to said secondary element 20 and the torque is transmitted between the web 16 and the secondary element 20 by one or more additional stages of elastic members.

The secondary element 20 comprises a hub 23 having internal splines intended to cooperate with complementary splines of a torque transmission device, such as a double clutch or a torque converter for example, which is capable of transmitting the torque between the secondary element 20 and an input shaft of the gearbox. In addition, the secondary element 20 also includes an optional secondary flywheel 24, which is fixed to the hub 23 and thus makes it possible to increase the inertia of the secondary element 20.

In other embodiments not shown, the secondary element 20 comprises a secondary flywheel having a planar annular surface, facing forward and intended to form a bearing surface for a friction lining of a disc. clutch.

Figure 4 illustrates in detail the target 4. The target 4 has a flange 5 which has a radial orientation and is intended to be fixed against the radial portion 11 of the primary element 2. To do this, the flange 5 has a plurality of holes 25 distributed around the axis X and intended for the passage of fasteners, such as rivets 26, ensuring the attachment of the flange 5 to the radial portion 11 of the primary element 2. The flange 5 comprises in addition to one or more annular ribs 27 of center X aimed at stiffening the flange 5.

Furthermore, the target 4 has an annular ring 6 which extends axially from the external periphery of the flange 5. The annular ring 6 has a plurality of windows 7, 19 which are separated from each other by fingers 8 extending in the axial direction, parallel to the X axis. Such a structure formed by alternating fingers 8 and windows 7, 19 allows a sensor which is fixed to a non-rotating element of the vehicle, such as for example the engine block or the casing of the vehicle gearbox, and is positioned radially opposite the annular ring 6 to detect the position and / or the speed of the target 4. The axial length of the windows 7, 19 defines the width of a reading area for the sensor.

To do this, in an advantageous embodiment, the target 4 is made of a magnetic material. The target 4 is for example made of metal sheet. According to an advantageous variant, the target 4 is produced in a steel stamping sheet, such as DD13 steel for example. In addition, the sensor is able to detect variations in magnetic fields. Such a sensor is for example an active hall effect sensor or a passive sensor. Thus, the alternation of fingers 8 and windows 7, 19 of the annular ring 6 is capable of generating, when the target 4 is rotated, a variation of the magnetic field which is detected by the sensor.

In another embodiment, the sensor is an optical sensor which detects the passage of a window 7, 19 or of a finger 8 in its optical field.

Advantageously, at least one of the windows, referenced 19 in FIG. 4, has a circumferential dimension different from that of the other windows 7. Such a window 19 constitutes a mark making it possible to determine the angular position of the target 4. From alternatively, such a mark can also be formed by a finger 8 having a dimension in the circumferential direction greater than that of the others. The reference may in particular be a top dead center reference, that is to say that it is located opposite the sensor when the position of the crankshaft is such that the engine piston closest to the nose of the crankshaft is located. high position.

Furthermore, the annular ring 6 has a distal edge 9 opposite the flange 5 and a proximal edge 12 adjacent to the flange 5. The distal edge 9 and the proximal edge 12 have an annular shape. The distal edge 9 has corrugations 10 which are each positioned circumferentially between two adjacent fingers 8. Similarly, the proximal edge 12 has corrugations 13. Each of the corrugations 13 of the proximal edge 12 extends opposite in the axial direction of one of the corrugations 10 formed in the distal edge 9. The corrugations 10, 13 protrude radially inwards with respect to the fingers 8. In the embodiments shown in the figures, the distal edge 9 is extends continuously around the axis X, that is to say without interruption, such that 'a slit. According to a variant not shown, the distal edge 9 is discontinuous. In this variant, discontinuities of the distal edge 9, such as slots, may be positioned at the level of the corrugations 10 and 13, in particular at the level of the radially innermost parts relative to the fingers 8 of the corrugations 10 and 13.

Returning to FIG. 1, it can be seen that when the target 4 is fixed on the primary element 2, the annular ring 6 is arranged around the cylindrical skirt 3 of the primary element 2. Furthermore, according to the variant illustrated in FIG. 2, each of the corrugations 10 formed in the distal edge 9 of the annular crown 6 is in contact against the cylindrical skirt 3. This makes it possible to limit the deformation of the annular crown 6, radially inwards, in the event of shocks. However, such a structure requires a forced mounting of the target 4 on the cylindrical skirt 3 of the primary element 2.

