DE102012221406A1 - Joint, in particular for a motor vehicle - Google Patents

Abstract

The present invention relates to a joint, in particular for a motor vehicle, for the articulated connection of at least two components. To provide a joint that has only a low weight, is easy to install and can be better adapted to the respective existing requirements, the invention proposes that the joint consists of an elastic fiber composite material.

Description

The present invention relates to a joint, in particular for a motor vehicle, for the articulated connection of at least two components.

In motor vehicles, the articulated connection of various components, such. B. the connection of links to the wheel, pivot bearings, axle o. The like., Most realized by means of rubber bearings. Rubber bearings, however, hinder optimal utilization of the material properties of the components to be joined in the context of lightweight construction with fiber composite materials. Rubber bearings per se and the additional material required for mounting in the form of tabs and bearing eyes on the components to be connected bring weight with it. Furthermore, rubber bearings are expensive to install. Their incorporation into fiber-reinforced plastic components, if necessary, entails risks in terms of increased settlement behavior and contact corrosion between a possibly metallic outer ring of the rubber bearing and carbon fiber reinforced plastics. Rubber mounts also allow more freedom of movement in many applications than would be functionally required. So a 360 ° rotation is often granted, although the articulated connection needs to perform only a fraction of a rotary motion in the application. Finally, this design often requires more space than necessary, which is then missing for a rigidity or strength optimized design.

It is therefore an object of the present invention to provide a joint that has only a low weight, is easy to install and can be better adapted to the respective existing requirements.

This object is achieved in a joint, in particular for a motor vehicle, for the articulated connection of at least two components, according to the invention in that the joint consists of a resilient fiber composite material.

As a result of the embodiment according to the invention accounts through the integration of functions interfaces in the form of rubber bearings and fasteners, such as screws and outer sleeves. The surrounding area of the joint can thereby be made slimmer. This leads to a weight reduction and reduces the assembly effort. In addition, more space is available for the design of the adjacent components. The inventive design of the joint allows the formation of "attacks" in the elastic characteristic, which z. B. in the case of abuse (crossing an obstacle) can reduce the load peaks on other components.

The dependent claims contain advantageous developments and refinements of the invention.

According to a preferred embodiment, the fiber composite material consists of endless fiber-reinforced plastics. This makes it possible to create the joints with a widely adjustable and directional elastic identifier.

According to an advantageous development, the fiber composite material consists of a combination of different plastics, eg. As a composite of glass and carbon fibers.

Advantageously, the fiber composite material passes continuously into the components to be joined. Due to the continuous transition (graduating), the joint according to the invention can be used directly in a composite structure of z. B. axle and handlebars are integrated.

According to a preferred embodiment, the fiber composite material by braiding against overloading, z. B. protected in an accident so that a residual performance is maintained.

According to an advantageous development, the joint is double-shelled with a first shell and a second shell.

Alternatively, the joint may also be formed with three shells with a first shell, a second shell and a third shell.

Preferably, the shells form a gap in the joint area.

The gap may be either hollow or filled with a visco-elastic material to increase damping.

According to an advantageous embodiment, a stop member may be arranged to limit the range of movement on both sides of the joint.

Further details, features and advantages of the invention will become apparent from the following description with reference to the drawings. Show it:

1 a longitudinal section through an embodiment of the joint according to the invention,

2 a longitudinal section through a further embodiment of the joint according to the invention,

3 a view of another embodiment of the joint according to the invention,

4 a schematic representation of another embodiment of the joint according to the invention,

5 a longitudinal section through a further embodiment of the joint according to the invention, and

6 a schematic representation of an axle system using the joint according to the invention.

The joint according to the invention 1 consists of a resilient elastic fiber composite material, eg. As glass fibers, which at both ends in a rigid fiber composite material 2 , z. B. made of carbon fibers, passes. To the stiff fiber composite material 2 is at one end (left in the figure) a first component 3 , z. B. connected to an axle, while at the other end (right in the figure), a second component 4 , z. B. a handlebar is connected. The fiber composite material goes continuously into the components to be joined 3 . 4 above.

One at least in the area of the joint 1 and in the transition region between the elastic and the rigid fiber composite material 2 intended over-weaving 5 can in case of overload, z. For example, in case of misuse or accident, make sure that there is residual wear.

The joint 1 can be provided with integrated damping in addition to the elastic functions. This is achieved by introducing viscous materials in the laminate structure or in the joint 1 , Corresponding embodiments are in the 2 and 3 shown.

In 2 is another embodiment of the joint according to the invention 1 shown. The local joint 1 is a bivalve joint with a first shell 1a and a second shell 1b running, being between the two shells 1a and 1b a gap 6 is trained. The gap 6 may be empty or filled with a visco-elastic material, which would increase the damping.

3 shows an embodiment in which the joint according to the invention 1 dreischalig with the shells 1a . 1b and 1c is trained. Due to the geometric design of the shells 1a . 1b and 1c the course of the restoring forces and moments can be adjusted over the joint travel in all spatial directions within wide ranges. The gap 6 between the cups 1a . 1b and 1c can be hollow or filled with a damping material.

In 4 an embodiment is shown in which the joint according to the invention 1 in the depth direction an opening 7 having.

The joint according to the invention 1 Compared to conventional multi-part abutments has a very limited range of motion. This is given by the elastic stress limits of the materials used. In order to avoid joint damage by exceeding the range of motion or to influence the joint characteristic, additional stops may be provided. A corresponding embodiment is in 5 shown. There are both sides of the joint 1 stop components 8th provided, which determines the freedom of movement of the joint 1 limit.

