FR2902161A1 - Torsion damping spring for motor vehicle, has last coil provided at each end of spring, and connected by coil of reduced diameter to preceding coil or antepenultimate coil of spring - Google Patents

Abstract

The spring (10) has a wire (12) that is wound on helical coils of constant diameter. The helical coils are non jointed at a free state, such that the spring acts as traction and compression spring. A last coil (14), at each end of the spring, is connected by a coil (16) of reduced diameter, to a preceding coil or an antepenultimate coil (18) of the spring. The coil (14) extends in a plane that is perpendicular to an axis of the spring.

Description

The invention relates to a torsion damper spring, as well as a

  double damping flywheel, particularly for a motor vehicle, comprising such springs. A double damping flywheel comprises two coaxial flywheels, centered and guided in rotation relative to one another, one of which is fixedly mounted at the end of a driving shaft and the other of which forms the plateau of reaction of a clutch. A torsion damper comprising circumferentially disposed springs is mounted between the two flywheels to transmit the driving torque from one flywheel to the other and to damp the relative oscillations of the flywheels. The springs are formed of a wire wound in non-contiguous helical turns in the free state and their ends rest on abutments integral with one of the flywheels and on radial tabs of an annular web integral with the other flying wheels. The support of the ends of the springs on the abutments and on the legs of the annular sail poses numerous problems in terms of efficiency and life of the springs. A known solution is to grind the last turn at each end of the springs, to form on this turn a plane face perpendicular to the axis of the spring, which will be the bearing surface of the spring on a leg of the annular sail or on a turn end of another spring placed at the end of the first. However, this grinding operation is expensive and weakens the end turns of the springs. The purpose of the invention is in particular to eliminate this drawback of the prior art. It proposes a torsion damper spring, consisting of a wire wound in non-contiguous helical turns in the free state, characterized in that at least one end of the spring, the last turn is connected by a turn of diameter reduced to the previous turn or antepenultimate turn and extends in a plane substantially perpendicular to the axis of the spring.

  The formation of a penultimate turn of reduced diameter makes it possible to catch the angle of inclination of the helical turns and thus to form a last turn which extends substantially perpendicular to the axis of the spring.

  The penultimate spire or spiral of reduced diameter is housed inside the last turn and the antepenultimate turn. The last turn is applied to the antepthultieth turn or is in the immediate vicinity of it. The spring wire may be circular in section, but is preferably of substantially oval or flat section. The spring according to the invention is bent in a circle axis to be mounted in a torsion damper, the turn of reduced diameter or penultimate turn being on the radially outer side of the spring. Preferably, each end of the spring comprises a last turn connected by a turn of reduced diameter to the third turn of the spring coil, the latter turn being substantially perpendicular to the axis of the spring. The invention also proposes a double damping flywheel, in particular for a motor vehicle, characterized in that it comprises circumferentially disposed springs which are of the aforementioned type. The ends of these springs are advantageously received in arcuate notches formed on either side of a centering nose in the radial edges of the lugs of an annular web integral with one of the flywheels of the double damper steering wheel.

  In a preferred embodiment, the double damping flywheel comprises springs of the aforementioned type which are placed end to end and which are formed of son having different sections, these springs having not reversed. Advantageously, the spring wires have substantially oval sections whose ends are formed by arcs of different radii, and the sections of the wires of the springs placed end to end are reversed from one spring to the other, the sections of the wire of a spring having large arcs on the inner side of the turns and the sections of the wire of the other spring having small arcs on the inner side of the turns, for self-centering of the ends of the springs in support of the one on the other. In general, the invention makes it possible to ensure correct supports of the ends of the springs on the abutments formed by one of the flywheels and on the radial lugs of the annular web integral with the other flywheel, while saving the cost of grinding the ends. springs and avoiding weakening the end turns. In addition, the end turns of the springs better support the transmission of the engine torque peaks, for which the springs are compressed to the maximum and the turns are in contact with each other. The service life of the chutes that are interposed between the springs and the radially outer wall of their housing in one of the flywheels is improved, the chutes being no longer attacked by the ridges resulting from the grinding of the end turns. springs. The invention will be better understood and other characteristics, details and advantages thereof will appear more clearly on reading the description which follows, given by way of example with reference to the accompanying drawings, in which: FIG. schematic perspective view of a spring according to the invention; Figure 2 is a front view of two springs according to the invention placed end to end; Figures 3 and 4 are enlarged partial views of encircled details III and IV of Figure 2; Figure 5 is an enlarged view in section of the ends of the springs shown in Figure 4; Figure 6 schematically shows a torsion damper for double damping flywheel.

  The spring 10 shown in FIG. 1 is formed of a wire 12 wound in helicoidal turns of constant diameter, the turns of the spring not being contiguous to the free state shown in the drawing, so that this spring can work as a spring. traction and compression spring as is the case in a torsion damper of a double damping flywheel. The last turn 14, at each end of the spring, is connected by a penultimate turn 16 of reduced diameter to the previous turn or antepenultimate turn 18 of the spring.

