NL8703122A - Vehicle air suspension - has axle mechanism including leaf spring with varying thickness - Google Patents

Abstract

An axle mechanism for a vehicle with air suspension includes a leaf spring at one side hinged on a transverse spindle, and at the rear allowing horizontal movement w.r.t. the vehicle frame. The centre of the leaf spring has a thicker part connected to a support for the transverse mounted wheel shaft. Two such leaf springs are on each side of the vehicle fixed to form a U-shaped stabiliser. Air springs are fitted between frame and leaf springs. Under and against the leaf spring (3) in the thickest part, fits a transverse spindle (4). A platform (5), spring and transverse spindle are secured with straps (12). The platform retains a shock absorber (15).

Description

NO 34906 GB / ihi 1 y%

Axle suspension device for a Tournig air suspension set

The invention relates to an axle suspension device for a vehicle with air suspension.

It is known that air springs for resiliently supporting the axles of vehicles have the advantage that the stiffness is so dependent on the load that the spring frequency and thus the spring comfort can remain practically the same despite the difference in loading. A drawback is, however, that such air springs have hardly any transverse stability in themselves, so that particularly heavy demands are made on external stabilizers.

It is known in this connection to use rod systems, in which hinged at both ends, approximately horizontal rods serve for guiding the shaft and the air springs while absorbing the horizontal forces. Such constructions are only applicable to a limited extent, especially in view of the space they occupy, cause a great deal of wear due to the many pivot points and cause complications due to the separate roller stabilizing means that are required.

It is known in this connection to bear an air spring on a frame pivotable and rigid-suspension arm, which is fixedly connected to the shaft or, with rotating shaft, with a carrier therefor, the two pivoting arms, each on one side of the vehicle, terminate directly behind the air springs and form a U-shaped roll stabilizer with that axle or carrier. Shock absorbers can engage part of the frame on the one hand and that arm or a part attached thereto on the other hand. In order to prevent excessive unwanted axle tilt, the length of the support arm is limited to a minimum length for steering axles and driven axles.

High demands are placed on the hinges for these arms. They must be able to pivot for a long time without wear without significant maintenance, while they must be able to absorb high transverse forces, which creates constructional problems.

To improve on this, it has been proposed to provide a thin leaf spring along that arm, which leaf spring is fixedly connected at the front to the rigid-resilient pivot arm and is secured together therewith to the frame and which is rigidly slotted at the axis. 35 is connected to the shaft together with that pivot arm.

.8703122 i 2>

That leaf spring extends backwards beyond that arm and is connected to the frame such as a rocking piece or a sliding shoe within transverse guides near the rear end, so that it can move horizontally there relative to the frame, but such that transverse forces 5 also there can be well recorded. This leaf spring is slack enough in a vertical longitudinal plane to be able to spring behind the shaft in such a way that it does not hinder the vertical spring movement of the air spring.

With regard to the absorption of the transverse forces, such a construction does provide an improvement in construction, but it also has important drawbacks. It is quite complicated and expensive. Furthermore, the pivot arm with that rear-reaching arm must pass above the air spring, which has disadvantages due to the height restrictions. In particular and in connection therewith, that hinge arm must support the air spring behind the axle. This gives high reaction forces on the front hinge for this arm due to the fairly considerable horizontal distance between air spring and shaft. As a result, impact movements of the shaft are transmitted to the frame not only on the spring, but also annoyingly after that pivot axis.

In addition to such systems, combinations of leaf springs with air springs suspended at both ends are known.

The object of the invention is now to simplify such known devices and to avoid the stated drawbacks of known constructions.

To this end, an axle suspension device as referred to in the invention is characterized in that a leaf spring of longitudinally varying thickness is hinged about a transverse axis and permits horizontal longitudinal movement at the rear to the frame of the vehicle, such that this connection of the leaf spring with the frame at both ends in a horizontal direction transverse to the longitudinal direction is rigid, that the front part of the leaf spring is much thicker and thus more rigid than the rear part, which near the center of the length this leaf spring with the thick part is fixedly attached to the transverse axis below it, which carries the wheels or, when the axle is rotating, to a carrier therefor, which axle or carrier rigidly connects two such leaf springs each near one side of the vehicle so as to form a U-shape near the center roller stabilizer, wherein one or more air springs between the frame and the leaf spring above the mounting of the leaf spring and transverse shaft or carrier therefor leaf spring are fitted.