The joint according to the invention 1 can be used as a load-bearing structure in the chassis area, as a structure with kinematic functions in connection with wheel guidance, suspension and / or steering and in particular as a structure between body-mounted structures, such as axle beams, and wheel-guiding components, such as wheel carriers. The components may be assembled individual components (screwed, glued or the like) or integrative components such as an axle system, eg. An axle carrier with integrated handlebars made of plastic.

An exemplary illustration of such a purpose is shown in FIG 6 shown in conjunction with an axis system. The axle system consists of two triangular links 9 , which with two axle carrier shells 10 via inventively designed resilient joints 1 are connected and the wheel carrier with wheel bearings 11 lead in the height direction articulated.

The joint according to the invention 1 can also be used in band or bar-like structures, preferably with flat cross sections within the hinge axis and simply curved course. Ideally, the joint tapers 1 in the area of the joint kinematics point. In the connection area is the joint 1 geometrically by thickness, choice of material, stiffening ribs u. Ä. Adaptable to the environment. Preferably, the joint area is performed curved, wherein the joint function is achieved by bending in the fiber composite material. To avoid damage or changes in the joint function by creeping or setting processes, it makes sense to guide the joint area around the joint axis in a suitable radius (S-stroke). As a result, strains in this area can be kept low.

The joint 1 has a rest position in the fully relaxed state. Deformations from this rest position cause elastic restoring forces and moments. The height of these joint reactions, as well as their course over the Gelenkverstellbereich, can be influenced by the geometric design (in particular width, thickness and spatial curvature) in the different hinge directions. As a result, a desired gimbal hinge behavior, as today's rubber bearings have to be readjusted.

The fiber composite material can be made of continuous fiber reinforced plastics and a combination of different plastics, eg. As glass and carbon fibers exist.

The connection area is ideally formed as a rigid structure. This may, for example, be a sandwich structure consisting of core and cover layers, a monolithic fiber composite structure or a fin-reinforced SMC or injection-molded component.

The hinge region is ideally a monolithic laminate of continuous filament. The function is mainly determined by the outer layers in thick joints. The inner regions are particularly in the thick-walled case represented by a material and a fiber assembly, which has a low creep. For this purpose, basically endless fiber-reinforced plastics, but also special core materials with short fibers in a directional or undirected arrangement come into question. To implement a damping property, a viscoelastic material can likewise be incorporated into the layer structure in the joint area. This can, for example, also replace the core area.

The transition region between resilient and rigid joint part is designed so that no jumps in stiffness occur because they can cause premature failure. This is achieved by a continuous transition between the regions, such as can be made, for example, by constraining the two adjacent laminates.

Possible core materials are plastics, likewise thermoplastics / thermosets, SMC, in particular fiber composite plastics as well as lightweight, shear-resistant foams, elastomers or other visco-elastic plastics.

Possible cover materials are continuous fiber reinforced plastics from z. As coal, glass, aramid, basalt fibers, which offer fracture-resistant and cost-effective glass fibers in the joint area. Furthermore, fiber webs or mats of random fiber, also recycled continuous fibers or combinations of the above materials can be used.

The compliant function is achieved by fracture-resistant continuous fibers. These are ideally arranged perpendicular to the hinge axis. This can be achieved by laminating from unidirectional patches.

In order to obtain a good-natured failure behavior in the event of overload, additional layers with undulating fibers (eg, fabrics, braids) can be used. These can be incorporated into the layer structure or, especially in the case of braids, applied to the joint as an outer shell by a braiding process.

Especially with thick-walled structures, the delamination tendency can be reduced by local reinforcements in the thickness range. This can be made by sewing, tufing or other textile processes.

The joint according to the invention 1 thus enables the articulated connection of two components 3 and 4 solely by the use of different stiff fiber composite materials.

The foregoing description of the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents.

LIST OF REFERENCE NUMBERS

1

joint

1a

first shell

1b

second shell

1c

third shell

2

rigid fiber composite material

3

first component

4

second component

5

Überflechtung

6

gap

7

perforation

8th

stop component

9

wishbone

10

Achsträgerschale

11

Wheel carrier with wheel bearing

Claims (10)

Joint, in particular for a motor vehicle, for the articulated connection of at least two components, characterized in that the joint ( 1 ) consists of an elastic fiber composite material. Joint according to claim 1, characterized in that the fiber composite material consists of continuous fiber reinforced plastics. Joint according to claim 1 or 2, characterized in that the fiber composite material consists of a combination of different plastics. Joint according to one of the preceding claims, characterized in that the fiber composite material continuously into the components to be connected ( 3 . 4 ) passes over. Joint according to one of the preceding claims, characterized in that the fiber composite material by braiding ( 5 ) is protected against overloading so that a residual performance is maintained. Joint according to one of the preceding claims, characterized in that the joint ( 1 ) clamshell with a first shell ( 1a ) and a second shell ( 1b ) is trained. Joint according to one of the preceding claims 1 to 5, characterized in that the joint ( 1 ) three-shelled with a first shell ( 1a ), a second shell ( 1b ) and a third shell ( 1c ) is trained. Joint according to claim 6 or 7, characterized in that the shells ( 1a . 1b . 1c ) in the joint area a gap ( 6 ) train. Joint according to claim 8, characterized in that the gap ( 6 ) is empty or filled with a visco-elastic material. Joint according to one of the preceding claims, characterized in that on both sides of the joint ( 1 ) a stop component ( 8th ) is arranged.

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