DE2820585C2 - Independent suspension of the steerable front wheels of motor vehicles - Google Patents

Description

The invention relates to the independent suspension of the steerable front wheels of motor vehicles using e <ne *> strut, consisting of a telescopic shock absorber and a helical spring surrounding this, serving as a wheel spring, the shock absorber housing being rigidly connected to the steering knuckle bearing the wheel and the The piston rod of the telescopic shock absorber as well as the wheel spring are elastically supported on the vehicle body and the piston rod and the upper spring plate of the wheel spring are rotatably mounted in a pivot bearing together with respect to the vehicle body around their longitudinal axis.

In the case of strut wheel suspensions in particular, for reasons of driving comfort it is important that the To a large extent to keep road-related impacts away from the vehicle body. For that purpose it is known, both the spring forces and the damper forces to be included in the structure using elastic means. It is also known to use the spring and Damping forces via a common elastic support bearing and also via separate elastic support bearings (decoupled version) to be introduced into the vehicle body.

At the same time there is for strut suspensions for dhi steerable front wheels of motor vehicles Eüfriöglichung the turning of the wheels but also the Demand for a possibility of rotation on the one hand between the one connected to the steering knuckle Shock absorber housing or the piston length elastically supported on the vehicle body and the vehicle body and to change between the wheel spring with its upper and lower spring plate opposite

the vehicle body or shock absorber housing. It goes without saying that there is mutual rotation between the shock absorber housing and the piston rod the piston and the housing or the cylinder of the telescopic shock absorber possible. Such a twist however, there is considerable friction involved. In addition, the seals in the piston and Guide camps are additionally stressed and thereby reduced in their lifetimes.

In DE-OS 24 47 821 are some embodiments illustrated for the support bearings of struts. Then it is known the spring and damper forces either via a common rubber mount or via separate rubber mounts in the vehicle body transferred to. When using a common rubber bearing for the transmission of the spring and Damper forces is a thrust ball bearing between The shock absorber and vehicle body are switched on. In this way, both the piston rod and the also the wheel spring with its upper spring plate when striking the baths against the vehicle body twist; this execution is liable but de. Disadvantage. that the spring and damper forces from one single elastic bearing must be transferred. When using separate rubber bearings for the Transmission of the spring and damper forces is either not at all special in this publication Pivot bearings provided or only one / wipe the lower spring plate of the wheel spring and the shock absorber housing, whereby a mutual rotation of the upper and lower spring plate enables or is facilitated. For the twist /. Wipe the The piston rod and the vehicle body is, however, in the exemplary embodiment with the decoupled support the spring and damper forces no special pivot bearing is provided, so that when the Wheels the shock absorber housing on the piston and in the guide bearing opposite the one in the vehicle body must adjust the pushed-off piston rod.

The definition is based on the task of a Strut suspension of the steerable front wheels the wheel spring and damper forces in a decoupled manner, d. H. independently of each other via separate support bearings elastically transferred into the vehicle body / u, the rotation around the spring strut sleeve and the Shock absorber housing or the piston rod as well as the rigidly connected to the shock absorber housing lower spring plate of the wheel spring relative to the vehicle body in a cm /, gene pivot bearing takes place.

This object is achieved according to the invention in that the elastic support of the telescopic shock absorber and the wheel spring on the vehicle body in a known manner independently of one another in separate supports / bearings takes place and that the pivot bearing / wipe a common component of the two elastic support bearings and the vehicle body is arranged.

Due to the arrangement according to the invention, it is a suspension strut with decoupled support bearings for the telescopic shock absorber and the wheel spring possible, a slight rotatability with respect to the Vehicle structure both for the shock absorber piston rod and for the upper spring plate of the wheel spring to achieve using only a single pivot bearing. A gör'nger torsional resistance in the pivot bearing results in a correspondingly reduced steering effort on the steering wheel.

According to a preferred embodiment of the invention, a Rqdinl ball bearing serves as a rotary bearing, its Inner ring in the formed from the inner edge of the upper wheel spring distributor or connected to it nen outer sleeve of the elastic support bearing of the ^ piston rod of the telescopic shock absorber is mounted and its outer ring is fixed directly to the vehicle body or to the vehicle body connected component supported.

Another feature of the invention is that ίο that the elastic support bearing of the telescopic shock absorber l as a button bushing surrounding its piston rod is made of rubber or a similar elastic material and that the inner edge of the upper The wheel spring plate is bent upwards in the axial direction of the telescopic shock absorber and with this bent part concentrically enclosing the elastic button bushing and that on its outer circumference of the Inner ring of the radial ball bearing is mounted.

Such a designed strut support bearing has the advantage that by means of the ball bearing in the support bearing Wheel spring and the piston rod, including the surrounding shock absorber housing, rotatable together is stored, i.e. when the wheel is locked, there is no relative rotation between the piston rod and surrounding damper housing instead. As a result, the de.i steering effort increasing friction between Piston and cylinder of the shock absorber kept small. This is particularly beneficial if the piston rod bends excessively due to bending stresses and is hit by the Sliding points between piston and cylinder increased friction due to jamming.

