DE973771C - Thin, firmly adhering, wear-resistant, colored coverings on objects made of polyplastic materials - Google Patents

Description

Thin, firmly adhering, wear-resistant, colored coatings on objects made of polyplastic fabrics The invention relates to polyplastic masses Moldings used as consumer goods, household goods, jewelry, toiletries, clothing and equipment or parts of such objects are used and with which therefore a colored decoration is desirable and expedient and those with thin, firmly adhering, wear-resistant, rich, shiny metallic colors Coverings are provided. These coverings not only offer some protection against harmful influences, especially against moisture, but above all have that distinguishing feature that they have the shine and appearance of the objects Metals, especially the bright, diverse shades of color are very thin, more translucent Lend metal foils.

There are already coatings on objects made from polyplasts are known in various material compositions and designs. she mostly consist of organic, air-hardening, clear or colored lacquers, however, they have the disadvantage that they are not very stable at higher temperatures are. The technology already has metallic coatings on plastic objects produced by spraying or spraying on liquid metal. Apart from the inhomogeneous, coarsely crystalline structure that makes such coatings unsuitable for many purposes the metal layer that solidifies on the surface does not adhere firmly. Most of time thin air lamellae form between the base and the metal layer, which both a slight peeling as well as a fading of the tones caused by total reflection or irregular patches of color.

Plated thin metal foils also have a low mechanical and optical contact and show similar defects. Also by dusting of metal powder on the surfaces of suitably pretreated plastic objects results are not favorable, in particular no bright color tones are achieved been. Thin mica platelets with metallic coatings (silver) have also been used. and thereby creating strikingly shiny color effects without this process the refinement of platelets made of inorganic material is an essential technical process Gained importance.

Metallic ones produced by vacuum vapor deposition or cathode sputtering or oxide layers on insulating materials are mainly used in electrical engineering in capacitors and in optics as mirror coatings on silicate or synthetic glass related, since layers produced in this way are very thin and even. but also dielectric, thin layers of oxides and fluorides produced in the same way and other water-insoluble, temperature-resistant chemical compounds on various occasions, especially for changing the reflexes of optical elements and as light-absorbing coatings on glasses, light filters that protect against intense radiation and other radiation protection devices, found application.

So much for such shifts and shift combinations so far had found in the technology, it was about special optical tasks with a defined beam path in connection with clear, translucent documents of glass. They also made significant progress in building high-performance selective light filters or high-performance light splitting coverings.

The latter had the task of avoiding absorption losses If possible over a large, preferably the visible, spectral range on falling Letting light pass halfway and half reflecting it. For one about optical Utilization of absorbing substances beyond the purposes of this, with the involvement of interference phenomena Shimmering color combinations of layers have not yet been found to be technically useful Solutions.

So far one has the most diverse, suitable for various purposes Customizable options, metallic or non-metallic, from both types of material produced by vacuum vapor deposition or cathode sputtering on polyplastic substrates Layers, but especially the richness of the magnificently shining, shiny metallic colors and the great enrichment of technology that they give not recognized.

The invention consists in that consisting of polyplastic materials Moldings used as consumer goods, household goods, jewelry, toiletries, clothing and equipment or parts of such objects and with which a colored decoration is desirable and expedient, or at least visible Parts of their surfaces with thin, firmly adhering, wear-resistant, when viewed through or top view, rich, shiny metallic colors are provided, which alternate in thickness with absorbent metal or semiconductor layers of the order of a few to 100 Å and made of only sparingly or insoluble in water, few light-absorbing dielectric layers with a thickness of the order of magnitude composed of the wavelengths of visible light and under vacuum from the Gas phase are deposited, these layers according to light refraction and absorption capacity are selected and arranged so that for through and incident light Interference effects arise and the outer layers from mechanical and chemical consist of particularly resistant fabrics.

