EP1034579A1 - Method for producing a radar reflection diminishing structural component - Google Patents

Abstract

The invention relates to a method for producing a radar reflection diminishing structural component comprised of a core element. The structural component is preferably comprised of a honeycomb core or a substrate especially for a two-dimensional sandwich structural component having a lower layer and an upper layer between which the core element is arranged. In order to produce a light structural component having a wide-band, efficient and optimized absorption characteristic of radar beams, the core element is immersed in and/or removed from a metallic immersion bath or an immersion device in a path-controlled and time-controlled manner by means of a computer supported simulation. As a result, the parameters for a subsequent galvanic treatment of the core element are determined with simulation values of the entire core element, said values being determined with the assistance of the computer, in order to deposit the layers with given or adjusted layer thickness gradients. After immersing the core element in the immersion bath, the inner and outer surfaces of the core element are coated with a thin metal layer by means of an electrochemical method.

Description

 METHOD FOR PRODUCING A RADAR REFLECTION-REDUCING COMPONENT

The invention relates to a method for producing a radar reflection-reducing component consisting of a core element, preferably a honeycomb core or a substrate, in particular for a flat sandwich component with a lower cover layer and an upper cover layer, between which the core element is arranged.

Radar reflection reducing components are used for example in aircraft, preferably as vertical tail or wing edge components. Use on buildings in the

Airport areas can be provided as well as in the area of shipping on superstructures of ships.

For the purpose of reducing the signature on aircraft, it has been investigated as part of development programs that the honeycomb for sandwich structures - this also applies to three-dimensional substrates used in foamed sandwich structures - with an electrically conductive plastic coating. Layering. For example, lacquers enriched with black soot were used. Disadvantageously, the electrically conductive plastic layers, which also lead to weight increases of approximately 100% by weight, can only be calculated to a limited extent by means of computer-aided simulation. Furthermore, the coating processes examined are costly, time-consuming and difficult to reproduce.

The invention is therefore based on the object of providing a method for producing a light component of the type mentioned at the outset with a broadband, powerful and optimized absorption characteristic of radar beams.

This object is achieved in that immersion and / or removal of the core element in or out of a metallic immersion bath of a diving device is controlled by time and time by means of computer-aided simulation, the parameters for being determined on the basis of simulation values of the entire core element determined with the aid of the computer a subsequent galvanic treatment of the core element for applying the layers with predetermined or set layer thickness gradients are determined, and that after immersing the core element in the immersion bath, the inner and outer surfaces of the core element are coated with a thin metal layer by an electrochemical process.

The method according to the invention advantageously ensures automatic and easily reproducible application of thin metal layers to a core element, its signature-reducing effect being designed in a defined manner by computer-aided simulation, ie using simulation values determined with the aid of a computer, in order to achieve the maximum achievable absorption characteristic becomes. The materials used, as well as the various geometrical designs of the substrate structures, offer a high degree of flexibility in the design of the absorption characteristics. The direct application of metallic thin layers to a core element advantageously makes it possible to use electrical and magnetic properties in a targeted manner. Further advantages of the applied thin layers are that they only lead to a minimal increase in weight, that they have no influence on the structural mechanical properties, are characterized by good chemical resistance and can be applied to all geometries.

Embodiments of the method according to the invention are described in subclaims 2 to 7.

In the drawing, the individual components of two flat components in sandwich construction are shown in the unfinished state, the core elements of which have been metallized according to the method of the invention, whereby

Fig. 1 is a sandwich component with a metallized honeycomb core and

2 show a sandwich component with a metallized foamed substrate.

The sandwich components shown in FIGS. 1 and 2 each have a lower cover layer 1, a core element 2 or 3 and an upper cover layer 4. The core element 2 from FIG. 1 is a honeycomb core, the metallized inner and outer surfaces of which are designated by 2a. In contrast, the core element 3 according to FIG. 2 is a foamed-in three-dimensional substrate with a metallized outer surface 3a. Between the core elements 2 and 3 and the lower and upper cover layers 1 and 4 are respectively Adhesion promoter layers 5 are arranged, by means of which good adhesion between the cover layers 1 and 4 and the core elements 2 and 3 is ensured after the individual components have been joined together.

In order to produce sandwich components with an optimal reduction in their radar signature with only a slight increase in weight and without influencing the structural bond, the inner and outer surfaces 2a and 3a of the core elements 2 and 3 are immersed in an immersion device after immersion in a metallic immersion bath electrochemical process completely covered with a thin metal layer, preferably with a thin nickel layer. All metals and metal compounds that can be deposited on optionally pretreated structural surfaces of the core elements 2 or 3 can be used as metallic coatings. The immersion and / or removal of the core elements 2 and 3 into and out of the immersion bath is controlled by time and by means of computer-aided simulation.

An electroless (electroless) metal deposition for applying the thin metal layers is preferably provided as the electrochemical method, by means of which it is achieved that the deposited metal layers have the same thickness everywhere. In combination with the special diving device that enables the intended path and time control, the absorption properties for radar beams are optimized and a design is made possible by means of computer-aided simulation. Reproducible immersion times are achieved with the path / time-controlled immersion device. The metal layers can advantageously be applied to the surfaces 2a or 3a of the core elements 2 or 3 with a linear, with a step-shaped or with an exponential layer thickness gradient. Reference list

1 lower cover layer

2 core element / honeycomb core

2a surfaces of the honeycomb core 2

3 core element / foamed substrate 3a surfaces of the substrate 3

4 top cover layer

5 adhesion promoters

Claims

Patent claims

1. A method for producing a radar reflection-reducing component consisting of a core element, preferably a honeycomb core or a substrate, in particular for a flat sandwich component with a lower cover layer and an upper cover layer, between which the core element is arranged, characterized in that an immersion and / or Removing the core element (2, 3) into and out of a metallic immersion bath of a diving device is path-controlled and time-controlled by means of computer-aided simulation, the parameters for a subsequent galvanic being determined on the basis of simulation values of the entire core element (2, 3) determined using the computer Treatment of the core element (2, 43) for applying the layers with predetermined or set layer thickness gradients are determined, and that after the core element (2, 3) has been immersed in the immersion bath, the inner and outer surfaces (2a, 3a) of the core element ( 2, 3) by an electrochemical process with a thin layer of metal.

2. The method according to claim 1, characterized by an external electroless (autocatalytic) metal deposition for applying the thin metal layers.

3. The method according to claim 1 or 2, characterized in that the metal layers are applied with a linear layer thickness gradient on the surfaces (2a, 3a) of the core element (2, 3).

4. The method according to claim 1 or 2, characterized in that the metal layers are applied with a step-shaped layer thickness gradient on the surfaces (2a, 3a) of the core element (2, 3).

5. The method according to claim 1 or 2, characterized in that the metal layers are applied with an exponential layer thickness gradient on the surfaces (2a, 3a) of the core element (2, 3).

6. The method according to any one of claims 1 to 5, characterized in that nickel is used as on the surfaces (2a, 3a) of the core element (2, 3) to be applied.

7. The method according to any one of claims 1 to 6, characterized in that between the metallized core element (2, 3) and the lower and upper cover layer (1 and 4) adhesion promoter (5) for assembling the components to a sandwich component are arranged.