DE19813092A1 - Structural component for motor vehicles - Google Patents

Abstract

The structural element (5) is of sheet steel, and has a hollow foam-filled chamber. The filling is of aluminum foam (2), and a border layer between steel and foam has a strength between that of steel and foam. The chamber is fluid-tight and almost gas-proof. The chamber may be only partially filled with foam, and the filled sections are subject to higher loads. The sheet steel forming the chamber are identical independent of the vehicle loads, adaptation to load is via variable aluminum foam filling.

Description

The invention relates to structural elements of Motor vehicles according to the preamble of the claim 1 and their use.

Known structural elements of vehicles often enclose Cavities, as for example in DE 39 32 121 A1, DE 37 22 490 C2 or DE 195 02 307 A1 shown is. Particularly inexpensive, easy to work with and in The use of steel sheets has proven itself in practice to form the structural elements (DE 39 32 121 A1). But also plastics (DE 37 22 490 C2) or aluminum (DE 195 02 307 A1) are used. The foaming of the respective cavities formed with art Foam is a relatively common measure me for sound insulation, but not for structural reinforcement kung.

From DE 195 02 307 A1 it is also known an aluminum to fill the mini carrier with aluminum foam, the Carrier is relatively expensive and only expensive with Stahlka body elements can be combined. The foam filled vehicle, however, has a convenient weight, energy absorption capacity and it is also easily recyclable.

It is an object of the invention to produce an inexpensive bares structural element for motor vehicles made of sheet steel  to create that to variable stability requirements is to be adapted and therefore for use with differ Chen vehicle loads is suitable.

The structural element is used to solve this task ment by the features specified in claim 1 out. Further details emerge from the patent Proverbs 2 and 3 and the description. The property ten of this structural element enable the in the patent pronounced 4 uses.

Structural elements of steel vehicles can be used as a pipe be formed or from several welded sheets exist, of which at least one is trough-shaped is, so that these sheets also form a cavity. in the Manufacturing process are the cavities of the structural elements initially not completely closed, but point Openings on. For pipes, these are the pipe ends and at deep-drawn sheet metal, these are the openings from which the deep-drawing tool is pulled off. There can be more Openings, such as holes or punched holes be.

According to the invention through the openings mentioned of the structural element aluminum foam base material in set amount introduced into the cavity and this Material is then foamed by heating. The aluminum foam base material is pre-pressed semi-finished product, consisting of aluminum powder and a blowing agent. The semi-finished product can be in the form of granules lat, but also in a spatially related to the structural element adapted form. When foaming forms a boundary layer between the steel sheet and the aluminum nium foam, the strength of which is between that of the steel sheet and that of the aluminum foam. The strength ent speaks about that of the aluminum foam base material. The called boundary layer arises through diffusion, with what  an intensive connection between steel and aluminum foam is created. As a result, the strength (Be resilience) of the structural element significantly increased against over a non-foamed one or one with art structural element foamed in foam. The tin Thickness of the structural element can be chosen lower than with a non-foamed structural element or this can be dimensioned smaller without sacrificing of stability.

The foaming with aluminum foam does not have to be the whole relate to the th cavity of the structural element, but can be limited locally to particularly high traffic Areas of the structural element. It is also possible Lich, one and the same structural element for different To use vehicle types. Is the load on the structure turements different in these vehicle types, he follows an adaptation to this requirement by variables- section by section or complete - foaming.

A limitation of the area of the hollow to be foamed The shape of the aluminum foam base material allows spaces rial semi-finished or certain areas of the Cavities are "locked" when foaming, so that the aluminum foam does not expand into these areas can.

To achieve corrosion resistance of the finished Structural elements are liquid-tight and almost sealed gas-tight. It is to be avoided that the resulting boundary layers between steel and aluminum of foam containing saline solutions. Of the Closure can vary depending on the type of installation and the shape of the structure element by plugging, by welding, by Lackie tion or other procedures.

It is particularly advantageous that such structural elements  te use subject to various loads Vehicles can find what the components are essential are cheaper to produce than a variety ver different structural elements. The adaptation to the conc The load is caused by variable foaming.

