FR2902166A1 - DOUBLE SHOCKWHEEL, IN PARTICULAR FOR MOTOR VEHICLE - Google Patents

Abstract

Double damping flywheel, particularly for a motor vehicle, whose torsion damper comprises short springs (30) screwed into long springs (24) and hysteresis pads (46) interposed between these springs and an annular web (28). ) integral with one of the flywheels, the hysteresis pads (46) for damping the relative oscillations of the flywheels at start and stop of the engine.

Description

The invention relates to a double damping flywheel, in particular for

  motor vehicle, comprising two coaxial flywheels which are supported and centered on one another, and a torsion damper arranged between the two wheels and having springs mounted in an annular housing of one of the wheels. These springs are circumferentially disposed around the axis of rotation of the flywheels and bear at their ends on radial tabs of an annular web integral with the other flywheels. It has been proposed to equip this double damping flywheel with a hysteresis slide, which consists of a cover, a support washer, a spring washer and a hysteresis washer and which makes it possible to to curb the relative oscillations of the flywheels at start and stop of the internal combustion engine of the vehicle, but this solution is expensive and relatively bulky. The object of the invention is in particular to avoid this drawback of the prior art. It proposes for this purpose a double damping flywheel, particularly for a motor vehicle, comprising two coaxial flywheels and a torsion damper arranged between the flywheels and comprising springs mounted in an annular housing of a first flywheel and coming into support at their ends on an annular web secured to the second of the flywheels, characterized in that hysteresis pads are interposed radially between the springs and the annular web and comprise means limiting their angular displacement relative to the annular web, as well as radially outer surfaces of concave annular shape coming into contact with the springs and radially inner annular surfaces bearing on the walls of the annular housing of the springs.

  The hysteresis pads according to the invention make it possible effectively to dampen the acyclisms and relative oscillations of the flywheels on starting and stopping the engine of the vehicle while their action decreases as the speed of rotation increases. because the centrifugal forces exerted on the springs cancel the support of the springs on the hysteresis pads. In a preferred embodiment of the invention, the aforementioned springs comprise long springs associated with short springs which are arranged in a central part of the long springs.

  This arrangement makes it possible, among other things, to have portions of springs of low stiffness at the ends of the long springs, which makes it possible to standardize the response of the shock absorber in the forward direction and in the retro direction. The short springs may have a turn diameter slightly less than or equal to that of the long springs and are screwed into the long springs. Advantageously, the short springs are straight springs in the free state, this arrangement for applying more effectively the hysteresis pads on the walls of the housing of the springs in the first wheel.

  The long springs may be straight springs in the free state, or may be preformed and bent in an arc to fit in the double damping flywheel. The ends of the short springs comprise immobilizing parts in rotation about their axis, each of these parts being mounted between two turns of a long spring and comprising a radial finger which extends between these turns and which cooperates by abutment with a cavity of the annular housing formed in the first flywheel. The long springs are themselves immobilized in rotation about their axis in these annular recesses, by pressing their ends 30 on walls of this housing.

  In general, the double damping flywheel according to the invention also has the following advantages: the connection between the coaxial springs does not pose any problem, the long and short springs are independent of one another, so that in the event of strong accelerations, for example at the time of starting, the friction of the springs on the guide chute provided in their annular recess is greater and the acyclisms generated by the motor are better damped, - if the second spring to a diameter slightly different, for example slightly lower than that of the first spring, there is a soft spring effect with damping due to the interpenetration of smaller diameter turns with the adjacent turns of greater diameter, which could not be realized until now. only by alternating turns of different diameters in the same spring.

