FR2577293A1 - Double element spring for vehicle clutch - Google Patents

Abstract

The plate spring for a vehicle clutch consists of two springs (1,101) one supported on the other. Both springs are annular (2,102) with radial fingers (3,103) sloping inwards and upwards away from the ring. The fingers on the upper ring (1) are offset between the fingers of the lower ring (101). The angles of the two sets of fingers are selected so that when the springs are under tension, their free ends are parallel, and acting at the same contact point with the same clutch plate. Their axial levels are different.

Description

"Disc spring assembly."
The invention relates to a disc spring assembly, such as a clutch, comprising an annular base body and tongues which leave therefrom and are separated from each other by cutouts.

 In friction clutches, the disc springs can be used to produce the clamping force necessary to transmit the desired moment; but they are also particularly advantageous as return springs for hydraulically actuated clutch pistons, as they are used for example in automatic gearboxes. In addition, such disc springs can be used on clutches as a lever element for transmitting clamping forces, the clamping force then being produced, for the clutch in question, by a piston, for example with hydraulic actuation, and amplified by means of '' lever amplification produced by disc springs.

In the case of hydraulically operated clutches used in gearboxes, the spaces available for the installation of the various construction elements are very tight, which greatly complicates the design of the parts, because they must not only fill their intended function, but also have a long service life. This is also encountered in particular for disc springs with dynamic loading, which must for example guarantee the return of the piston of a hydraulically operated clutch, because these springs -discs must provide a high force for the space they have, so that, when the pressure disappears, the piston is quickly recalled and therefore the clutch opens quickly;
The object of the present invention is to create disc spring assemblies, such as clutches, which have improved operation and a longer service life, together with simple, rational and inexpensive manufacturing. relates in particular to the creation of disc springs with higher dynamic resistance for this type of assemblies, as well as the space-saving installation of these disc springs in these assemblies.

 According to the invention, in the case of disc spring assemblies of the type mentioned at the beginning, this object is achieved by means of stacking one on the other at least two disc springs of the same direction, c that is to say with the positioning angle directed in the same direction; and that the tabs of one of the disc springs - seen in the direction of the periphery - are placed respectively between two tabs of the other disc spring. Thanks to the use of two stacked disc springs of this type, we can on the one hand study the ratio of the thickness to the width of the annular base body of the different disc springs in a more fcvorable way than would be the case if we used a single disc spring which should bring the same force and should be, on the other hand, reduced to the axial size required, this because we can nest the tongues of the two disc springs - seen in the axial direction. Thanks to the reduction, which can be obtained, in the thickness of the base body of the various disc springs, its life is increased with regard to dynamic stresses.

 I1 can be particularly advantageous that the various disc springs have tongues directed radially inwards, it being specified that it can be particularly indicated that the axial profile of the tongues of one of the disc springs deviates from the axial profile tabs on the other disc spring.

 I1 it is advantageous that one chooses there the axial profile difference between the tongues of the different disc springs so that the tongues of one of the disc springs are housed, at least as regards the areas of the points of their tongues, seen in the axial direction, between the tongues of the other disc spring. It may be indicated that the profile of the tongues of the disc springs has a shape such that at least the tongue points of the two disc springs are, at least approximately, at the same level - and this also in the unstressed state of the springs - discs.

 Although it may be interesting, for many use cases, that the base bodies of the two disc springs have a different installation angle, it is interesting for many use cases, that the base bodies of the springs -discs have the same positioning angle, so that they are placed entirely on top of each other.

 It may be advantageous for the tongues of at least one of the disc springs to have at least one section which has the same angle of positioning on the base body. I1 may be appropriate here that this section represents between 10 and 70% of the length of a tongue.

 In addition, it may be advantageous for the tongues of at least one of the disc springs to have at least one zone which has a setting angle greater than that of the annular base body of the disc spring. It may be particularly useful here for the zones with the greatest angle of positioning to be the radially interior zones of the tongues. Furthermore, it may be particularly advantageous for the radially interior zones of the tongues of the two disc springs to have approximately the same angle. of positioning, it being specified that it may then be particularly advantageous for the sections and the radially inner zones of the disc spring to be adapted to one another so that the radially inner zones of tongues come to overlap, at least approximately, one inside the other along their zone of the same angle of placement.

 Let us now explain 1 invention in detail using Figures 1 to 6.

FIG. 1 represents, in section, two disc springs mounted in an assembly in accordance with the invention,
FIG. 2 is a view, on a reduced scale, of the stacked disc springs, in the direction of arrow II in FIG. 1,
FIGS. 3 and 4 respectively represent a half-section of one of the disc springs,
FIGS. 5 and 6 are respectively a detail, on an enlarged scale, of the top view along arrow Z, of a disc spring corresponding to FIGS. 3 and 4.

 The disc springs 1,101 shown in the figures respectively have an annular base body 2,102 from which extend the tongues 3,103 directed radially inwards.

Between the tongues of the disc springs 1,101 there are cutouts 4,104.

 The cutouts 4,104 of the disc springs 1,101 are designed so that - seen in the peripheral direction - the tongues of the spring - disc 1 can be accommodated respectively between two tongues 103 of the disc spring 101 and vice versa.

 In the case of the embodiment shown, the tongues 3,103, apart from their axial profile, and the cutouts 4,104 have at least approximately the same shape. This has the advantage that the two springs can be produced. 1,101 discs with the same stamping tools.

 As can be seen in FIGS. 3 and 4, the basic bodies 2,102 of the disc springs 1,101 have, at least approximately, the same angle of positioning 5,105, so that when stacked, or that the 'one is placed one on the other, the two disc springs 1,101, the basic bodies 2,102 come one on the other.