Thus, with a single leaf spring with a strongly changing thickness difference, the axle suspension can be provided, whereby the transverse forces are absorbed sufficiently rigid and where attractive possibilities are opened to place the parts relative to each other and the height .8703122 t 3 <ί keep the difference between the front hinged mounting of the leaf spring and the axle small, so that the axle undergoes little horizontal displacement relative to the frame during suspension, while the thin rear part of the leaf spring can be bent in such a way that it can easily be moved along which could get in the way if this spring were to run approximately horizontally backwards, for example along parts for driving driven axles. The rear connection of this spring to the frame can then, without any problem, be considerably higher than the front mounting and the shaft. In particular, there are so many fewer restrictions in the choice of the location of the air springs, and especially the possibility is opened to place the air springs, viewed in side view, practically directly above the axle, which offers great advantages in terms of power absorption and constructional design. .

All kinds of possible elaborations of the invention and associated advantages are possible. It is important here that there are at least certain thickness differences and thus differences in bending stiffness between the front and rear parts of the leaf spring, as will be described hereinafter. In the accompanying drawing the invention will be further elucidated on the basis of an exemplary embodiment. This drawing shows a side view of an axle suspension according to the invention, in fig. 1 in the fully extended driving position and in FIG. 2 in maximum depressed position when braking.

A spring hand 2 is mounted on the front of the vehicle, of which a longitudinal beam 1 is partly drawn, in which a leaf spring 3 is hingedly mounted via a bearing. This leaf spring gradually thickens backwards to form a flat surface at 4 in the thickest part at the top, on which rests a plateau 5, which bears the lower end of an air spring 6, which can be of conventional construction 30, with compressed air supply, which is variable and stops 7 and 8, which come to press each other mechanically at maximum compression and which are indicated by dashed lines.

The leaf spring 3 is thinned backwards gradually from plateau 5 at first, but for a short distance in the part 9, considerably thinner, to become a thin part 10, which thins backwards preferably gradually. The width can be equal over the entire length of spring 3 and considerably greater than the thickness of at least most of the spring.

At the bottom of the leaf spring 3 a transverse axis 11 40 is arranged in the thickest part and the platform 5, spring 3 and transverse axis are fixedly connected by slings 12. 87 03 122 4 r). The air spring 6 is preferably displaced a short distance in the longitudinal direction of the vehicle relative to the axle 11, in this case slightly in front of that axle, in order to maintain a small pretension on the mountings of the spring 3 on the carriage.

The leaf spring 3 is connected to the frame at 13 via a rocking piece 14.

A shock absorber 15 engages on platform 5. There is also an upright stop 16 on that plateau.

If desired, an additional roll stabilizer as a U-shaped stabilizer 10, 17, 18 by 17 can be hingedly connected to the platform and suspended from the frame by hinge rods 19, engaging 20 on the legs of the U. The part 17 forms the torsion bar part of said stabilizer running transversely of the vehicle.

Dotted lines 3 'show to the right in FIG. 1 shows how the thin part of spring 3 can be curved differently if this is desired in connection with the available space.

Bottom right in Fig. 1 it is also shown how the rear end of part 10 of spring 3 has been guided with a loop 10 'to the rocking piece 14 in order to obtain a greater effective spring length without rearward displacement of this spring hand. Bottom left in Fig. 1 is shown how part 10 of spring 3 can slide in rocking piece 14 by 13 '.

Fig. 2 shows the situation under heavy braking. The air spring 6 is fully compressed and the upright stop 16 abuts the frame to help limit the axle tilt occurring.

