DE9409126U1 - Molded component - Google Patents

Description

Stenger, Watzke & Ring·*.: ··%.**

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PATENT ATTORNEYS

DIPL-ING. WOLFRAM WATZKE

ir vu «„_&Lgr;&ogr;.,&ggr;&ggr; DIPL-INC. HEINZ J. RING

Our reference: 94 0315 DIPL-ING. ULRICH CHRISTOPHERSEN

PATENT ATTORNEYS

1. HW Meckenstock KG, Oststrasse 2, european patent attorneys
40822 Mettmann-Mettmann,

_Dahjm 3 June 1994

2. Helmut W. Diedrichs, Messeler-Park-Str. 119, 64291 Darmstadt-Wixhausen

Mold component

The invention relates to a molded component, in particular for covering functional elements, for example vehicle functional parts in

motor vehicles.

Such covers, for example of chassis elements, are subject to high dynamic loads on the one hand, and thermal loads can also affect the parts on the other. Such covers have so far been made from aluminum or aluminum alloys, which are preferably processed using the die-casting process. Such previously known covers have a number of disadvantages, since they have to be made relatively thick to achieve certain strength properties and are therefore heavy. The production of the molded components using the aluminum die-casting process is energy- and material-intensive. In addition, the surfaces of the aluminum die-cast molded components cannot be designed to an adequate optical standard. The vibration behavior is perceived as particularly negative, so that the material thickness is increased, which leads to relatively thick and heavy molded components and has an adverse effect on the connection areas and can lead to rattling and/or droning. If cracks occur in the area of fastening holes or other connection points, these can only be detected using complex procedures. Finally, the disposal of the molded components is a problem, especially since comparatively large quantities are generated.

Telephone (02U) 572IJI-TeIex35884i9paie3-Terefax(0i&T58Ji?5-Postgirokonto Köln (BLZ 37010050) 227610-503

Based on this, the invention is based on the object of providing a molded component which does not have the disadvantages mentioned and is in particular easier to manufacture and can be designed to be lighter and thinner while achieving corresponding strength properties.

To technically solve this problem, a molded component is provided, in particular for covering functional elements, consisting of at least one layer, preferably made of metallic material, which is three-dimensionally chip-free formed at least in partial areas and provided with connection areas for fastening, which has a three-dimensional structure at least in one partial area which is perforated in at least two directions lying at an angle to one another in the layer plane.

Due to the three-dimensional structure formed in the layer, the layer used to manufacture the molded component can be made thinner and thus a lighter molded component can be obtained. Due to the structure being perforated in at least two directions at an angle to each other and in the layer plane, the material can easily be deformed three-dimensionally without cutting, for example in presses, in the deep-drawing process or the like. This makes the manufacturing process more efficient than the

Aluminum die-casting process is considerably simplified. The significantly lower weight improves the vibration properties and in particular counteracts the tendency to produce droning. A structure is formed that corresponds to intersecting waves.

A metal foil is preferably used as the layer material. Such metal foils with a structure as specified have a very high strength with a minimal weight. Depending on the requirements, a sheet of metal can also be used as the layer to be formed.

It is particularly advantageous that the three-dimensional structure is formed by studs. These studs form dome-like arches that guarantee high compressive strength, whereby the molded component can nevertheless be formed from a thin and extremely light layer. In an advantageous

The knob structure is preferably aligned at an angle of 45° to the main deformation direction. This improves deformability while at least maintaining the same stability.

It is advantageously proposed that the molded component has unstructured connection areas. These can be achieved either by not applying a three-dimensional structure or by pressing the layer to be deformed again in the connection areas. It is advantageously proposed that at least one of the connection areas is designed as a flange. This is advantageously angled and has holes. The molded part can thus be attached to connection flanges in the area of the functional elements to be covered using screws, bolts and the like. The molded component advantageously has stiffening beads. The stiffening beads have a stabilizing effect, in particular they strengthen the component against twisting. Stiffening beads are advantageously formed on the edge. There they run essentially parallel to the edge at least in places and bring about the desired stiffness of the component. It is advantageously proposed that stiffening beads also be designed as tunnel-like connections to the angled flange. These tunnel-like connections stabilize the flange in its position relative to the component surface and make the component more rigid overall. The tunnel-like connections are advantageously arranged in the area surrounding holes formed in the flange in such a way that the flow of force from the screw connection point into the component surface is promoted. It is particularly advantageous that the edge is bent at least once by 180°. This bending creates a folded edge, which also contributes to the torsional rigidity. In addition, the folded edge has a positive effect on the vibration behavior of the component, which is improved in its resonance and vibration behavior. The fold also counteracts notch effects. It is advantageously proposed to form a fold on the flange. It is advantageously proposed that the fold is wide enough to cover the holes. On the one hand, this measure creates a flat connection surface, and on the other hand, notch effects are avoided, particularly in the area of the flange holes.

