DE102016121923A1 - combination of materials - Google Patents

Abstract

Material combination for a composite, comprising a first material with electrical conductivity and a second material with release properties.

Description

Field of the invention

The invention relates to the deposition of layers for producing a composite with superficial electrical conductivity.

Background of the invention

In many cases, composites are produced using a mold, also called a mold, on the surface of which the materials for producing the composite are laid down in layers. The curing of the composite to a workpiece is often carried out under pressure. This pressure can be achieved by evacuating the sealed material structure. After curing the composite to the workpiece, the workpiece must be successfully separated from the seal and mold. The equipping of such composites with a particular electrical conductivity plays a role, for example, in vehicle construction, since vehicle outer sides should be such that occupants and transported goods are not impaired by occasionally occurring in nature high-voltage discharge phenomena.

Description of the invention

It has now surprisingly and unforeseeable for the skilled worker that a combination of materials for a composite, comprising a first material, having electrical conductivity and thermal conductivity and comprising a second material, having release properties, remedies the disadvantages of the prior art. The material combination of a conductive material and a material with release properties can be a material that combines both properties, then "first material" and "second material" would be identical.

On the one hand, this first material is such that it has a specific conductivity on the surface of a finished component which is sufficient to provide sufficient electrical conductivity on the surface of the component depending on the intended use. Applications can be power supply, ground return or lightning protection. To achieve sufficient lightning protection properties, for example, the energy from a lightning strike must be absorbed so that no punctiform load acts on the component, but the energy is distributed and converted into a surface load and line cross-section and electrical conductivity are set so that the required power density is reached can be. In the case of aircraft, for lightning protection areas 1A-1C, 2A, 2B and 3, a copper or bronze mesh or expanded metal having a basis weight of 73 to 850 g / m ^{2 is} usually used. It is advantageous if the first material is reworkable, so its surface properties can be improved by grinding or polishing, so as to obtain a component that is particularly smooth, without the first material protruding or looking out of the resulting surface. The first material may be aluminum, silver, gold, copper, chromium or nickel and mixtures or alloys containing these metals, such as bronze. Also, columbium, inconel, phosphor bronze, platinum, stainless steel, low carbon steel, tantalum, titanium, zinc, zirconium can be used. Further, the second material is such that it has release properties. The release properties are intended to enable the detachment of a component made using the second material from a mold, the mold may be made of fiber-reinforced plastic or of metal or wood. The second material must be applicable to a mold surface. This can be done by brushing, rolling, spraying, dipping when the second material is in liquid form (such as a particulate system or as a solution) in which the release property imparting agent is dissolved or dispersed in a carrier. The second material may also be in the form of a film or a film. The second material can also be electrostatically applied to the mold. The second material can also be applied in liquid form or deposited from the gas phase, such as by spraying, plasma desorption, flame spraying or by bombardment with molten material particles and by cold gas spraying. The second material may be elemental metal, polymer based, or a mixture of various such materials. The second material must lose its adhesive properties later or under the influence of heat, so that a separation of cured component from the mold is possible. The second material can be washable. The second material may be a film release agent or a release paint, for example based on polyvinyl alcohol and water.

It is preferred if the combination of materials can be formed in a layered manner. It can form a layer on the tool surface on which another layer can be applied. In this case, the basis weight of the first material may vary and be partially zero: it may be sufficient to provide the electrical conductivity only in certain areas, such as embedded metal elements such as bolts or riveted joints. On the other hand, the release properties, ie the second material, are to be provided over the entire surface of the tool facing the component.

It is further preferred, if the material combination is at least partially suitable, part to be of the association. At least the first material must become part of the composite made using the tool.

It is further preferred if the material combination allows protection of the composite from lightning strikes. On the one hand, the material combination serves to minimize damage when the flash strikes by local evaporation, on the other hand, the derivative of the current across the component surface.

It is further preferred if the combination of materials is layered.

It is further preferred if the first material is part of the composite. For this purpose, the first material is cured and / or curable. This can be done chemically, for example by curing and / or thermally induced, such as by solidification from the liquid phase or by thermally induced chemical reaction.

The invention also encompasses a composite comprising a material combination according to the invention, wherein the composite is produced using a mold and the material combination is arranged on the form side in the composite.

Such a shape is also referred to as a tool or mold. It may consist of Ni-36 (Invar trademark), CFK (e.g., Hextool trademark), a millable thermoplastic (e.g., Ebalta trademark ebablock), wood, plywood, foam, 3D printed material, and may be made by molding.

The composite is preferably a fiber composite. A fiber composite consists essentially of two main components, a bedding matrix and reinforcing fibers, which are a multiphase or mixed material. By mutual interactions of the two components of this material receives higher quality properties than each of the two individually involved components (Wikipedia). The composite also includes a preform which has not yet cured and which does not yet contain the entire amount of matrix material.

It is preferred in this case if the mold used for producing the composite consists of metal or fiber composite material or of three-dimensionally printed material.

In all of this, the material combination allows the release of the cured composite from the mold surface.

The invention also encompasses a workpiece and / or aircraft comprising a combination of materials or a composite according to the invention. Such workpieces according to the invention may be wings, rotor blades, winglets, sharklets, elevators or rudders, landing or spoilers, high-lift systems, engine covers or automotive body panels. Aircraft according to the invention may be aircraft, drones, rockets, helicopters.