The progress on which the invention is based is therefore based on the knowledge that by using metals, especially several metals and semiconductors in connection with dielectric materials such as metal oxides, fluorides, tungstates, Sulphides, selenides in layer sequences, which according to thickness, refraction exponent, absorption capacity are well coordinated, not just against those that occur in use Produce sufficiently resistant, abrasion-resistant coatings on plastics, but it is still splendid in both reflected and translucent light give laudatory, brilliant colors that are often unknown in compact metals can. As polyplastic substances for the base, both polymerisation as well as condensation resins.

The layers designed according to the invention on the plastic objects have thicknesses on the order of a few angstroms up to wavelengths of visible light and more. The metals used with advantage are, for example, copper, Silver, gold, iron, cobalt, nickel, rhodium, palladium, platinum, titanium, vanadium, Chromium, manganese, zircon and aluminum as well as the rare earths are used. With a single metal in a single layer, there are few possibilities for modification and achieves only slight color effects that are known per se, which are still very diverse Type of substrate, application speed, gas influences, pressure and the presence of foreign matter.

However, all of these color effects are caused by the layers that follow the present invention are made in their various colors and the Metal luster exceeded, the distinguishing feature of the designed according to the invention Coverings or moldings made of polyplasts is that in them alternately on the one hand Metals or semiconductors such as selenium, selenides, sulfides and tellurides, for example Zinc or cadium sulfide, and on the other hand non-metallic substances, such as high-melting, water-insoluble, permanent oxides, fluorides, tungstates and silicates are, for example oxides of silicon, beryllium, germanium, titanium, thorium, Molybdenum and tantalum, rare earths and other metals or fluorides of magnesium, aluminum and thorium. Highly resistant, hard oxide or fluoride layers form the topmost protective layer, but they are also used as the bottom, directly on the layer resting on the base. Even sensitive ones, less so Corrosion-resistant substances, such as selenium, because of its being in a thin layer bright yellow-orange to red color used in the production of the colored coverings can be, or sulphides, one conveniently closes between two dense, protective ones Oxide layers.

The mentioned non-metallic substances are appropriately matched Layer thickness and suitable depending on the refractive power, absorption capacity and color selected arrangement drawn between the individual metal layers so that, apart from their own color, which is also important here, the metallic hues enhanced by interference effects and rich, bright colors are created, which for the linings of the invention are characteristic. These richly bright colors can more in translucent light or more in reflective light, depending on requirements Light appear and further changed by selective absorption in individual layers be. Such selectively absorbing layers can, for example, be made from oxides of rare earths, titanium and molybdenum.

One recognizes without further ado the rich, hardly to be exhausted variation possibilities, which can be achieved with the complex, colored coverings according to the invention. here some examples of layer sequences are mentioned: a) plastic - silicon monoxide - Selenium - aluminum oxide - Cu - silicon dioxide, b) plastic - silicon oxide - titanium - tantalum pentoxide - gold - germanium dioxide, c) plastic - metal - oxide - sulfide Oxide.

With some of the coverings according to the invention it was observed that a Becoming matt by crystallizing out the metallic or dielectric Layers occurred. In order to get the effects of the applied layers small admixtures of foreign substances introduced into the layers, which crystallize out impede. In the production of aluminum layers, for example, low, simultaneously evaporated amounts of silicon such a crystallization.

Of course, the individual layers can also be material be inhomogeneous, especially any mixing ratios of metals are present. Phosphorescent and fluorescent substances can be installed. The fat of the individual layers is in the order of magnitude of absorbent materials a few to 100 Å, in the case of non-absorbent materials it can be much higher and is usually in the order of magnitude of the wavelengths of visible light. The total thickness the multilayer coverings according to the invention can be as much as a few microns.

As a method for producing the coatings according to the invention offer look at the most varied of possibilities, known per se, in which the used substances in very fine, atomic or molecular, disperse form from the Precipitate gas phase. The conversion into the gas phase takes place either thermally by heating the substances in a vacuum or by ion bombardment of cathodes that are covered with the substances to be steamed.

