DE19748634A1 - Device for supporting helical compression spring on shock absorbing strut of motor vehicles - Google Patents

Abstract

The device comprises a high pressure pipe (40) and a movable spring plate for compensation of the slanting adjustment conditioned through manufacturing tolerances between at least one end-winding (30) of the compression spring (14) and the corresponding spring seat (32'). The high pressure pipe is annular and is filled with an incompressible liquid (38). The diameter of the pipe is almost equal to that of the end-winding of the compression spring.

Description

The invention relates to a device for supporting a screw compression spring on a shock absorber of a motor vehicle suspension stuff, according to the preamble of claim 1.

In such suspensions with around the telescopic shock absorbers ordered helical compression spring (shock absorber) result from the Coil compression spring caused bending moments on the shock absorber possibly lead to slight jamming and comfort which can affect the wheel suspension (more Stick-slip effect).

The object of the invention is in a generic wheel suspension their response behavior (bouncing) with relatively little effort improve.

This object is achieved with the characteristic feature len of claim 1 solved. Advantageous further training of the Erfin can be found in the other claims.

According to the invention, means for compensating for the Manufacturing tolerances misalignment between at least one ner end turn of the helical compression spring and the corresponding Provide spring support. It is known that helical compression springs due to the manufacturing process relatively large tolerances un are subject. With regard to the lengths of the springs, it is therefore common divide them into tolerance groups and install them accordingly. So far, however, the end turns of the  Helical compression springs that have limited bending moments on the Can exercise piston rod of the telescopic shock absorber. Add to that manufacturing tolerances on the spring supports of the Suspension parts, e.g. B. of the cylinder tube of the telescopic joint damper attached spring plate or on the body support the helical compression spring. According to the invention, the response behavior the suspension or the telescopic shock absorber by elimination of the bending moments now caused by separate means for com pensation of this imbalance are provided.

The funds can e.g. B. provided on the spring support with incompressible liquid-filled, high-pressure hose after the "waterbed effect" hydraulic compensation of the skew manufactures. The high pressure hose can preferably be annular between the End turn of the helical compression spring and the spring support, e.g. B. one Spring plate, arranged and filled with a viscous liquid. By shifting the liquid inside the high pressure hose can create a uniform surface pressure and therefore a bending moment Free support of the helical compression spring can be achieved.

The compensation of the skew can also be done by a moveable Chen spring plate can be achieved, preferably with a spherical pad surfaces match each other when the Endwin is skewed can align the helical compression spring.

Several embodiments of the invention are in the following with wide ren details explained. The schematic drawing shows in

Figure 1 shows the upper portion of a suspension strut of a wheel suspension of a motor vehicle with a helical compression spring supported on spring plates as Federaufla conditions.

Fig. 2, the lower, on the cylinder tube of the telescopic shock absorber to the ordered spring plate of the helical compression spring with a high pressure hose integrated in the elastic damping ring;

FIG. 3 the spring plate according to FIG. 2 with an exaggerated inclination of the end turn of the helical compression spring;

. Figure 4 shows a cylinder tube of the telescopic shock absorber for bewegli chen lower spring plate of the strut of FIG. 1;

Fig. 5, the spring plate according to Figure 4 with an again exaggerated skew of the end turn of the screw pressure spring.

Fig. 6 shows a further embodiment of the lower spring plate with an extension sleeve and a ball bush as a portable storage; and

Fig. 7 finally shows an embodiment of the lower spring plate similar to Fig. 6, but with a cup movably supported over a rubber-elastic pad.

Fig. 1 shows essentially a shock absorber 10 of a wheel suspension of a motor vehicle, not shown, which is essentially composed of a telescopic shock absorber 12 and a helical compression spring 14 arranged around the telescopic shock absorber 12 . The strut 10 is articulated with the damper rod 16 of the telescopic shock damper 12 on the body 18 of the motor vehicle via an elastic bearing 20 , while the end of the damper cylinder 22, not shown, z. B. on a wishbone (not shown) of the wheel suspension is articulated.

The helical compression spring 14 is supported on its one end turn 28 by means of egg nes spring plate 24 via an elastic damping ring 26 on the body 18 of the motor vehicle, while the opposite end winding 30 is supported on the damper cylinder 22 via a second spring plate 32 and an elastic damping ring 34 . The spring plate 32 is, for example, welded to the damper cylinder 22 .

As far as described, the construction according to FIG. 1 corresponds to the state of the art, whereby the tilting of the end windings 28 , 30, as can be easily seen from the drawing, can exert bending moments on the telescopic shock absorber 12 . As a precautionary measure, he also mentions that the damping rings 26 , 34 and the elastic bellows 36 provided between the end turn 28 and the spring plate 24 can not compensate for this imbalance, since the compensation effect of the elastic intermediate layers is almost zero due to the high surface pressures.

According to FIGS. 2 and 3 'is as defined in the damper cylinder 22 spring support of the end turn 30 of the helical compression spring 14, an elastic damper ring 34' is provided between the lower spring plate 32, such in a sigkeit with a viscous, incompressible flues 38 (. B . Silicone) filled high pressure hose 40 is integrated. The high-pressure hose 40 is designed annular, the diameter of which corresponds approximately to the diameter of the end turn 30 of the helical compression spring 14 . The high-pressure hose 40 can consist, for example, of a fiber-reinforced, liquid-tight rubber mixture.

As can be seen from Fig. 3, can at a skew of the end turn 30 (see. Angle α between the longitudinal axis 42 of the telescopic shock absorber 12 and a vertical 44 through the support plane of the end turn 30 of the helical compression spring 14 ), the viscous silicone 38 in the move annular high pressure hose 40 as shown after the waterbed effect over the circumference in such a way that the misalignment damper 12 is compensated for without exerting bending moments on the telescopic shock. The elastic damping ring 34 'can deform due to the resilience of the high pressure hose 40 accordingly, without changing its damping properties or inadmissible material deformations can occur.