Details of the invention are described below with reference to two Exemplary embodiments explained. From the associated figu show

Fig. 1a, 1b: a side member for motor vehicles in a perspective, partially ge sectioned representation with variable foaming with aluminum umschaum;

FIG. 2a to 2d: a trough-shaped structural element for motor vehicles in its originating form and at variable from foaming with aluminum foam.

The tubular support made of sheet steel illustrated in FIG. 1 is a side member 1 for motor vehicles. It has a cranked shape, as is known from various motor vehicles. The steel sheet thickness or cross-sectional area is, however, reduced compared to that in known motor vehicles, so that the side member 1 is per se less resilient than this meets the requirements. The adaptation to the occurring loads is carried out by foaming with aluminum foam 2 in the manner described above. The cavity of the longitudinal member 1 shown in Fig. 1a is completely foamed with aluminum foam 2 , so that an aluminum core connected to the steel forms over the entire length of the longitudinal member 1 and thus a structural element 3 is formed which withstands high loads.

In Fig. 1b, the cavity of the side member 1 is only partially filled with aluminum foam 2 be . In particular, area 4 of the elbow has been foamed. The structural element 5 thus formed can be used for motor vehicles with lower loads than the structural element 3 .

The manner in which the structural elements 3 , 5 are closed is not shown in FIGS. 1a, 1b. It is possible to weld the pipe ends closed or to close them with plugs.

In Fig. 2a, a tub-shaped motor vehicle component 6 is shown, which consists of sheet steel and was made by deep drawing. It has a large upper opening 7 from which the deep-drawing tool has been removed. Following deep drawing (and degreasing), component 6 is variably foamed, for which two of the various possibilities are shown in FIGS. 2b, 2c. For medium load applications, partial foaming takes place ( Fig. 2b). The aluminum foam B introduced here has the shape of a cross, the height of the foam 8 being limited to the height of a flange 9 of the component 6 . The semi-finished product of the foam base material can already be cross-shaped, and when foaming (heating), the free areas of the cavity shown in FIG. 2b are "locked" with a tool. This tool can also form the upper limit at the same time, so that the foam height corresponds to that of the flange 9 .

The component 6 can also, as shown in Fig. 2c, be completely filled with aluminum foam 8 so that it is suitable for high loads. For this purpose, granular foam base material can be introduced into the cavity, and the foaming takes place after the component 6 has been closed by a cover element 10 made of sheet steel.

A closed structural element 11 is shown in Fig. 2d. The cover member 10 is connected to the component 6 by spot welding in the region of the flange 9 . It can also be connected to the cruciform foam core (according to FIG. 2b), which is not connected by diffusion with the cover element 10 , but only with the component 6 , by gluing. If the foaming of the aluminum foam takes place only after the component 6 has been closed (variant according to FIG. 2 c), the above-mentioned boundary layer also forms between the aluminum foam 8 and the cover element 10 .

Structural elements 11 of this type are extremely stable. The sheet thickness of the component 6 and the cover member 11 can be reduced compared to conventional components, and the use of the structural elements 11 for various vehicles is possible with variable foaming with aluminum foam 8 .

Claims (4)

1. Structural element ( 3 , 5 , 11 ) of a motor vehicle, which is formed by at least one steel sheet which encloses a cavity, the cavity being at least partially filled with a foam ( 2 , 8 ), characterized in that the foam ( 2, 8) an aluminum foam (2, 8) and a boundary layer between the steel sheet and aluminum foam (2, 8), of which the strength between the lies of the foam (2, 8) and of the steel sheet. 2. Structural element ( 3 , 5 , 11 ) according to claim 1, characterized in that the foamed cavity is liquid-tight and at least almost gas-tight ver closed. 3. Structural element ( 3 , 5 , 11 ) according to claim 1 or 2, characterized in that the cavity is only partially filled with aluminum foam ( 2 , 8 ), the filled areas are subject to an increased load compared to unfilled areas un. 4. Use of structural elements ( 3 , 5 , 11 ) according to egg nem of claims 1 to 3 in motor vehicles with un different load profile, the steel sheets forming the cavity are identical regardless of the vehicle load and a load adjustment is carried out by variable aluminum foaming.