The necessary angular mobility of the piston rod and the upper wheel spring plate in the support bearing of the ij strut is according to a further feature of the Invention improved in that the upwardly bent inner edge of the wheel spring plate inside Double-cone-shaped and groove this section in the corresponding double-cone-shaped waisted trained button socket engages.

Some embodiments of the invention are shown in FIG Drawing shown and are described in more detail below. It shows

1 shows a schematically illustrated Gerimtanord- ⁴ > tion of a wheel guide by means of a strut according to the invention and

Fig. 2 to 4 each compared to FIG. 1 enlarged and partial representations of the upper area of the wheel suspension.

i “In Fig. I the one with the car body is fixed associated wheel installation is designated by 10. A steerable impeller 12 mounted on a stub axle 13 is ί> τι Car body by a handlebar 14 and a shock absorber 16 firmly connected to the F.aduäger with inside displaceable shock absorber piston rod 15 out.

Stuck with the casing of the telescopic shock absorber 16

connected is a lower spring plate 17 on which one end of a helical spring 18 forming the associated wheel spring is supported. The lower

λ Federtellcr 17 is thus carried by the housing of the telescopic shock absorber 16.

An upper wheel spring plate 15 bifdpt the upper one Support of the wheel spring 18.

As can be seen in particular from FIGS. 2-4, the shock absorber ^ piston rod 15 has a tapered Bearing pin 20 on. On the bearing pin is a button bushing 21 made of rubber as an elastic support bearing put on. For the axial fixation and pre-tensioning of the

Button bushing 21 clicnl on the one hand a collar 22 on the Piston rod 15, on the other hand a disk 23 with a screw thread 24 on the bearing pin Fixing nut 25.

In the case of the right ί in the embodiment according to FIG The variant shown by the center line 26 of the piston rod 15 are Slütz bearing plates and fastening nuts designed in one piece and numbered 27.

From Fig. 2-4 it is also clear that the elastic button bushing 21 in the middle area double-ended nish is designed to be waisted. This, in cooperation with the upper wheel spring plate 19 a Carclanic resilience of the piston rod 15 is achieved.

In the embodiment according to FIG. 2, the upper wheel spring plate, designated here as 19.1, consists of two parts 28 and 29, between which a rubber ring 30 is vulcanized as an elastic support bearing. By bilateral constrictions 31 and 32 of the rubber ring Jö receives a biconcave shape, thereby achieving m gimbal flexibility of the upper Radfedertellers 19.7.

As can also be seen from FIG. 2, the part is 29 of the upper wheel spring plate 19a on its inner edge

33 formed bent upwards. The edge bent upwards> i has double-conical surfaces on the inside

34 and 35 on. which engage in a correspondingly shaped constriction of the button bushing 21. Of the Upper wheel spring plate I9a is thereby fixed in the axial direction. On its outer circumference 36, on the other hand, is the according to] o Inner edge 33 of the upper wheel spring plate 19a, which is bent at the top, is cylindrical. It is used here for Storage of the inner ring 37 of a radial ball bearing. The inner ring 37 of the radial ball bearing is here on the one hand by a collar 38 on the upper wheel spring plate 19a, on the other hand by a snap ring 39 in Axialrichiung held. The outer ring, designated 40, of the radial ball bearing is supported against it on a sheet metal part 41 bent downwards. which by a screw 42 with the not shown Vehicle body is firmly connected.

In the case of FIG. 2 can be seen and described in the above upper strut support thus the damping forces from the shock absorber piston rod 15 initially into the button bushing 21 and from -45 there further introduced into the vehicle body via the radial ball bearing 37/40, whereas the wheel forces from the upper wheel spring plate 19a directly into the radial ball bearing 37/40 and from there in turn into the Vehicle body can be transferred. In relation to a ϊο Rotation of the strut on the other hand, piston rod 15 and wheel spring 18 act like a single body, the by means of the ball bearing 37/40 without significant frictional resistance to the vehicle body Can twist.

The embodiment according to FIG. 3 is distinguished from FIG. 1 essentially only by one different design of the upper one hereby designated 196 Radfedertcllers off. According to FIG. 3 this also consists of two parts 43 and 44, between which as elastic support bearing a rubber ring 45 is arranged. This rubber ring is in contrast to the embodiment according to Fig. 2 only between the correspondingly conically bent ends of the spring plate parts 43 and 44 pinched. Another difference compared to the embodiment according to FIG. 2 is seen in that the Slützring, designated here with 336, for the Ball bearing 37/40 is not made in one piece with wheel spring plate part 44. but at 46 with this part is welded. whereby the upper wheel spring plate 196 is easier to manufacture.

A front axle buffer is denoted by 47 in FIG. 3, However, this also applies to the embodiments according to FIG. 2 or 4 can be provided.

The advantage of the configuration of the upper wheel spring plate 196 shown in FIG. 3 consists in its particularly large cardanic compliance, which is a consequence of the corresponding design of the bearing parts 43.44.45 is.

