EP1981680A1 - Control element - Google Patents

Abstract

The invention relates to a control element (1), in particular for a motor vehicle, consisting of a material (2) through which light can be passed and which is provided with at least one opaque coating (3) provided with symbols (5), and having a transparent enamel layer (4) on the coating (3), wherein nanoparticles (11) are introduced into the enamel layer (4), and the coating (3) and the enamel layer (4) are removed by means of a laser.

Description

 DESCRIPTION

operating element

The invention relates to an operating element, in particular an operating element for a motor vehicle, made of a transilluminable material which is provided with at least one opaque coating and with a transparent lacquer layer on the coating.

A preferred field of application of the invention is in the field of motor vehicles and there with controls, which are backlit for the most part. It is also conceivable to use the invention on controls of consumer electronics, in the range of kitchen appliances or washing machines, the so-called white goods, just where controls are used, which are backlit and have a metallic appearance of their appearance should. For backlighting preferably translucent plastics are used here, which offer the possibility to illuminate the control element or the button from a rear side by means of a light source and to backlight a introduced into the coating of the control element or the button symbolism. A preferred material used for this purpose is polycarbonate (PC) or polymethylmethacrylate (PMMA), these plastics offer favorable properties in terms of processing and through- or backlighting.

A trend that prevails in controls in motor vehicles, is to provide the controls or buttons with a metallic-looking look. Here, the components are molded from a plastic and provided by various methods with a metallic coating. Metallic coatings which have a high-gloss chrome finish or the appearance of aluminum (AL) or ruthenium (RU) or a comparable glossy surface are, according to the current state of the art, usually applied by a galvanization or PVD (Physical Vapor Deposition) method.

During plating, metallization usually takes place after the process steps: palladium nucleation, reduction, chemical metallization, for example by means of nickel or Copper, and galvanic reinforcement, for example with chrome. In the PVD process, the metallization takes place by means of a physical deposition from the gas phase, for example by means of vapor deposition.

A use of a PVD method in relation to plastics for producing metallic coatings on workpieces is described in DE 103 37 456 A1. Thus, this method offers the possibility of direct metallization of the surface of the material or of a component, wherein the metallic coating consists of one or more superimposed identical or different metal layers. By means of the technique described in the process, also materials or components with lower surface energies can be coated. Here, the surface energies of the materials or components are activated by means of a plasma, whereby a very good adhesion to polymers is produced. In the plasma activation, a gas or a gas mixture is subjected to an electrical gas discharge in a vacuum. In doing so, electrons, ions, radicals and neutral particles are generated which impinge on the surface of the material of the component, thereby contaminations can be removed and the surface roughened and chemically modified. This is followed by direct metallization, in which, in a described exemplary embodiment, a chromium and aluminum layer is produced which has a total layer thickness of about 330 nm.

In the generic, unpublished DE 10 2005 006 459 a metallized plastic component and a method for producing a metallized plastic component having a metallic coating and a coating applied to the metallic coating lacquer layer, which may be present in undyed form, is described. Described is a control element, which is provided with a metallic coating, which is applied for example by means of a PVD process. After the application of the metallic coating, a symbolism is introduced into the operating element by means of a laser. A metal layer is then deposited on this first metallic coating, for example by means of a galvanic process, so that a metallic coating consisting of two layers is produced, in which the area exposed in advance is not provided with the metallic coating. If the operating element is backlit, the light only emerges in the region of the exposed area of the operating element. The opaque area, on which the metallic coating is present, appears here as a metal part, in which a symbolism is incorporated. Described is also the application of an undyed lacquer layer, which is also referred to as a clearcoat. The disadvantage here is that the symbolism must represent a coherent area, since the liable mediating first coating for electroplating must be placed under tension. There are thus no symbols representable, which have metallic areas in their interior.

It is therefore an object of the invention to provide an operating element that is provided with at least one opaque coating and moreover has a transparent lacquer layer, wherein in the lacquer layer and the coating any symbolism can be introduced. In addition, the symbolism in one step should be recoverable.

The object of the invention is achieved in that the transparent lacquer layer is provided with nanoparticles and that the coating and the lacquer layer is partially removed by means of a laser. The inventive composition of the transparent lacquer layer, which can also be labeled as a clear lacquer layer, and the integrated nanoparticles, according to the invention now provides the possibility that the clear lacquer can be removed by means of the energy of the laser irradiation. By selecting the particles in the nanometer range, the clearcoat layer remains transparent and can be activated simultaneously by means of the laser irradiation. It is thus possible to produce the control element or the control knob with an opaque coating and a clearcoat layer applied above and then incorporate a symbolism in the operating element or the button in one operation. Another significant advantage with respect to the known prior art is that the symbolism is introduced into the operating element as the last working step. Soiling of the control element by the introduction of the symbolism in an intermediate step of manufacturing in the coating or during transport of the control element before painting can not be detrimental to the operating element, i. affect the end product or the entire manufacturing process.

By carefully selecting the diameters of the nanoparticles introduced into the clearcoat layer, the clearcoat layer remains transparent, so that the seemingly metallic appearance of the control element is retained. The diameters of the nanoparticles are in the range between 10 nm and 10 μm and are thus not visible in the clearcoat layer.

The invention will be explained with reference to an embodiment of a control element. It shows

Figure 1 shows the section through an operating element for a motor vehicle, for example, represents a button for a climate control device.

