EP3017095B1 - Metal plate - Google Patents

Description

The invention relates to a metal plate according to the preamble of claim 1.

Such a metal plate is intended for a coin, for a part of a coin, for example pill or ring. Coins are not only used as circulating coins, but also serve as collector coins and / or foams. A foam is, for example, a medal, which is awarded as an award for special achievements, such as sporting nature. Coins, in particular collector coins or foams, must also meet high aesthetic requirements. For example, awarding medals at sporting events is an important media event, with the medals often being an important identification object of these events. Even collector coins, which are arranged for example behind a showcase, should meet the aesthetic requirements. The appearance of a coin is often formed only by the embossing, ie a three-dimensional relief.

The disadvantage of this is that coins, viewed from a distance, seldom satisfy the aesthetic requirements, or have little distinctive character from a distance, since the characteristic embossing can only be clearly recognized from close up.

From the EP 0 280 886 A1 A method for producing decorative coatings on metals is known. In this case, a comparatively thick electrochemical layer is produced, the color of which is predetermined by color pigments.

From the EP 0 802 267 A1 For example, an aluminum surface having an interference layer is known as a coloring surface layer. The interference layer has an aluminum oxide layer and a partially transparent layer applied thereon. The interference layer may have local regions of predeterminably different color, which may be caused by a variation of the layer thickness of the aluminum oxide layer or the properties of the partially transparent layer.

From the DE 10 2010 011185 A1 For example, an article with a metallic surface is known which has a glass, glass-ceramic or ceramic-like protective layer is provided. The generation of a pattern is not provided here.

From the WO 91/19649 A1 is a temperature monitor with an interference layer on a flexible substrate known. When a limit temperature is exceeded, the interference layer delaminates, thereby changing its color.

From the EP 0 303 400 A2 a temperature monitor with an interference layer is known which changes the color when a limit temperature is exceeded.

From the WO 2011/066594 A1 An arrangement of coins in a carrier mask is known, wherein the coins are coated together with the carrier mask with a substantially invisible protective layer.

The object of the invention is therefore to provide a metal plate of the type mentioned, with which the mentioned disadvantages can be avoided, with which the aesthetic requirements is still guaranteed even at a greater distance, and which is durable and can be produced at the same time with little effort.

This is achieved by the features of claim 1 according to the invention.

This results in the advantage that the coins are well distinguishable and / or identifiable to the observer even from a distance, since a good contrast can be achieved by the two-colored optical element. As a result, for example, medals of a sporting event lose nothing of their important identifiable character even in a television broadcast. Also, in collector coins and / or foams from a distance already given the desired optical effect, which is why it is sufficient to consider these coins in a closed showcase, whereby a for the coin weary or polluting removal from the showcase is no longer necessary. Furthermore, the twofold optical element allows a large number of further, sophisticated and hitherto impossible coin designs. The oxide layer offers the advantage that its interference color has substantially the same gloss as a polished metal surface, and is not dull or darker than a pigment paint or finish, and therefore meets the highest aesthetic requirements. Furthermore, oxides are chemically slower than metals, causing the Coin does not migrate even after many years, the outer appearance, since there is no further unwanted oxidation.

Furthermore, the invention relates to a method for producing a two-colored optical element of a metal plate according to claim 10.

The object of this method is to produce a two-color optical element described above in a particularly simple and reliable manner.

This allows coins to be made, with little added expense, to conventional coins, with an advantageous two-color optical element.

The subclaims relate to further advantageous embodiments of the invention.

It is hereby expressly referred to the wording of the claims, whereby the claims at this point are incorporated by reference into the description and are considered to be reproduced verbatim.

• Fig. 1 eine bevorzugte Ausführungsform einer Münze mit einer als Pille ausgebildeten Metallplatte in Draufsicht;
• Fig. 2 den Schnitt entlang der Linie A in Fig.1 als bevorzugte erste Zwischenstufe eines zwe1färbigen optischen Elementes;
• Fig. 3 den Schnitt aus Fig. 2 als bevorzugte zweite Zwischenstufe eines zweifärbigen optischen Elementes;
• Fig. 4 den Schnitt aus Fig. 2 als erste bevorzugte Ausführungsform eines zweifärbigen optischen Elementes;
• Fig. 5 den Schnitt aus Fig. 2 als zweite bevorzugte Ausführungsform eines zweifärbigen optischen Elementes; und
• Fig. 6 den Schnitt aus Fig. 2 als dritte bevorzugte Ausführungsform eines zweifärbigen optischen Elementes.