The tongues 3.103 of the disc springs 1.101 respectively have a section 6.106 which has the same angle of positioning 5.105 as the basic body 2.102 of the disc springs 1.101. The section 6 of the upper disc spring 1, seen according to the arrow
X of FIG. 1, is longer than the section 106 of the spring -lower disc 101. Zones 7,107, which have a setting angle 8,108 greater than that of the corresponding basic body 2,102, and which include the tips of the tongues 9,109, are connected respectively, inwards in the radial direction, to the section 6,106 which has the same angle of installation 5,105 as the respective base body 2,102. In the embodiment shown, the areas 7,107 of the two disc springs 1,101 have the same positioning angle.

 The Longuettes 3,103 of the two disc springs 1,101 are fitted one on the other so that the tips of the tongues 9,109 of the two disc springs 1,101, when stacked, arrive at approximately the same height in the axial direction. In the case, from the embodiment shown, this is obtained by means that the length of the sections 6 of the tongues 3 of the disc springs is dimensioned so that the zones 7,107 of the two disc springs 1,101, seen according to the axial direction X, are nested one in the other in such a way that they arrive at least approximately at the same level on the length where they have a common profile.

 Due to the small difference in length between the outer pivot diameter, formed by the lower edge of the respective base body and the inner pivot diameter, formed by the upper edge of the respective tongue tips, during a common pivoting of the stacked disc springs, there is an insignificant offset or displacement between the points of the tongues, so that the points of the tongues may have a bearing diameter of which the difference is of little importance .

 Figure 1 also indicates in dashed-punctured a disc spring 201 which can be combined with the disc spring 101. The disc spring 201 has an entirely different profile from that of the disc spring 101. Seen in section, this spring -disc 201 appears rectilinear and rests, by the radially outer zone of its base body 202, against the disc spring 101 and the tips 209 of its tongues 203 are housed respectively between two tongues 103 of the disc spring 101. The disc spring 201 is designed in such a way that, at least in the assembled state of the assembly, its tongue tips 209 are placed at least approximately on the same diameter as the tongue tips 109 of the disc spring 101. The combination of a disc spring 201 with a disc spring 101 has the advantage that between the two disc springs 201, 101 there remains an axial free space and that the friction, or hysteresis, which appears during the pivoting of the two disc springs is less than in the case of a combination in which the two disc springs rest directly on each other over the entire surface of their basic body.

 As can also be seen in FIG. 2, seen in the peripheral direction, the sections 4 of the disc spring 1 and the sections 104 of the disc spring 102 intersect so that, seen in the axial direction, it forms respectively a cut 10 between two neighboring tongues 3,103.

 Figure 1 further shows how the two disc springs 1,101 are mounted in a plate clutch, not shown in detail. The disc springs 1,101 bear radially inwards, by their tongue points 9,109, against a fixed part in the axial direction 11, and, by means of the external diameter of the disc spring 102, recall in their position starting the annular piston 12 of the lamella clutch not shown in detail.

Claims (12)

 1. Disc spring assembly, such as a clutch, comprising an annular base body and tongues which leave therefrom and are separated from each other by cutouts, characterized in that at least two springs are stacked- disks of the same direction; and in that the tongues (3,203) of one of the disc springs - seen in the direction of the periphery - are placed respectively between two tongues (103) of the other disc spring.  2. Assembly according to claim 1, characterized in that the disc springs (1,101,201) have tongues (3,203) directed radially inwards.  3. Assembly according to any one of claims 1 or 2, characterized in that the axial profile of the tongues (3,203) of one of the disc springs (1,201) deviates from the axial profile of the tongues (103) of the 'other disc spring (101).  4. Assembly according to any one of claims 1 to 3, characterized in that the tongues (3,103,203) of one of the disc springs (1,202) are housed, at least as regards the areas of the tips of their tongues (9,209), seen in the axial direction, between the tongues (103) of the other disc spring (101).  5. Assembly according to one of claims 1 to 4, characterized in that the profile of the tongues (3,103,203) of the disc springs (1,101,201) has a shape such that at least the tips of the tongues (9,109,209) of the two springs- discs (1,101; 101,201) are located, at least approximately, on the same level.  6. Assembly according to one of claims 1 to 5, characterized in that the base body (202) of the two disc springs (1,101) has the same positioning angle (5,105).  7. Assembly according to one of claims 1 to 6, characterized in that the tabs (3,103,203) of at least one of the disc springs (1,101,201) have at least one section (6, 106,203) which has the same placement angle as the base body (2,102,202).  8. Assembly according to claim 8, characterized in that the section (6) represents between 10 and 70% of the length of a tongue (3).  9. An assembly according to any one of claims 1 to 8, characterized in that the tongues (3,103) have at least one zone (7,107) which has a setting angle greater than that (5,105) of the annular base body (2,102) of the disc spring (1,101)  10. An assembly according to claim 9, characterized in that the zones (7,107) of greatest angle of introduction (8,108) are the radially inner zones of the tongues (3,103).  11. An assembly according to any one of claims 9 or 10, characterized in that the radially inner zones (7,107) of the tongues (3,103) of the two disc springs (1,101) have approximately the same angle of positioning (8,108) .  12. An assembly according to any one of claims 1 to 11, characterized in that the two disc springs (1,101) have, on at least one area (7,107) of their tongues (303), at least approximately the same angle of placement (8,108); and in that the disc springs (1,101) are stacked one on the other in such a way that the radially interior zones (7,107) of the tongues (3,103) come to overlap, at least approximately, one in the other along their area (7,107) with the same placement angle (8,108).