According to another variant illustrated in FIG. 3, each of the corrugations 10 formed in the distal edge 9 of the annular ring 6 is radially separated from the cylindrical skirt 3 by a functional clearance less than a radial distance capable of causing plastic deformation of the fingers 8. The functional clearance is typically less than 1 mm, for example of the order of 0.5 mm. Such a game makes it easier to mount the target 4 on the primary element 2 while preventing irreversible deformations of the annular ring 6, radially inward.

FIG. 5 illustrates a target 4 according to a second embodiment. This embodiment differs in particular from the previous embodiment in that the proximal edge 12 of the annular ring 6 is devoid of undulations. In addition, the flange 5 has a smaller radial dimension and has no hole allowing the passage of fasteners. In such an embodiment, the flange 5 can in particular be fixed to the radial portion 11 of the primary element 2 by welding, as detailed below.

FIG. 6 illustrates a target 4 according to a third embodiment. This embodiment differs from the previous embodiment in that the windows 7, 19 extend at the level of the external periphery of the flange 5. Such an embodiment is advantageous in that it makes it possible to increase the width of the reading area.

Figures 7, 8 and 9 illustrate a torsional damper equipped with a target 4 according to a fourth embodiment. As shown in FIG. 7, the flange 5 of the target 4 and the radial portion 11 of the primary element 2 are arranged axially on either side of the cylindrical skirt 3. Thus, the flange 5 of the target 4 n 'is not fixed against the radial portion 11 of the primary element 2 but is welded against the front edge of the cylindrical skirt 3. The axial orientation of the annular ring 6 is therefore reversed since it extends backwards from the outer periphery of the flange 5 and not towards the front as in the embodiment of FIG. 1. The flange 5 of the target 4 therefore replaces the cover 22 of FIG. 1 and thus defines, with the radial portion 11 and the cylindrical skirt 3 of the primary element 2, the annular chamber 14 in which the elastic members 15 are housed. This makes it possible to limit the number of components of the device 1.

As shown in Figure 9, the flange 5 of the target 4 has bosses 17 which project towards the radial portion 11 of the primary element 2. Each of the bosses 17 is arranged opposite a boss 18, shown in FIG. 8, formed in the radial portion 11 of the primary element

2. Each pair of facing bosses 17, 18 forms a support seat disposed circumferentially between two adjacent elastic members 15 and intended, in operation, to press against one end of one of the two elastic members 15.

Note that, in another embodiment, not illustrated, the elastic members of the torsion damper are not coil springs but elastic blades. The elastic blades are fixed to one of the primary 2 and secondary 20 elements and have a cam surface which cooperates with a cam follower associated with the other element. Such torsional dampers are described in particular in documents FR3027986, FR3026801 and FR3032248.

In such a case, a flange 5, fixed against the end of the cylindrical skirt 3 which is opposite to the radial portion 11 as described above in relation to FIGS. 7, 8 and 9, is in particular capable of contributing to a clevis mounting of the articulation axis of the cam follower (in a torsion damper as described in the documents FR3027986, FR3026801) or in axially retaining the cam follower (in a torsion damper as described in the document FR3032248).

FIG. 10 partially illustrates a torsional damper equipped with a target 4 according to a fifth embodiment. The target 4 is here fixed to the primary element 2 by welding. To do this, the radial portion 11 of the primary element 2 has a shoulder 28 which projects axially rearward from the radial portion 11 of the primary element 2. The shoulder 28 defines an annular centering surface 29 which cooperates with the internal periphery of the flange 5 and thus makes it possible to ensure centering of the target 4 relative to the primary element 2. Furthermore, a weld 30 is produced between the annular centering surface 29 and the internal periphery of the flange 5 so as to secure the target 4 to the primary element 2.

According to another embodiment not shown, the target 4 is fixed to the primary element by welding between the cylindrical skirt 3 and the distal edge 9. The welding can for example be carried out between the cylindrical skirt 3 and the corrugations 10 of the edge distal 9.

FIG. 11 partially illustrates a torsion damper according to a sixth embodiment. In this embodiment, the target 4 is fixed to the primary element 2 by means of rivets 31 which are formed in the mass of the primary element 2.

