FR2915436A1 - Articulation mechanism for front seat of motor vehicle, has helical spring comprising end that is positioned to be supported against stop of cam when cam rotates in angular direction without being driven by central shaft - Google Patents

Abstract

The mechanism has a braking device comprising a helical spring extending between ends by rotating in an angular direction (39) from one of the ends to another end. The ends of the spring are positioned to be supported against stops integrated to a central shaft (12) when the shaft is activated in another angular direction (40) and in the former direction, respectively, for driving an eccentric cam (29). The latter end is positioned to be supported against a stop of the cam when the cam rotates in the angular direction (40) without being driven by the shaft.

Description

Hinge mechanism and vehicle seat comprising such a mechanism.

  The present invention relates to articulation mechanisms and vehicle seats comprising such mechanisms. More particularly, the invention relates to a hinge mechanism for a vehicle seat comprising first and second frames mounted rotatable relative to each other and interconnected by a gear controlled by an eccentric cam connected with angular play. to a central shaft which extends along a central axis, said central shaft being rotatably mounted in a bearing which is integral with the second armature and which has an inner face, a braking device being interposed radially between the shaft central and the inner face of said bearing. Document FR-A-2,770,810 describes an example of such a hinge mechanism which gives satisfaction and in which the braking device is a metal spring. The hinge mechanisms of this type, however, have the disadvantage that the braking torque generated between the input member and the bearing is relatively variable from one hinge mechanism to the other and can prove insufficient. The present invention is intended to overcome this disadvantage. For this purpose, an articulation mechanism of the kind in question is characterized in that the braking device comprises a helical spring extending between first and second ends while rotating in a first angular direction from said first end to the said second end, said helical spring being pivotally mounted with lost motion around the central shaft and having an outer periphery in frictional contact with the inner face of the bearing, in that the first end of the coil spring is arranged to engage pressing against a first solid stop of the central shaft when said central shaft is actuated in a second angular direction opposite to the first angular direction to drive the eccentric cam, in that the second end of the coil spring is arranged to bear against a second solid abutment of the central shaft when said shaft ntral is actuated in the first angular direction to drive the eccentric cam, and in that the second end of the spring is arranged to bear against a third stop belonging to the eccentric cam when said eccentric cam rotates in the second angular direction without being driven by the central shaft. Thanks to these provisions, the braking torque generated between the central shaft of the input member is well controlled. This braking torque is almost zero when the mechanism is controlled voluntarily by a user who actuates the control shaft, but it is high when the eccentric cam rotates in the second angular direction without being controlled by the user.

  Indeed, when the central shaft is actuated by a user, the helical spring is deformed in the direction of a diameter reduction by pressing the first stop against its first end or the second stop against its second end, so that the friction of the helical spring against the inner face of the landing becomes negligible. On the other hand, when the eccentric cam rotates in the second angular direction without being controlled by the central shaft, under the effect of a torque exerted between the first and second armatures, when the articulation mechanism connects a seat back to a seat, this second angular direction can correspond for example to the pivoting of the backrest), the helical spring is deformed positively by the third stop in the direction of an increase in diameter, which reinforces the braking. In preferred embodiments of the hinge mechanism according to the invention, one or more of the following arrangements may also be used: the helical spring has at its first end a first branch extending substantially radially inwardly relative to the central axis, said first leg being engaged in a recess in the central shaft and opening radially outwardly, said recess having an edge which forms said first abutment; the helical spring has at its second end a second branch extending substantially parallel to the central axis and adapted to bear against the second stop when the central shaft rotates in the first angular direction and against the third stop; when the eccentric cam rotates in the second angular direction; - The central shaft is integral with a collar having a notch defined angularly between two edges, one of these edges format the second abutment mentioned above; the eccentric cam comprises first and second superimposed half-cams displaceable in relative rotation with angular clearance, the abutment belonging to the first half-cam; the gear is hypocycloidal; the gear comprises first and second circular teeth in mutual engagement and in mechanical connection respectively with the first and second armatures (the second toothing may be integral with the second armature or belong to a planet gear having a third gearing); in engagement with a fourth toothing secured to the second armature), said first and second teeth respectively having first and second central axes parallel and offset with respect to each other, the central shaft being rotatably mounted about the second axis in said bearing, and said eccentric cam being rotatably mounted about the first axis in a circular housing integral with the first armature, so that a rotation of the eccentric cam causes relative rotation between the first and second teeth.