FIG. 1 shows the section through an operating element 1 designed according to the invention, which is designed in the form of a key 1. The key 1 is hollow in its interior, and has different thicknesses. On the key base body 2, an opaque coating 3 is applied, on which in turn a clearcoat film 4 has been applied. In the coating 3 and the clearcoat layer 4, a symbolism 5 was introduced by means of a laser. In this case, the introduction of the symbolism 5 by means of a laser on the filigree and arbitrary form of the symbolism and on the basis of the removal of the coating 3 and the clearcoat layer recognizable, the removal in one step and thus by both layers 3, 4 identical, that is consistent , In the interior 6, a light source 7 is arranged, which emits light L at least in the direction of the upper side 8 of the key 1.

The key body 2 is limited in terms of its chemical and physical properties only in so far that it consists at least partially of a translucent material selected from the group: glass, ceramic and polymers. Preferably, the material is made of a polymer. Preferred polymers are plastics, such as polycarbonate (PC), acrylonitrile-butadiene-styrene (ABS, (PC + ABS) black, polyamide (PA) or polymethyl methacrylate (PMMA).) Transparent ceramics, such as, for example, a sapphire, can also be used Depending on the required light intensity of the symbol 5, it is conceivable in this case to form the material of the key base body 2 in different thicknesses 9, 10. As shown in FIG. 1, the thicknesses in the regions 9 and 10 are different, in order thus to provide sufficient Luminance in the area of the symbol 5 to provide.

On the key body 2 is an opaque coating 3, made of one or more different materials. Thus, it is conceivable according to the invention to cut off a metal layer or a metal layer system by means of a PVD or CVD method on the key base body 2. The coating 3 in this case had a thickness of up to 5 microns and consists of transition metals, precious metals, alloys or oxide, carbide, nitridic metal layers, which are applied in one or more layers. The thickness of the coating 3 is dependent on the material used and must be chosen in each case such that it can be removed by means of a laser activation. Furthermore the coating 3 can also be produced from a dyed lacquer. In addition, it is possible to subject the key body 2 to a suitable pretreatment, such as a plasma treatment. In addition, it is also conceivable to apply a primer coating as a coating 3 on the key body 2. The coating 3 is in any case impermeable to light, and has the advantageous property that the key base body is provided with a metallic or optically enhancing coating 3.

On this coating 3, the transparent clearcoat layer 4 according to the invention is applied. The application of the clearcoat layer 4 takes place in the usual manner by means of spraying. In the clearcoat layer 4 nanoparticles are introduced, which can be activated by means of the energy of the laser beam, so that the clearcoat layer 4 can be removed by means of the laser. The nanoparticles consist of metal oxides such as zinc oxide, indium tin oxide (ITO) and are transparent. The nanoparticles have a diameter of between 10 nm and 10 μm. The nanoparticles are used in a volume concentration of 0.01% up to 10%. The nanoparticles 11 are uniformly distributed in the clearcoat film 4 and shown as dots 11 in the clearcoat film 4 of FIG.

In the layer system 3, 4 of coating 3 and clearcoat layer 4, a symbol 5 is introduced after the application of the coating 3 and the clearcoat layer 4 by means of a laser. This is possible according to the invention in that the clearcoat layer 4 can be activated by means of the laser and because the coating 3 has a thickness which can be removed by means of the energy of the laser. It is thus possible according to the invention to introduce into the control element 1 any symbolism 5 after coating and spraying the button in the key 1 and in a single operation or process step. It is thus conceivable according to the invention to produce an operating element 1 which has a metallic appearance and in which a back-lightable symbolism is incorporated.

Such controls 1 are for example in the motor vehicle as controls, in consumer electronics, in kitchen appliances or in the so-called white goods, such as a washing machine stainless steel look, used.

The clearcoat film 4 has a thickness of up to 100 μm. The symbolism is thus backlashable with a suitable material, that is to say substrate, if, for example, polycarbonate is used as the translucent material.

Claims

1. Operating element, in particular for a motor vehicle, made of a translucent material (2) provided with at least one opaque coating (3) provided with a symbol (5) and with a transparent lacquer layer (4) on the coating (3) in that nanoparticles (11) are introduced into the lacquer layer (4) and that the coating (3) and the lacquer layer (4) are removed in regions by means of a laser. Second Operating element according to Claim 1, characterized in that the nanoparticles (11) have a diameter of 10 nm to 10 μm and are present in a volume concentration of 0.01% to 10% and consist of metal oxides. Third Operating element according to one of claims 1 and 2, characterized in that the Clearcoat layer (4) has a thickness which is smaller than 100 microns. 4th Operating element according to one of claims 1 to 3, characterized in that the material (2) is a translucent plastic (2), preferably a polycarbonate (PC) or a polymethylmethacrylate (PMMA), or a transparent ceramic, preferably a sapphire, or a glass is. 5th Operating element according to one of claims 1 to 4, characterized in that the coating (3) is a metal layer (3) or a colored, can be processed by means of a laser lacquer layer (3). 6th Operating element according to Claim 6, characterized in that the metal layer (3) has a thickness of <5 μm and is applied in one or more layers by means of a PVD or CVD method. 7th Control element according to claims 6 or 7, characterized in that the metal layer (3) is produced by means of a reactive PVD method and is present as an oxide, carbidic or nitridic metal layer (3). 8th. Operating element according to one of claims 1 to 8, characterized in that the material (2) with a below the coating (3) arranged additional adhesive layer, in particular a primer coating, is provided.