Both methods have the advantage that the atoms or molecules of the the substances used receive a relatively high kinetic energy and the base, on which they should come to condensation, both of adhering foreign matter free, as well as penetrate deep into their structure and thus a firm anchor effect of the coating.

These processes can be controlled so that the finest structure the coating layers become more or less uniformly amorphous or more crystalline. First of all, more easily condensable substances will be precipitated higher atomic or Molecular weight and higher melting point and the troublesome Do not show the effect of surface migration, rather stick to it evenly. Provides this thin layer that may not be visible to the eye under certain circumstances the condensation nuclei for those that are then more difficult to condense Substances that experience shows like to migrate or move on to the surface of the base. evaporate again. The formation of larger piles with empty spaces in between becomes like this prevented. With rapid steaming with a dense stream of steam, less in the course of the process Seconds you get a more amorphous, more homogeneous structure, but through slower vaporization with a low density vapor stream a more crystalline one Structure. The latter shows lower heat and electrical conductivity and has greater scatter reflection, therefore gives a more metallic appearance. Particularly the middle layers can get this structure, while one is preferred the bottom and top layers fine, evenly amorphous designed to a high adhesive strength and sufficient wear resistance of the covering achieve.

To a later change of the layer structure, especially by According to the invention, to avoid crystallization under the influence of heat designed coverings also receive an aging treatment, for example by Warming to higher temperatures, as far as the polyplastic base can handle it. A kind of recrystallization then occurs in individual layers, but this is due to the small thickness cannot progress to a visible change. Materially non-uniform mixed layers are more resistant to recrystallization and are also provided according to the invention. They are obtained by simultaneous evaporation different substances.

The individual layers or the thicknesses of individual layers of the coating can have a different surface area if during their manufacture differently designed stencils can be used. This enables the generation patterned, e.g. B. colored coverings provided with ornaments on plastic objects.

The coverings designed according to the invention can be used anywhere on the one hand They are used wherever plastics are used in technology, transport and the home found to save expensive metal, but where you can get a metallic Appearance want to receive. The use of precious metals in the coverings is not expensive because of the extremely thin layer.

Vehicle accessories and interior equipment parts, such as dashboard fittings, Horn buttons and hub caps, hood ornaments, etc., but then also jewelry items, Jewelry containers, toys, toiletries, parts of office and household machines, Fittings, wall coverings, buttons, advertising items made from polyplasts, and even fabric made of natural and artificial fibers can be combined with the colored coverings according to the Invention to be covered.

Another advantage is that the coverings, despite their metallic Feel warm to the touch. This does not only apply to underlays behind transparent ones Synthetic resin surfaces, but also for top coverings, as their thermal conductivity is low is.

On the other hand, the coverings according to the invention offer completely new effects and properties. The radiant, saturated, metal-like ones that can be achieved with them Shades of color that one has not thought of using so far mean a big one Enrichment of technology and a considerable advance.

In the figure, an embodiment of the invention is shown as an example Coatings shown on a tray. A means the base of a polyplastic Substance, B an oxide layer, e.g. B.

SiO, C a metal layer, e.g. B. Cu, D silicon monoxide, E chromium and F silicon dioxide.

PATENT APPROVALS: I. Moldings consisting of polyplastic materials, used as utility, household, jewelry, toiletries, clothing and equipment or used as parts of such objects and which therefore have a colored decoration is desirable and expedient, characterized in that at least visible parts of their surfaces with thin, firmly adhering, wear-resistant, When viewed through or on top of the floor, the coverings show rich, shiny metallic colors are provided, which alternately consist of absorbent metal or semiconductor layers on the order of a few to 100 Å thick and difficult in water or insoluble, poorly light-absorbing dielectric layers with a thickness in composed of the order of magnitude of the wavelengths of visible light and below Vacuum from the gas phase are deposited, these layers after light refraction and absorbency are selected and arranged so that for continuous and incident light, interference effects arise and the outer layers from mechanically and chemically particularly resistant materials.