In relation to FIGS. 12 and 13, a method of manufacturing a target 4 is described below, as illustrated in FIG. 4.

Firstly, as shown in FIG. 12, a metal sheet is cut so as to form a part of annular shape. The outer portion of the annular portion is punched so as to form the plurality of windows 7, 19. In addition, in the embodiment shown, the inner portion of the annular part is drilled so as to form the plurality of holes 25 intended the passage of fasteners. The internal portion is also stamped so as to form the annular ribs 27.

In a second step, the part is deformed by stamping so as, on the one hand, to incline the external portion relative to the internal portion at an angle between 10 and 80 °, advantageously between 30 and 50 ° and by example of the order of 40 °, and, on the other hand, to form the corrugations 10, 13. A part, as illustrated in FIG. 13, is then obtained.

According to a first embodiment, the inclination of the external portion relative to the internal portion as well as the formation of all of the corrugations 10, 13 are carried out during a single stamping step. However, according to another embodiment, the stamping of corrugations 10, 13 too close to each other being capable of generating additional technical difficulties, in particular for the manufacture of the matrix, the stamping of all the corrugations 10, 13 is not produced during the same stamping step. In such an embodiment, the punch and the die used for stamping the part have shapes which correspond only to part of the corrugations 10, 13 of the proximal edge, on the one hand, and of the distal edge 9 , on the other hand. Thus, the shapes of the punch and of the matrix intended to form the corrugations correspond only to one corrugation in two or one corrugation in three for example. These forms being regularly distributed around the axis X, the part to be formed is turned around its central axis after a first series of corrugations has been formed so as to form a second series of corrugations offset circumferentially with respect to the first series. This operation is repeated as many times as necessary to form all of the undulations.

Thereafter, the part as illustrated in FIG. 13 is deformed by stamping so as to arrange the external portion forming the annular crown 6 perpendicular to the internal portion forming the flange 5, as illustrated in FIG. 4.

Note that such a method is particularly advantageous in that it makes it possible to limit the risks of local buckling of the annular ring 6 and thus makes it possible to limit the geometric defects of the target 4.

Subsequently, the target 4 is fixed to the primary element 2 as described above.

Although the invention has been described in connection with several particular embodiments, it is obvious that it is in no way limited thereto and that it includes all the technical equivalents of the means described as well as their combinations if these fall within the scope of the invention.

In particular, if the invention has been described above in relation to a device of the torsion damper type, a target 4 as described above can also be associated with other types of device, such as a steering wheel motor, rigid or flexible, torque converter or others.

The use of the verb "behave", "understand" or "include" and its conjugate forms does not exclude the presence of other elements or steps than those set out in a claim.

In the claims, any reference sign in parentheses cannot be interpreted as a limitation of the claim.

Claims (18)