Furthermore, the invention comprises a method for the production of composites, wherein materials are deposited in layers in a mold and the combination of materials according to the invention is deposited in the mold, so that the detachment of the cured composite allowed to give the composite an electrical conductivity and the combination of materials according to the invention at least Part becomes part of the network. It is preferred if the inventive method without the use of volatile solvents (boiling point to 100 ° C / up to 260 ° C) manages.

The above-described aspects and other aspects, features, and advantages of the invention may also be had from the examples of the embodiments, which are described below with reference to the attached drawings.

list of figures

• 1 represents a known layer structure. 2 shows the layer structure according to the invention. 3 shows the removal of the structure according to the invention after curing.

In the figures, like reference numerals are used for the same or at least similar elements, components or aspects. It is noted that in the following embodiments will be described in detail, which are merely illustrative and not restrictive.

Detailed description of embodiments

1 represents a known layer structure. In this case, the surface of the made of metal or CFK molding tool ( 1 ) permanently with a metallic mold surface coating ( 2 ), the subsequent detachment of the release layer ( 3 ) facilitated. Then a first release film ( 3 ) filed. At least one layer of electrically conductive material ( 4 ), such as lightning protection material in the form of a bronze grid. This can be provided with resin. It will be further layers ( 5 ) deposited from reinforcing fibers, these form the Fasergelege. These reinforcing fibers may consist of CFRP and also contain resin. The structure is completed by an overhead release film ( 6 ) to which the vacuum seal ( 7 ) is applied. The metallic tool surface coating ( 2 ) remains on the mold ( 1 ).

2 shows the layer structure according to the invention. The surface of the metal or CFK molded tool ( 1 ) with an easy-to-apply and renewable mold surface coating ( 8th ), which provides for the subsequent detachment of the detachment properties of the part of the material combination ( 9 ) facilitated. On a metallic mold surface coating ( 2 ) is waived. Then the material combination according to the invention ( 9 ) filed. This can be done in two steps: the second material is applied to the mold, then the first material with electrical conductivity is deposited. On the material combination according to the invention ( 9 ), more layers ( 5 ) deposited from reinforcing fibers, these form the Fasergelege. These reinforcing fibers may be made of CFRP and contain resin. The structure is completed by an overhead release film ( 6 ) to which the vacuum seal ( 7 ) is applied.

3 shows the removal of the structure according to the invention after curing. Vacuum sealing ( 7 ) and overhead release film ( 6 ) work together from hardened workpiece ( 10 ) and discarded. The workpiece ( 10 ) can also be taken. At least the electrically conductive first material of the material combination ( 9 ) is now part of the workpiece and firmly connected to it. The second material with release properties can be easily removed, such as by brushing or washing. The surface of the hardened workpiece ( 10 ) can be reworked by grinding or polishing. After inspection, the component can be coated. The mold ( 1 ) can be applied by renewed or further application of the easy-to-apply and renewable tool surface coating ( 8th ) for the next production cycle.

While the invention has been illustrated and described in detail in the drawings and the foregoing description, it is intended that such illustrations and descriptions be merely illustrative or exemplary and not restrictive, such that the invention is not limited by the disclosed embodiments. In the claims, the word "comprising" does not exclude other elements and the indefinite article "a" does not exclude a plurality.

The mere fact that certain features are mentioned in various dependent claims does not limit the scope of the invention. Combinations of these features can be used advantageously. The reference signs in the claims are not intended to limit the scope of the claims.

LIST OF REFERENCE NUMBERS

1

mold

2

metallic tool surface pretreatment

3

underlying release film

4

Lightning protection layer

5

fiber fabrics

6

overhead release film

7

vacuum sealing

8th

Renewable tool surface pretreatment

9

combination of materials

10

hardened component

11

Separating layer and vacuum sealing

Claims (14)

Material combination for a composite, comprising a first material with electrical conductivity and a second material with release properties. Material combination according to Claim 1 characterized in that it can be formed in layers. Material combination according to one of the preceding claims, characterized in that it is suitable to be part of the composite. Material combination according to one of the preceding claims, characterized in that it allows protection of the composite against lightning strikes. Material combination according to one of the preceding claims, characterized in that it is formed layer-shaped. Material combination according to one of the preceding claims, characterized in that it is at least partially part of the composite, cured and / or curable. Composite comprising a combination of materials according to one of the preceding claims, characterized in that the composite is produced using a mold and the material combination is arranged in the form of composite. Composite according to one of the preceding claims comprising a combination of materials, characterized in that the composite is a fiber composite. Composite according to one of the preceding claims, characterized in that the mold consists of metal or fiber composite material or of three-dimensionally printed material. Composite according to one of the preceding claims, characterized in that the material is removed with release properties after curing of the composite. Workpiece comprising a material combination or a composite according to one of the preceding claims. Aircraft comprising a combination of materials or a composite according to one of the preceding claims. Process for the preparation of composites wherein materials are deposited in layers in a mold and a combination of materials according to one of the preceding claims is placed in the mold, that it allows the detachment of the cured composite and gives the composite an electrical conductivity and at least partially becomes part of the composite , Method according to Claim 13 that works without the use of volatile solvents.

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