  Moreover, the invention also relates to a vehicle seat comprising first and second parts connected to each other by a hinge mechanism as defined above, the first and second armatures being fixed, one to the first part and the other to the second part. The first and second seat parts may optionally be one, a folder and the other a seat. The hinge mechanism may optionally be mounted so that a relative rotation of the input member relative to the bearing in the first angular direction corresponds to an angular displacement of the backrest backwards. Other features and advantages of the invention will become apparent from the following description of one of its embodiments, given by way of non-limiting example, with reference to the accompanying drawings. In the drawings: Fig. 1 is a schematic view of a vehicle seat equipped with a hinge mechanism according to one embodiment of the invention; Fig. 2 is a perspective view of the mechanism of articulation fitted to the seat of FIG. 1, - FIGS. 3 and 4 are exploded perspective views of the articulation mechanism of FIG. 2, viewed respectively along the directions III and IV of FIG. 2, FIG. axial sectional view of the articulation mechanism of FIG. 2; FIG. 6 is a sectional view along the line VI-VI of FIG. 5; FIG. 7 is a partial perspective view showing the central shaft; the helical spring and the eccentric cam of the hinge mechanism of FIG. 2; and FIG. 8 is a partial view in per- spective showing only the central shaft and the helical spring. In the different figures, the same references designate identical or similar elements. FIG. 1 shows a front seat 1 of a motor vehicle, which comprises a backrest 2 pivoted about an axis Y1 on a seat 3, which seat is itself mounted on the floor 4 of the vehicle, for example by 5. Thus, the backrest angle 2 is adjustable by means of a rotary control knob 6a or the like which drives a hinge mechanism 6 (thus a mechanism that positively controls the rotation of the backrest). ), an embodiment of which is shown in FIGS. 2 to 6. This articulation mechanism 6 comprises (see FIGS. 2 to 6): a first armature formed by a first metal flange 7 which extends in a perpendicular plane; to the axis Y1 and which, in the example shown, is secured to the backrest frame 2, - a second armature formed by a second metal flange 8 which extends parallel to the first flange 7, said second flange 8 being secured to the armature of the seat 3 and being retained against the first flange by any known means, for example by means of a crimped ring 9 or optionally soldered gussets (not shown) similar to those described in FR-A2 872 105, a hypocycloidal gear 10 interconnecting the first and second flanges 7, 8, and an input member 11 controlling the hypocycloid gear 10. The input member 11 may be made in one piece by molding plastic or lé-15 ger alloy. This input member comprises a central shaft 12 which extends longitudinally along a central axis Y2 parallel to the axis Y1 mentioned above but offset with respect to this axis Y1. The central shaft 12 may optionally be pierced with a square inner recess 13 (or grooved, or other) in which the above-mentioned control knob 6a can fit. Furthermore, the central shaft 12 is radially extended outwards by a flange 14 which extends parallel to the flanges 7, 8 and bears against the outer face of the first flange 7. In the example shown, this collar 14 has a notch defined angularly by two edges 14a, 14b extending in radial planes with respect to the axis Y2 (see Figure 8). The face of the flange __4 which abuts against the first flange 7 is extended towards the hypocycloidal gear 10, by two control fingers 15 which extend parallel to the axis Y2 and whose utility will be seen further. . The outer peripheral surface 16 of the central shaft 12 has a cylindrical shape of revolution centered on the axis Y2 and is surrounded by a helical spring 17 (see Figures 3 to 5). The coil spring 17 extends between a first end 18 and a second end 19 rotating in a first angular direction 39. The first end 18 of the spring may for example be constituted by a first branch extending substantially radially inwardly relative to the axis Y2, while the second end 19 may be constituted for example by a second branch extending substantially axially parallel to the axis Y2.