Claims (1)

2. Shaped body with coverings according to claim 1, characterized in that that alternating metals or semiconductors and dielectric layers in to achieve of color effects are arranged according to dimensioned thickness, preferably the corrosion resistance of the substances in the coatings increases from the inside out. 3. Shaped body with coverings according to claim I, characterized in that that the corrosion resistance of the covering is achieved by the fact that individual layers, especially the top layer, made of hard, durable fabrics, especially made of water-insoluble oxides, for example from silicon dioxide or silicon monoxide, exist. 4. Shaped body with coverings according to claim I, characterized in that that the metallic layers are made of one or more of the metals copper, silver, Gold, iron, cobalt, nickel, rhodium, palladium, platinum, titanium, vanadium chromium, Manganese, aluminum, zirconium and the rare earths or from alloys of these metals exist, the metals in layers individually or in any mixing ratio can be present next to each other in the same layer, so that in the translucent andior in reflected light, diverse, based on the properties of thin metal films based colors occur. 5. Shaped body with coverings according to claim I, characterized in that that between the metal layers as dielectric oxides of silicon, germanium, Berylliums, Aluminum, Titans, Thoriums, Tantalum, Molybdenum, Iron and the rare ones Earths or fluorides, in particular fluorides of magnesium and aluminum, or also silicates and tungstates, or as semiconductors silicon, germanium, selenium, sulfides and selenides are applied. 6. Shaped body with coverings according to claim I, characterized in that that they contain phosphorescent substances, for example phosphorescent sulfides. 7. Shaped body with coverings according to claim I, characterized in that that the metallic and absorbent layers preferably have a thickness of up to a few 100 Å, while the non-absorbent, non-metallic layers have one Have thicknesses in the order of magnitude of the wavelengths of visible light. 8. Shaped body with coverings according to claim 1, characterized in that that in them layers of less stable, sensitive materials, for example made of selenium, embedded between dense, highly resistant, protective layers of oxides are. 9. Shaped body with coverings according to claim I, characterized in that that the substances in the layers in the finest, even, non-crystalline distribution are present. IO. Shaped body with coverings according to Claim I, characterized in that that the fine structure of the individual layers is different, that of the lowest and the uppermost layers, for example, more or less amorphous, those of the middle Layers more crystalline. II. Shaped body with coverings according to claim I, characterized in that that the crystallizability of individual layers is reduced in that they contain small amounts of foreign matter. 12. Shaped body with coverings according to claim I, characterized in that that they are used as underlay or surface covering and either their permeability or their reflectivity for visible light predominates, or both light components are about the same size. 13. Shaped body with coverings according to claim I, characterized in that that in order to generate patterns, the individual layers of the coatings are different have a geometric shape. 14. A method for producing the molded body with coverings according to claim I to I3, characterized in that to obtain a different, either more amorphous or more crystalline structure of each in itself known Way by evaporation or cathode sputtering of the coating materials in a neutral, for example in a vacuum, or in an active way, for example for the production of oxides the application speed to be applied to the layers in an oxygen-containing residual gas atmosphere, the gas pressure, the addition of foreign substances, the composition of the, if applicable active atmosphere in the coating system or the temperature of the substrate or more of these conditions can be modified. Publications considered: German Patent Specifications No. 716 153, 76738 in 839 250, 909 143, 947 339; German patent application p I0407 / 32 b (announced September 21, 1950); Swiss Patent No. 220 789; UNITED STATES. -Patent specification No. 2,384,500; Journal of Applied Physics, Volume 7, Issue 2, pp. 53 to 66; Journal de physique et le rad., Vol. II, 1950, p.444ff .; Philos. mag., 7, I904, p. 376 ff .; Steel, I25, I949, pp. 84 to 87, 115 and II6.