In Figs. 4 and 5 supported on the damper cylinder 22 spring plate 32 '' relative to the damper cylinder 22 is movable net angeord. Spherically formed support surfaces 46 are provided on the annular spring plate 32 '' on its inner circumference, which cooperate with cor-responding bearing surfaces 48 on an annular bead 50 of the damper cylinder 22 , and which have a wobble movement with corresponding oblique positions of the spring plate 32 '' relative to Damper cylinder of the 22 enable.

During assembly, the compression coil spring 14 (see FIG. FIG. 5) may be at a corresponding oblique position of the end turn 30 of the helical compression spring 14, the spring plate 32 '' with the interposed elastic damping ring 34 in such a way to the longitudinal axis 42 of the damper cylinder 22 obliquely move (cf. Vertical 44 on the support plane of the end turn 30 ) that bending moments are also avoided by the skewing of the end turn 30 on the telescopic shock absorber 12 .

Referring to FIG. 6, the lower spring seat 32 is welded to an extension sleeve 52, which covers with an annular space 54 the Dämpferzy linder 22 of the telescopic shock absorber 12 via a part of its length.

The extension sleeve 52 is hen in the region of the end face 56 penetrated by the damper rod 16 with spherical support surfaces 46 ', which correspond to corresponding bearing surfaces 48 ' of an annular ball bushing 58 .

The ball bushing 58 is in turn provided with a radially inwardly projecting collar 60 , which is supported on the end face 56 of the damper cylinder 22 .

The ball bushing 58 , which could also be attached directly (without the extension sleeve 52 ) to the damper cylinder 22 (e.g., as shown in FIG. 5 at reference number 50 ), enables, as described above, compensation for any misalignment of the end turn 30 of the helical compression spring 14 (cf. FIG. 1 in this regard) in that the spring plate 32 can move in the area of the predetermined free space 54 around the hinge point defined by the ball bushing 58 .

Finally, in FIG. 7 (identical parts are provided with the same reference numerals), the extension sleeve 52 ′ is formed into an inverted cup 62 with a spring plate 32 integrally formed thereon and a radially extending bottom 64 , the bottom 64 being formed on the end face 56 of the damper cylinder 22 is supported by an essentially disk-shaped, rubber-elastic support 66 .

The support 66 is additionally provided with a plurality of material-weakening recesses 68 which increase the flexibility of the support 66 . Furthermore, the support 66 has a cylindrical extension 70 which extends over the outer circumference of the damper cylinder 22 and thus effects a centering of the extension sleeve 52 'relative to the damper cylinder 22 .

The compensation of the skew of the end turn 30 of the helical compression spring 14 (see FIG. 1) that can be achieved with the support 66 is exaggerated in FIG. 7.

The means described in FIGS. 2 to 7 for compensating for the misalignment of the end turn 30 of the helical compression spring 14 can also be provided on the end turn 28 or only on this in the described or a similar form.

Claims (11)

1.Device for supporting a helical compression spring on a spring leg of a wheel suspension of a motor vehicle, Endwin applications of the helical compression spring, optionally with the interposition of an elastic damping ring, being supported on spring supports, characterized by means (high-pressure hose 40 ; movable spring plate 32 '') Compensation of the misalignment caused by manufacturing tolerances between at least one end turn ( 28 , 30 ) of the helical compression spring ( 14 ) and the corresponding spring support ( 32 '; 32 ''). 2. Device according to claim 1, characterized in that the means are formed by at least one on a spring support ( 32 ') provided with an incompressible liquid ( 38 ) filled, high pressure hose ( 40 ). 3. Apparatus according to claim 2, characterized in that the high pressure hose ( 40 ) is designed annularly with a diameter approximately equal to the diameter of the end turn ( 30 ) of the helical compression spring ( 14 ). 4. Device according to claims 1 to 3, characterized in that the incompressible liquid is viscous, especially silicone is sustainable.   5. Device according to one of claims 1 to 4, characterized in that the high pressure hose ( 40 ) in the damping ring ( 34 ') of the spring support ( 32 ') is integrated. 6. The device according to claim 1, characterized in that the Fe derauflage ( 32 '') is movable relative to the fixed support ( 50 ) on the structure ( 18 ) and / or on the strut ( 12 ) or damper cylinder ( 22 ). 7. The device according to claim 6, characterized in that the Fe derteller ( 32 '') cooperates as a spring support with spherical support surfaces ( 46 ) on corresponding support surfaces ( 48 ) on the receiving part or on the damper cylinder ( 22 ). 8. Device according to claims 6 and 7, characterized in that a ball bushing ( 58 ) is fixed on the damper cylinder ( 22 ) on which the spring plate ( 32 ) is movably mounted. 9. The device according to claim 8, characterized in that the Ku yellow rifle ( 58 ) with a radially inwardly projecting collar ( 60 ) on the damper rod ( 16 ) of the shock absorber ( 12 ) Durchdrun gene end face ( 56 ) is supported. 10. The device according to claim 9, characterized in that the Fe derteller ( 32 ) is provided with a damper cylinder ( 22 ) partially covering extension sleeve ( 52 ) which is movably supported on the ball bushing ( 58 ). 11. The device according to claim 6, characterized in that the Fe derteller ( 32 ) with a the damper cylinder ( 22 ) partially overdec Kenden inverted cup ( 62 ) is provided with a bottom ( 64 ) on a rubber-elastic pad ( 66 ) the end face ( 56 ) of the damper cylinder ( 22 ) penetrated by the damper rod ( 16 ) is movably supported.