  The spring 17 is interposed radially between the central shaft 12 and a bearing 20 integral with the second flange 8, in which the central shaft 12 pivots. This bearing 20 may be formed by a collar formed in one piece with the second flange 8. This step 20 is centered on the aforementioned axis Y2 and extends axially from the second flange 8 to the first flange 7 (see Figures 3 to 5). The bearing 20 has an inner surface 21, cylindrical in revolution and centered on the axis Y2, which is in contact with the spring 17, with friction. The hypocycloidal gear 10 is here a monotrain gear which comprises, for example: a first toothing 27 centered on the axis Y1, this toothing being oriented radially outwards and formed on the inner face of the first flange 7, one piece with it, - a second toothing 28 which is formed on the inner face of the second flange 8 and which is oriented radially inwards, this second toothing being centered on the axis Y2, said second toothing 13 having an inner diameter greater than the outer diameter of the first toothing 14, - and a rigid eccentric cam 29, for example metal, which extends perpendicularly to the axis Y1 and which is driven by the input member 11 , this cam journalled around the collar 20 and in a cylindrical housing 30 integral with the first flange 7, said housing 30 being centered on the axis Y1. A ring 31 may optionally be interposed 10 between the eccentric cam 29 and the housing 30. The input member 11 is rotatably connected to the eccentric cam 29. Thus, the rotation of the input member 11 causes a rotation of the cam 29 which itself causes a relative rotation between the first and second fiases 7, 8 with a nutation movement between the two flanges. The cam 29 could be formed in one piece, but in the particular case considered here, it is constituted (see Figures 3 to 7) of two half-cams 29a, 29b superposed metal movable in relative rotation with angular play. As shown in more detail in FIGS. 3, 4 and 7, the half-cams 29a, 29b are annular and mounted around the central shaft 12. The peripheral edge of each of the half-cams comprises two notches 32 into which penetrate respectively the two control fingers 15 of the input member 11. In addition, the two half-cams 29a, 29b are angularly biased relative to each other by a spring 35 having a general shape substantially 0 which comprises two axial branches 36 penetrating simultaneously into two recesses 37 belonging respectively to the two half-cams 29a, 29b. The shapes of the half-cams 29a, 29b are such that the biasing of the spring 35 tends to increase the eccentricity of the cam 29 constituted by said half-cams 29a, 29b. Furthermore, as can be seen in detail in particular in Figure 7, the first branch 18 of the coil spring 17 enters a recess 33 formed in the central shaft 12 and opening radially outwardly. This recess 33 has first and second opposite edges 33a, 33b, extending in radial planes with respect to the axis Y2, between which the first leg 18 of the spring 17 is disposed with clearance. The edge 33b, forming a first stop is arranged to bear against the first leg 18 of the spring 17 by driving said spring 17 when the input member 11 rotates in a second angular direction 40 opposite to the first direction 39 and corresponding to a rotation of the file 2 from the seat to the back. Furthermore, one of the half-cams 29a, 29b, for example the half-cam 29a, comprises a stop 34, for example in the form of a tooth which projects radially inwards.

  The second branch 19 of the coil spring 17 is disposed between the abutment 34 and the edge 14a of the flange to bear: - against the edge 14a of the flange 14 (forming a second stop) when the input member 11 rotates in the first angular direction 39 corresponding to a pivoting of the backrest 2 forwards, - and against the stop 34 (constituting a third stop) when the half-cams 29a, 29b rotate in the second angular direction 40 without actuating the input organ. At rest, the half-cams 29a, 29b serve to catch the internal clearances of the hypocycloidal gear 10 and thus contribute to ensuring that a torque exerted between the first and second flanges 7, 8 is not translated. not by angular displacement between these two flasks. On the contrary, when a user actuates the input member 11, for example by means of the button 6a mentioned above, one of the fingers 15 abuts against one of the side edges of a notch 32 of the one of the half-cams 29a, 29b thus unlocking this half-cam, which then allows said control fingers 15 to drive in rotation the entire eccentric cam 29 which itself controls a relative rotation between the first and second flanges 7, 8. According to the invention, the irreversible nature of the hinge mechanism is further reinforced by the presence of the spring 17. Indeed, when the input member 11 is actuated in the one of the first and second angular directions 39, 40, one of the first and second stops 33b, 14a acts on the coil spring 17 tending to decrease its diameter, so that the friction between the spring 17 and the inner surface 21 20 are superseded, or at least strongly. reduced. Thus, during voluntary actuations of the hinge mechanism, the spring 17 has no or almost no braking action. On the other hand, when the flanges 7.8 undergo a torque that tends to pivot the backrest 2 rearwards, the half-cams 29a, 29b tend to pivot in the second angular direction 40, the helical spring 17 is deformed positively, by the action of the stop 34 of the stop 34 of the half-cam 29a on the second branch 19 of the spring: this deformation tends to increase the diameter of the coil spring 17, which reinforces the friction of said spring on the inner face 21 of the bearing 20 and thus reinforces the braking. This braking, makes it possible to avoid or limit the pivoting movements of the backrest 2 towards the rear due to the torque applied to the backrest 2 (under the effect of the vibrations of the vehicle or under the effect of a violent impact ). The braking device constituted by the spring 17 thus makes it possible to reinforce the irreversibility of the articulation mechanism 6, without generating discomfort for the user. Note that the hypocycloidal gear could be not only a monotrain gear as described above, but also a satellite gear as described for example in EP-A-0 505 229. Finally, the hinge mechanism 6 could be used to control a relative rotation between two seat parts other than a backrest and a seat.