Steering reactions during springing in and out are prevented by placing the spring hand 2 in transverse direction as precisely as possible next to the pivot point of the steering rod for steered axles. If the construction makes this desirable and also allows it, for instance because a cross beam can be arranged on site between the longitudinal beams 1 of the frame, the air springs 6 can also be placed next to the longitudinal beams 1, whereby the plateaus 5 of course have an adapted shape. and can stand. This also often gives the attractive possibility to raise the air springs and to be able to bring the front spring hand 2 vertically even more at the same height as the axle and also gives other possibilities for variation in mutual arrangement and dimensions of construction parts in order to obtain the most favorable construction. to achieve.

The system lends itself well to standardization, as the spring arms 2 and the swing or slider attachments 13, 14 can be factory fitted to the frame as standard, with 40 still available as a choice of some type of leaf spring system or system with air. 67 03122 5 ζ suspension as will be chosen according to the invention.

It is easy to choose the vertical position of spring hand 2 as favorably slow relative to the shaft 11 as to make the shaft perform as little forward and backward movement as possible in the spring. The angular position of platform 5 and axis 11 can easily be optimally selected.

Preferably, the rear part of the leaf spring 3 after the strong thinning at 9 is on average thinner than 0.45 times the average thickness of the leaf spring for shaft mounting. In the example given, this ratio is about 0.36.

Most of the length of the rear portion of the leaf spring is preferably thinner than 0.35 times the thickest part of the leaf spring immediately before the shaft attachment. In the example given, this ratio is about 0.27.

These limits were found to be optimal for the ratio of bending stiffness for normal truck applications. The absolute thicknesses and the thickness variation of the springs 3 are selected in such a way that maximum comfort is achieved depending on the construction weight and loading.

For the bending stiffness of the front part of the spring, that stiffness is high in order to obtain the required rolling stability, but again not so high that unevenness in the road and the like entail too high loads and an uncomfortable behavior of the vehicle. The shape and thickness of the leaf spring 3 are geared to the most uniform tension variation.

The leaf spring can consist of known and suitable steel grades, but also of fiber-reinforced plastic.

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Claims (8)

Axle suspension device for a vehicle with air suspension, characterized in that a leaf spring of longitudinally varying thickness is pivoted about a transverse axis and permitting horizontal longitudinal movement at the rear to the frame of the vehicle, such that the connection of the leaf spring with the frame at both ends in a horizontal direction transverse to the longitudinal direction, the front part of the leaf spring is much thicker and thus more rigid than the rear part, which near the center of the length fixes this leaf spring with the thick part is attached to the transverse axis below it, which carries the wheels or, when the axle is rotating, to a carrier therefor, which axle or carrier rigidly connects two such leaf springs each near one side of the vehicle so as to form a U-shaped stabilizer near the center , wherein one or more air springs between frame and leaf spring are arranged above the leaf spring near said attachment of leaf spring and transverse axis or carrier therefor. ranks. Device as claimed in claim 1, wherein the air spring or air springs are arranged practically directly above the shaft. The device of claim 1 or 2, wherein the leaf spring gradually thickens from the front linkage to the frame toward the axle mount 20 and gradually thins behind that axle mount after a strong thinning over more than half the length of that portion. The device of claim 1, 2 or 3, wherein the rear portion of said leaf spring is thinner than 0.45 times the average thickness of the leaf spring at the shaft mounting. The device of claim 4, wherein the rear portion of the leaf spring is thinner over most of its length less than 0.35 times the thickest part of the leaf spring at the shaft mounting. 6. Device according to any one of the preceding claims, wherein the thin rear part of the leaf spring extends with an upward bend from the axle mounting to the rear pivot point. 7. Device as claimed in any of the foregoing claims, wherein near the transverse surface through the air spring or air springs a protruding stop is arranged on the frame, the leaf spring in the thick part or a supporting platform, which is normally some distance between the stop and the co-acting therewith. release the part and cause it to strike when braking. , 87 03 12.2. £ 8. Device as claimed in any of the foregoing claims, characterized in that a shock absorber engages thereon or on a carrying platform near the center of the length of the leaf spring. *****. 6703122