The embodiment according to FIG. 4 differs again of the embodiments according to FIG. 2 or 3 essentially only by the design of the upper Radfedertdler 19c. The remaining parts are therefore for the sake of better clarity with the the same reference numerals as in the embodiments according to FIG. 2 and 3.

The upper wheel spring plate 19c is in turn made in two parts from parts 48 and 49. The two in Axially opposite ends of the parts 48 and 49 are here each shaped like a circular ring include between them an inserted molded rubber O-ring 50 as an elastic support bearing.

The inner edge of the wheel spring plate part serving as a camber ring for the inner ring 37 of the ball bearing 37/40 49 is double-conical in shape and fixes the inner ring 37 of the ball bearing in both axial directions.

The particular advantage of the embodiment according to Fig. 4 is also in a special gimbal Mobility of the upper split wheel spring plate 19c due to the loosely inserted O-ring 50 Molded rubber.

For this purpose 2 sheets of drawings

Claims (11)

Patent claims: 1. Using independent suspension of the steerable front wheels of automobiles a shock absorber, consisting of a telescopic shock absorber and a surrounding, Helical spring serving as a wheel spring, the shock absorber housing with the one supporting the wheel The steering knuckle is rigidly connected and so is the piston rod of the telescopic shock absorber how the wheel spring are elastically supported on the vehicle body and where piston rod and upper Spring plate of the wheel spring in a pivot bearing together with respect to the vehicle body around their Longitudinal axis are rotatably mounted, thereby characterized in that the elastic support of the telescopic shock absorber (16) and the Wheel spring (18) on the vehicle body (10) in a known manner independently of one another in separate Support bearing η (21 and 30, 45 or 50) takes place (decoupled version) and that the pivot bearing (37/40) between a common component of the two elastic support bearings (21 and 30, 45 or 50) and the vehicle body (10) is arranged. 2. Independent wheel suspension according to claim I _1, characterized in that a radial ball bearing (37/40) is used as a pivot bearing. its inner ring (37) in the outer height of the elastic support bearing (21) of the piston rod of the trlescope, formed from or connected to the inner edge (33a, 336 or 49) of the upper spring plate (19a, 196 or 19c; Oßdämpfers (16) is mounted and the outer ring (40) is supported directly on the vehicle body or? in a component (41) firmly connected to the vehicle body. 3. Independent wheel suspension according to claim I and 2, characterized in that the elastic support bearing of the telescopic shock absorber (16) is designed as a button bushing (21) surrounding its piston rod (15) made of rubber or a similar elastic material and that the inner edge {3 \ a. 33b or 49) of the upper wheel spring plate (19a. 190 or 19cV is bent upwards in the axial direction of the telescopic shock absorber (16) and with this bent part surrounds the elastic button bushing (21) concentrically and that on its outer circumference (36) the inner ring (37) of the radial ball bearing is supported. 4 Independent wheel suspension according to Anspn i. characterized in that the inner edge (33a, 33b or 49) of the railfcd plate (19a, 196 or 19c) bent towards oh-jn is double-cone-shaped on the inside and engages with this section in the button bushing (21) which is correspondingly double-cone-shaped and tapered. 5. Independent wheel suspension according to claim 3 and 4, characterized in that the inner edge of the upper wheel spring plate (19a. 196 or 19c,) is bent or bent in such a way that it is in Axial direction of the shock absorber (16) at least on one side a stop (38) for the The inner ring (37) of the radial ball bearing forms (Fig. 4). 6 <Independent wheel suspension according to claim 5, characterized in that the double-conical shaped inner hand of the upper wheel spring plate (19c,) on the outside in both axially one Stop for the inner ring (37) of the ball bearing forms (Fig. 4). 7. Independent wheel suspension according to one or more of the preceding claims, characterized characterized in that the upper wheel spring plate (19a, 196 or 19t ·; consists of two parts (28 and 29 or 43 and 44 or 48 and 49), between which a rubber ring (30, 45 or 50) is arranged. 8. Independent wheel suspension according to Airspruch 7, characterized in that the rubber ring (30) between the two parts (28 and 29) of the wheel spring plate (19ajeinvulkanisiert (Fig. 2). 9. Independent wheel suspension according to claim 7, characterized in that the rubber ring (45 or 50) between the two parts (43 and 44 or 48 and 49) of the wheel spring plate (196 or 19c; loose is interposed (Figs. 3 and 4). 10. Independent suspension .räch claim 9. characterized in that the two parts (43 and 44) of the wheel spring plate (196; in opposite directions are bent conically and that between the two approximately parallel Conical surfaces a correspondingly hollow conical rubber ring (45) is clamped (Fig. 3). 11. Independent wheel suspension according to claim 10, characterized in that the two in Axialrichiuiig opposite ends of the two wheel spring plate parts {48 and 49) are each shaped like a circular ring and between them one Include the inserted molded rubber O-ring (50) as an elastic support bearing (FIG. 4).