The molded component according to the invention is characterized by a number of advantages. It is easier to manufacture, with the three-dimensional structure contributing significantly to the strength without negatively affecting non-cutting deformability. The molded component can be made considerably thinner and lighter than conventional molded components. In addition, the surface can be designed, for example by choosing a suitable three-dimensional structure. The vibration behavior of the new molded component is considerably improved compared to conventional molded components. The new molded component does not tend to rumble. Cracks are easy to detect compared to conventional aluminum components. Finally, disposal is considerably improved because the molded component according to the invention consists of a metal foil or thin metal sheets, for example of aluminum, steel or aluminum alloys, so that no large quantities have to be disposed of.

Further advantages and features of the invention emerge from the following description based on the figures. They show:

Figure 1 is a schematic perspective view of a

Example of a molded component;

Figure 2 is a sectional view along the line ll-ll according to Figure 1 and
Figure 3 is a sectional view along the line III-III of Figure 1.

The molded component 1 shown in the figures consists of a metal foil, for example made of aluminum, in which studs 3 are formed to form a three-dimensional structure. These studs 3 do not prescribe a bending edge position direction, so that even difficult deformations of the component are easily possible. The metal foil 2 is specially designed at the edges. A flange 4 is formed at one end, stiffening beads 5 are formed along the other edges, or a simple flat edge 6 is formed. Holes 8 are formed in the flange. In addition, the flange 4 is opposite the

Cover surface provided with tunnel-like connections 9, i.e. stabilizing stiffening beads in the flange area.

As can be seen in Figure 3, the metal foil 2 is bent once by 180° in the area of the flange 4, so that the fold 7 is formed.

The knobs 3 increase the strength of the foils or sheets, whose torsional rigidity is increased by the stiffening beads 5 and the tunnel-like connections 9. The metal foil 2 can be easily deformed without cutting. The flange 4 is reinforced by the fold, which improves the resonance and vibration behavior and reduces the formation of cracks in the area of the holes 8.

In practice, the formation of folds in the area of the flange edges 10 has proven to be important. In addition, the arrangement of tunnel-like connections 9 in the manner shown in Figure 2 is advantageous, since this promotes the flow of force from the screw connection point, i.e. the middle hole 8, to the component surface.

Reference list

1 molded component

2 metal foil

3 studs

4 Flange

5 Reinforcing bead

6 Edge

7 Fold

8 hole

9 tunnel-like connection

10 Flange edge

Claims (15)

Expectations 1. Molded component (1), in particular for covering functional elements, consisting of at least one layer, preferably made of metallic material, which is three-dimensionally deformed without cutting at least in partial areas and provided with connection areas for fastening, which has a three-dimensional structure at least in one partial area, which is perforated in directions lying at an angle to one another at least in the layer plane. 2. Molded component according to claim 1, characterized in that the layer is a metal foil (2). 3. Molded component according to claim 1, characterized in that the layer is a sheet metal. 4. Moulded component according to one of the preceding claims, characterized in that the three-dimensional structure is formed by knobs (3). 5. Molded component according to claim 4, characterized in that the knob structure is aligned at an angle of preferably 45° to the main deformation direction. 6. Moulded component according to one of the preceding claims, characterized in that it has flat connection areas. 7. Molded component according to claim 6, characterized in that at least one of the connection regions is a flange (4). 8. Molded component according to claim 7, characterized in that the flange {4) is angled to the molded component (1). 9. Moulded component according to one of claims 7 or 8, characterized in that holes (8) are formed in the flange (4). 10. Moulded component according to one of the preceding claims, characterized in that it has stiffening beads (5). 11. Molded component according to claim 10, characterized in that the stiffening beads (5) are formed on an edge of the molded component (1). 12. Moulded component according to one of claims 7 to 11, characterized in that the moulded component (1) has tunnel-like connections (9) running transversely to the angled flange (4) in the flange region. 13. Molded component according to one of the preceding claims, characterized in that the metal foil (2) is bent at least once by 180° on at least one of the edges to form a fold (7). 14. Molded component according to claim 13, characterized in that the fold (7) is formed on the flange (4). 15. Moulded component according to one of claims 13 or 14, characterized in that the fold is designed so wide that holes (8) are covered by the fold (7).