  The invention will be better understood and other characteristics, advantages and details thereof will appear more clearly with the aid of the description which follows, given by way of example with reference to the appended drawings in which: FIG. 1 is a schematic view in axial section of a double damping flywheel according to the invention; - Figure 2 is a schematic cross-sectional view of this double damping flywheel, shown at rest; - Figure 3 is a view corresponding to Figure 2 and shows the torsion damper in the state of maximum compression of the springs; - Figures 4, 5 and 6 are schematic perspective views of the springs of the torsion damper; Figure 7 is a partial schematic view in axial section and on a larger scale, showing a hysteresis pad and a rotational immobilization piece of the short springs; FIG. 8 is a view corresponding to FIG. 7 and represents the immobilization means in rotation of the long springs;

  Figure 9 is a schematic perspective view of a hysteresis pad. The double damping flywheel of FIGS. 1 to 3 essentially comprises a primary flywheel 10 fixed by screws 12 at the end of a motor shaft or crankshaft 14 of an internal combustion engine of a motor vehicle and associated with an annular plate. flexible 16, a secondary flywheel 18 forming the reaction plate of a clutch 20, and a torsion damper 22 which is mounted between the two flywheels 10 and 18 and which serves to transmit the driving torque of steering wheel to another and to absorb and dampen vibrations and relative oscillations between the wheels resulting from the acyclisms generated by the internal combustion engine. The torsion damper 22 comprises long springs 24 with helical turns, circumferentially oriented, which are arranged in an annular housing of the primary flywheel 10 and which bear at their ends on radial tabs 26 of an annular web 28 fixed at its inner periphery by rivets on the secondary flywheel 18. In the embodiment of Figures 2 and 3, the long springs 24 are two in number and each extend a little less than 180 at rest, the radial tabs 26 on which rely the ends of the springs being diametrically opposed. These long springs 24 are associated with short springs 30 with helical turns whose turns have a diameter substantially equal to or slightly less than, for example, that of the turns of the long springs 24, the short springs 30 having a length which is typically between half and two-thirds of the length of the springs 24 and being screwed into the long springs so as to be substantially in the middle thereof, as shown in Figures 2 and 6.

  The springs 24 and 30 are arranged in an annular housing formed by the outer peripheral portion of the primary flywheel 10 and by an annular cover 32 fixed on the periphery of the primary flywheel, and are guided in this annular housing by the annular-shaped ducts 34 interposed radially between the springs and the outer wall of the annular housing. The short springs 30 are immobilized in rotation about their axis by plastic parts 36 which are each mounted between two turns of a long spring 24 and which comprise an anti-rotation finger 38 which extends radially outwards between the turns of the long spring 24 to engage either between two inner surfaces of the annular housing of the springs as shown in Figure 1, or between the outer peripheral flange 40 of the primary flywheel 10 and / or the chute 34 and the annular cover 32 as shown in FIG. 7. Each piece 36 has substantially the same outside diameter as the turns of the springs on one half of its circumference, the other half of its circumference having a smaller outer diameter allowing the winding of a half-turn The two parts of different diameters of the parts 36 are connected by two diametrically opposite radial faces 42 which are turned on the opposite side. opposite the finger 38 and which form stops for the ends of the short spring 30, the latter ending in two lower half-turns whose ends bear on a radial face 42 of one of the parts 36 and on the radial face 42 diametrically opposite the other piece 36 to prohibit the rotation of the spring 30 about its axis. The ends 44 of the long spring 24 extend tangentially, with respect to the turns, in the direction of the axis of rotation of the flywheels and protrude slightly outside the turns of the spring, as shown in FIG. 8, these ends 44 coming rely on stops formed on the primary flywheel 10 and the annular cover 32, respectively, to prohibit the rotation of the spring 24 about its axis.

  Hysteresis pads 46 are interposed radially between the middle portions of the spring pairs 24, 30 and the annular web 28.

  6 with a possibility of limited rotation relative to the annular web by the presence of teeth 48 formed projecting on the radially inner surface of the pads 46 and meshing with clearance with an external toothing 50 of the annular web 28.

  The outer peripheral surface 52 of the pads 46 is a concave annular surface which conforms to the shape of the springs 24 and 30, while the inner peripheral surface of these pads forms a V whose branches 54 follow the shapes of the inner surfaces of the housing of the springs formed. by the primary flywheel 10 and the annular cover 32 (Figure 7).

  The teeth 48 of each hysteresis pad 46 are joined by a radial wall 56 on one of their sides, this radial wall 56 extending along the toothing 50 of the annular web 28 and forming an anti-tilt bearing surface. skating. When stopped, the hysteresis pads 46 are applied to the primary flywheel 10 and the annular cover 32 by the springs 24 and 30. It is advantageous for the short springs 30 to be straight springs in the free state. When these springs are mounted in the annular housing of the primary flywheel as shown in Figure 2, their middle portion exerts on the hysteresis pads 46 a radial force directed towards the axis of rotation. In the embodiment shown, the short springs 30 are longer than the hysteresis pads 46. The long springs 24 can also be straight free springs, which are less expensive than curved springs in an arc. .