Claims (10)

  1. Hinge mechanism for a vehicle seat having first and second armatures (7, 8) mounted rotatably relative to each other and interconnected by a gear (10) controlled by an eccentric cam ( 29) connected with angular clearance to a central shaft which extends along a central axis (Y2), said central shaft (12) being rotatably mounted in a bearing (20) which is integral with the second armature and which has an inner face (21), a braking device (17) being interposed radially between the central shaft (12) and the inner face (21) of said bearing, characterized in that the braking device comprises a helical spring (17) extending between first and second ends (18, 19) rotating in a first angular direction (39) from said first end to said second end, said coil spring (17) being pivotally mounted with lost motion around the central shaft (12). ) and an outer periphery in frictional contact with the inner face (21) of the bearing, in that the first end (18) of the helical spring is arranged to bear against a first abutment (33b) integral with the central shaft ( 12) when said central shaft (12) is actuated in a second angular direction (40) opposite the first angular direction to drive the eccentric cam (29), in that the second end (19) of the coil spring is arranged to engage bearing against a second stop (14a) integral with the central shaft (12) when said central shaft (12) is actuated in the first angular direction (39) to drive the eccentric cam (29), and in that the second end (19) of the spring is arranged to bear against a third stop (34) belonging to the eccentric cam (29) when said eccentric cam rotates in the second angular direction (40) without being driven by the central shaft. l (12).   2. articulation mechanism according to claim 1, wherein the coil spring (17) has at its first end a first leg (18) extending substantially radially inwardly relative to the central axis (Y2), said first leg (18) being engaged in a recess (33) formed in the central shaft (12) and opening radially outwardly, said recess having an edge (33b) which forms said first abutment.   3. articulation mechanism according to any one of claims 1 and 2, wherein the coil spring (17) has at its second end a second branch (19) extending substantially parallel to the central axis (Y2 ) and adapted to bear against the second stop (14a) when the central shaft (12) rotates in the first angular direction (39) and against the third stop (34) when the eccentric cam (29) rotates in the second angular direction (40).   4. articulation mechanism according to claim 3, wherein the central shaft (12 is integral with a flange (14) having a notch defined angularly between two edges (14a, 14b), one ( 14a) of these edges format the aforementioned second stop.   5. articulation mechanism according to any one of the preceding claims, wherein the eccentric cam (29) comprises first and second half-cams (29a, 29b) superimposed, movable in relative rotation with angular play, the third stop ( 34) belonging to the first half cam (29a).   The hinge mechanism of any preceding claim, wherein the gear (10) is hypocycloidal.   Articulation mechanism according to claim 6, in which the gearing (10) comprises first and second circular teeth (27, 28) in mutual engagement and in mechanical connection respectively with the first and second armatures (7,   8), said first and second teeth respectively having first and second central axes (Y1, Y2) parallel and offset with respect to each other, the central shaft (12) being rotatably mounted about the second axis (Y2 ) in said bearing (20), and said eccentric cam (29) being rotatably mounted about the first axis (Y1) in a circular housing (30) integral with the first armature (7), so that a rotation of the eccentric cam (29) causes a relative rotation between the first and second teeth (27, 28). A vehicle seat having first and second parts (2, 3) connected to each other by a hinge mechanism (6) according to any one of the preceding claims, the first and second armatures being laid down, one in the first part and the other in the second part.   Vehicle seat according to claim 8, wherein the first and second seat parts are one, a backrest (2) and the other, a seat (3).   The seat according to claim 9, wherein the hinge mechanism (6) is mounted for relative rotation of the central shaft (12) relative to the hinge (20) in the first angular direction (39). ) corresponds to an angular displacement of the backrest (2) towards the rear.