1. Device (1) for a motor vehicle transmission chain comprising: - a rotary element (2) intended to be mounted for rotation about an axis of rotation X, the rotary element (2) comprising a cylindrical skirt (3) of axial orientation; and - a target (4) intended to be placed opposite a sensor capable of delivering a signal representative of the angular position and / or of the speed of the target (4), the target (4) being fixed on the element rotary (2) and comprising: - a flange (5) which has a radial orientation; and - an annular ring (6) which extends axially from the flange (5), and is arranged circumferentially around the cylindrical skirt (3) of the rotary element (2), the annular ring (6) comprising a plurality of windows (7, 19) distributed around the X axis and separated from each other by fingers (8), the annular crown (6) having a distal edge (9), opposite the flange (5), which has a annular in shape and has corrugations (10), said corrugations (10) being directed radially inwards towards the cylindrical skirt (3), being each positioned circumferentially between two adjacent fingers (8) and being able to bear radially inwards against the cylindrical skirt (3) of the rotary element (2) so as to limit the deformation of the annular ring (6). 2. Device (1) according to claim 1, wherein each corrugation (10) is in contact against the cylindrical skirt (3) of the rotary element (2) or spaced radially from said cylindrical skirt (3) by a functional clearance less than a radial distance capable of causing plastic deformation of the fingers (8). 3. Device (1) according to claim 1 or 2, wherein the rotary element (2) comprises a radial portion (11) having an external periphery and in which the cylindrical skirt (3) of the rotary element (2) extends axially from the outer periphery of the radial portion (11). 4. Device (1) according to claim 3, wherein the flange (5) bears against the radial portion (11). 5. Device (1) according to claim 4, wherein the flange (5) is welded to the radial portion (11) of the rotary element (2). 6. Device (1) according to claim 4, wherein the flange (5) is riveted on the radial portion (11) of the rotary element (2). 7. Device (1) according to any one of claims 1 to 6, wherein the rotary element (2) is a flywheel intended to be fixed to a drive shaft of a motor vehicle, and in particular a flywheel primary inertia of a torsion damper. 8. Device (1) according to claim 3, wherein the rotary element (2) is a flywheel, in particular a primary flywheel of a torsion damper, intended to be fixed to a drive shaft d 'a motor vehicle and in which the flange (5) and the radial portion of the rotary element (2) are arranged axially on either side of the cylindrical skirt (3) of the rotary element (2). 9. Device (1) according to claim 8, wherein the flange (5) is fixed against a front edge of the cylindrical skirt (3). 10. Device (1) according to claim 9, wherein the flange (5) is welded to the front edge of the cylindrical skirt (3). 11. Device (1) according to one of claims 8 to 10, further comprising: - a web (16) which is rotatable with respect to the rotary element (2) and which is axially interposed between the flange (5) and the radial portion (11) of the rotary element (2); - elastic members (15) which are housed in an annular chamber (14) defined by the flange (5), the radial portion (11) of the rotary element (2) and the cylindrical skirt (3) and which are each circumferentially interposed between a support tab integral in rotation with the web (16) and a support seat integral in rotation with the rotary element (2). 12. Device (1) according to claim 11, in which each support seat integral in rotation with the rotary element (2) comprises two facing bosses (17, 18), respectively formed in the radial portion (11) of the rotating element (2) and in the flange (5) of the target (4). 13. Device (1) according to any one of claims 1 to 12, wherein the target (4) is made of a metal sheet. 14. Device (1) according to any one of claims 1 to 13, wherein the annular ring (6) has a proximal edge (12) of annular shape between the windows (7, 19) and the flange (5). 15. Device (1) according to claim 14, wherein the proximal edge (12) has corrugations (13) which are directed radially inwards and are each positioned circumferentially between two adjacent fingers (8). 16. Device (1) according to any one of claims 1 to 13, in which the windows (7, 19) of the annular ring (6) extend at the level of the external periphery of the flange (5). 17. Method of manufacturing a device (1) comprising the following steps: - Provide a rotary element (2) intended to be mounted for rotation about an axis of rotation X, the rotary element (2) comprising at least one cylindrical skirt (3) of axial orientation; and - manufacture a target (4) intended to be placed opposite a sensor capable of delivering a signal representative of the angular position and / or of the speed of the target (4), the target (4) comprising: - a flange (5) which has a radial orientation; and - an annular ring (6) which extends axially from the flange (5), the annular ring (6) comprising a plurality of windows (7, 19) distributed around the axis X and separated from each other by fingers (8), the annular ring (6) having a distal edge (9), opposite the flange (5), which has an annular shape and has undulations (10), said undulations (10) being directed radially towards the inside and being each positioned circumferentially between two adjacent fingers (8); and - fix the target (4) to the rotary element (2) in a position in which the annular ring (6) is arranged circumferentially around the cylindrical skirt (3) of the rotary element (2) and in which the undulations (10) are able to bear radially inwards against the cylindrical skirt (3) of the rotary element (2) so as to limit the deformation of the annular ring (6). 18. A method of manufacturing a device (1) according to claim 17, wherein the manufacturing of the target (4) successively comprises: - Provide a piece of flat sheet metal of annular shape comprising an internal portion intended to form the flange (5) and an external portion intended to form the annular crown (6); - punch the outer portion of the sheet metal part so as to achieve plurality 5 of windows (7, 19); - deform the sheet metal part so that the outer portion of the sheet metal part is inclined with respect to the internal portion by an angle between 10 and 80 and so that the corrugations are made in the area of the portion external intended to form the distal edge (9) of the annular crown ⁰ ; 10 - deform the sheet metal part so that the external portion of the sheet metal part is arranged perpendicular to the internal portion so as to produce the annular ring (6) extending perpendicular to the flange (5). 1/7 2/7