  Alternatively, the long springs 24 may however be springs preformed by bending to facilitate their mounting and that of the short springs 30 in the annular housing of the primary flywheel 10. During operation of the double damping flywheel, the relative oscillations between the two wheels due to the acyclisms of the internal combustion engine of the vehicle, are absorbed by compression and expansion of the springs 24 and 30 and are braked by the friction between

  7 on the one hand the springs and the hysteresis pads 46 and on the other hand between these pads and the conjugate surfaces of the primary flywheel 10 and the annular cover 32. This friction is most important at the start and stop of the engine. Then, when the engine rotates, centrifugal forces are exerted on the springs 24 and 30 and gradually reduce the radial forces applied by these springs on the hysteresis pads. The vibration filtering by the double damping flywheel according to the invention is excellent. In addition, this double damping flywheel can use straight springs, less expensive than curved springs, and hysteresis pads which are less expensive and less bulky than the hysteresis drawers of the prior art.

Claims (14)

  1. Dual damping flywheel, in particular for a motor vehicle, comprising two coaxial flywheels (10, 18) and a torsion damper (22) arranged between the flywheels and comprising springs mounted in an annular housing of a first one of the flying and bearing at their ends on an annular web (28) integral with a second flywheel, characterized in that hysteresis pads (46) are interposed radially between the springs (24, 30) and the annular web (28) and comprise means limiting their angular deflection with respect to the annular web, these hysteresis pads having radially outer surfaces (52) of concave annular shape coming into contact with the springs and radially inner annular surfaces (54) coming from resting on walls of the annular housing of the springs.   2. Double damping flywheel according to claim 1, characterized in that the hysteresis pads are interposed at rest between a middle portion of the springs (24, 30) and the annular web (28).   3. Double damping flywheel according to claim 1 or 2, characterized in that the springs comprise long springs (24) and short springs (30) disposed in a central portion of the long springs.   4. Double damping flywheel according to one of the preceding claims, characterized in that the hysteresis pads (46) are, at rest, applied radially by the springs on the walls of the annular housing of the springs.   5. Double damping flywheel according to one of the preceding claims, characterized in that the hysteresis pads (46) comprise teeth (48) which meshes with clearance with a toothing (50) of the annular web (28). 9   6. Double damping flywheel according to one of claims 3 to 5, characterized in that the short springs (30) have a turn diameter smaller than or equal to that of the turns of the long springs and are screwed into the long springs.   7. Device according to one of claims 3 to 6, characterized in that the short springs (30) have a length greater than that of the hysteresis pads.   8. Double damping flywheel according to one of claims 3 to 7, characterized in that the short springs (30) are straight springs in the free state.   9. Double damping flywheel according to one of claims 3 to 8, characterized in that the long springs (24) are straight springs in the free state.   10. Double damping flywheel according to one of claims 3 to 8, characterized in that the long springs (24) are preformed springs arcuate in the free state.   11. Double damping flywheel according to one of claims 3 to 10, characterized in that the ends of the short springs (30) comprise parts (36) of immobilization in rotation about their axis in the aforementioned annular housing.   12. Double damping flywheel according to claim 11, characterized in that each piece (36) of immobilization in rotation is mounted between two turns of the long spring (24) and comprises a radial finger (38) which extends between these turns and cooperates by abutment with a cavity of the annular housing receiving the springs.   13. Double damping flywheel according to one of the preceding claims, characterized in that the long springs (24) are immobilized in rotation about their axis in the annular housing, by pressing their ends (44) on the walls of this housing .   14. Double damping flywheel according to one of claims 3 to 13, characterized in that the torsion damper (22) comprises two long springs (24) each extending a little less than 180 at rest, two short springs (30) each mounted in a long spring (24) and two hysteresis pads (46) each mounted between a pair of springs (24, 30) and the annular web (28).