  The reduced diameter of the penultimate turn 16 of the spring allows it to register within the end turn 14 and the antepenultimate turn 18, as best seen in FIG. example. The disposition of the penultimate turn 16 inside the turns 14 and 18 makes it possible to apply the last turn 14 against the antepenultimate turn 18 by catching the angle of inclination of the helical turns so that the last turn 14 is substantially perpendicular to the axis of the spring. The last turn 14 thus forms a flat bearing surface on a surface perpendicular to the axis of the springs, for example on an abutment integral with a steering wheel or on a radial lug of an annular web integral with the other flywheel. The same advantages are obtained as with ground end turns, but avoiding their disadvantages (high cost of the grinding operation, fragility of the end turn, wear of the guide chutes, etc.). It is advantageous, in a twisting damper for a double damping flywheel for a motor vehicle, to place end to end two curved springs, each of which extends to a little less than 90 and which are formed of wires of different sections to have different stiffnesses, as shown in FIG. 2. In this figure, one of the springs placed end to end is designated by the reference numeral 10 and is formed of a wire 12 having a lower section than that of the wire 22 of the other spring 20, the turns of the two springs having substantially the same outer diameter. The end turns 14 of the first spring 10 are connected by the last-to-last turns 16 of reduced diameter to the spiral antepenultimate 18 and extend in a plane substantially perpendicular to the axis of the spring and, likewise, the turns of end 24 of the other spring 20 are connected by penultimate turns 26 of reduced diameter to the antepenultimate spring turns. The winding pitch of the turns of the two springs are reversed from one spring to the other, the turns 16 and 26 of reduced diameter being on the radially outer side of the two springs. Thus, when the springs are compressed to the maximum, their turns 16 of reduced diameter do not withstand high stresses. It is also advantageous, as can be seen more clearly in the sectional view on a larger scale of FIG. 5, that the wire of the spring 10 has a substantially oval section formed of two circular arcs C1 and C2 of different radii connected by segments of line d, the arc of circle cl having a radius smaller than that of the arc of circle c2. Similarly, the wire of the spring 20 has a substantially oval section formed of two circular arcs c'l and c'2 of different radii connected by straight line segments of, the arc of circle c'l having a lower radius to that of the arc of circle c'2. The pitch of the springs 10 and 20 are reversed, as already indicated, and the sections of the spring wires are reversed from one spring to the other, the arc of circle c of smaller radius of the wire of the spring 10 being radially the outside of the spring and the arc of circle c2 of larger radius inside the spring while for the spring 20, the arc of circle c'l of smaller radius of the section of the wire of the spring is radially inside the spring and the arc c'2 of larger radius radially outside the spring. This inversion of the sections of the spring wires to their contact interface, that is to say to the support interface of the end turns 14 and 24 on one another, carries out a self-centering of these ends of the springs, the end turn 14 of the spring 10 being caused to align axially on the end turn 24 of the spring 20 due to the inclinations of the right segments of the son sections of these springs at the interface . In FIG. 6, which represents a portion of a torsion damper of a double damping flywheel, there are two sets of two springs 10 and 20 shown in FIG. 2, the free ends of which bear in contact with radial tabs 30 of FIG. an annular web 32 intended to be fixed on a flywheel, for example on a secondary flywheel, a double damping flywheel. The radial edges 34 of the radial tabs each comprise two notches 36 in an arc, each intended to receive the radially inner portion and the radially outer portion of the end turn 14 or 24 of a spring 10 or 20. The part of the radial edge 34 which is located between the two notches 36 forms a centering nose of the end turn 14 or 24 of the spring, the relatively small circumferential dimension of the centering nose making it possible not to deteriorate the penultimate turn 16 or 26 of the spring. It is therefore very simple and very inexpensive to machine the radial edges 34 of the radial tabs 30 of the annular web to ensure the centering and support of the ends of the springs 10 and 20 of the torsion damper.

Claims (10)

  1. Torsional damper spring, consisting of a wire (12, 22) wound in non-contiguous helical turns in the free state, characterized in that at least one end of the spring, the last turn (14) , 24) is connected by a turn (16, 26) of reduced diameter to the preceding turn or antepenultimate turn (28) and extends in a plane substantially perpendicular to the axis of the spring.   2. Spring according to claim 1, characterized in that the coil (16, 26) of reduced diameter is housed inside the last turn (14, 24) and the antepénultième turn (18, 28).   3. Spring according to claim 1 or 2, characterized in that the last turn (14,24) is applied on the antepenultimate turn (18, 28).   4. Spring according to one of the preceding claims, characterized in that the wire (12, 22) is circular section, substantially oval or flat.   5. Spring according to one of the preceding claims, characterized in that it is bent in a circular arc and in that the turn (16, 26) of reduced diameter is on the radially outer side of the spring.   6. Spring according to one of the preceding claims, characterized in that at each of its ends, a last turn (14, 24) is connected by a turn (16, 26) of reduced diameter to the antepenultimate turn (18 28) of the spring and extends substantially perpendicular to the axis of the spring.   7. Dual damping flywheel, in particular for a motor vehicle, characterized in that it comprises springs (10, 20) of the type described in one of the preceding claims.   8. Double damping flywheel according to claim 7, characterized in that the ends (14, 24) of the springs are received in notches (36) arcuate formed on either side of a centering nose in the radial edges (34) of the radial tabs (30) of an annular web integral with a flywheel.   9. Double damping flywheel according to claim 7 or 8, comprising springs (10, 20) placed end to end and formed of son having different sections, characterized in that the springs (10, 20) placed end to end have not inverted and end turns which are substantially perpendicular to the axes of the springs and are applied to one another.   10. Double damping flywheel according to claim 9, characterized in that the son of the springs (10, 20) have substantially oval sections whose ends are formed by arcs of circle (cl, c'1, c2, c'2 ) of different radii and in that the sections of the wires of the springs (10, 20) placed end to end are inverted relative to each other, the arcs of circle (c2) of large radius of the sections of the wire of a spring (10) lying inside the turns of the spring and the arcs of circle (c'2) of large radius of the sections of the wire of the other spring (20) being outside the turns of the spring, for self-centering of the ends (14, 24) of the springs resting on one another.