The invention will be described in more detail with reference to the accompanying drawings, in which only preferred embodiments are shown by way of example. Showing:

• Fig. 1 a preferred embodiment of a coin with a formed as a pillar metal plate in plan view;
• Fig. 2 the section along the line A in Fig.1 as a preferred first intermediate of a two-colored optical element;
• Fig. 3 the cut out Fig. 2 as the preferred second intermediate of a two-color optical element;
• Fig. 4 the cut out Fig. 2 as the first preferred embodiment of a two-color optical element;
• Fig. 5 the cut out Fig. 2 as a second preferred embodiment of a two-color optical element; and
• Fig. 6 the cut out Fig. 2 as the third preferred embodiment of a two-color optical element.

The Fig. 1 to 6 show preferred embodiments of a metal plate 1 for a coin 2, for a pill 3 of a coin 2 or for a ring 4 of a coin 2, wherein at least a portion of a surface on at least one side of the metal plate 1 has a two-colored optical element 5. The metal plate 1 can in this case particularly preferably be formed in one piece and / or homogeneously. Homogeneous in this context means that the metal plate 1 has substantially the same chemical composition over the entire volume, in other words that it is not a bimetallic plate. A coin 2 may be formed in one piece or in several pieces, in particular in two pieces. As pill 3 of a coin 2, in a two-part coin 2, for example one euro coin, preferably the inner part of the coin 2 is designated. The ring 4 of a coin 2 is preferably that part of a two-part coin 2 which preferably surrounds the pill 3 at the edge. The metal plate may be square or round, in particular circular, be formed. A coin 2, or a part of a coin 2, consisting of the metal plate 1 may particularly preferably be designed as a collector coin and / or as a foam, in particular as a medal. The partial area of the surface on at least one side of the metal plate 1 will hereinafter be referred to merely as the partial area. The two-color optical element 5 is arranged on at least one side of the metal plate 1. It can also be provided that a further two-colored optical element 5 is arranged on the opposite side. The two-color optical element 5 may also have more than two colors, and is hereinafter referred to merely as the optical element 5.

The optical element 5 has at least a first region 6 with a first oxide layer 7 with a first color, which first color is an interference color. Particularly preferably, the first oxide layer 7 is at least partially transparent. In this context, an interference color is a color which arises when a light beam, in particular white light, is at least partially reflected at both boundary surfaces of a layer of an at least partially transparent material, whereby the difference in the optical path length results in a constructive and / or destructive interference of the individual color components of the reflected light beam. Therefore, regions of the spectrum of the reflected light are deleted, depending on the wavelength, whereby the reflected light as interference color has the complementary color of the deleted spectral regions. In particular, since an interference color depends on the observation angle, the observation direction for defining the first color can be set as normal to the viewed surface of the metal plate 1.

In particular, it can be provided that the first oxide layer 7 has a first thickness of 20 nm to 2000 nm, in particular 30 nm to 1000 nm, particularly preferably 50 nm to 500 nm. Up to 2000 nm, interference colors are still very noticeable. In the range from 50 nm to 500 nm in this case interference colors are particularly pronounced.

Particularly preferably, it can be provided that the first thickness of the first oxide layer 7 is substantially constant over the entire area of the at least one first region 6.

Furthermore, it can be particularly preferably provided that the first oxide layer 7 is formed as a metal oxide layer.

The optical element 5 furthermore has at least one second area 8 with a second color, the first color being different from the second color. In this case, the first region 6 and the second region 8 may be parts of the subregion. In particular, it can be provided that the first region 6 is arranged directly adjacent to the second region 8. Furthermore, it can be provided that the subarea is designed to be continuous.

The difference in color can be defined here particularly preferably according to the Lab color space, which is also known under the name CIELAB color space. The Lab color space has three dimensionless axes, the L axis, which represents the brightness and can assume a value between 0 and 100, the a axis which represents the green or red portion of a color and a value between -150 and 100, as well as the b-axis which represents the blue or yellow part of a color and a value between -100 and 150 can take. Through the Lab color space, all colors perceptible by humans with different color valences, saturations and brightnesses can be represented as a coordinate point, whereby the choice of the axes means that the same Euclidean distances of two coordinate points correspond to the same color separations.

In this regard, it can be particularly preferably provided that the Euclidean distance of the first color to the second color in the dimensionless Lab color space is at least 5, in particular at least 10, particularly preferably at least 20, dimensionless units. Here, the first color represents a first coordinate point, and the second color represents a second coordinate point of the dimensionless Lab color space.

The first area 6 and / or the second area 8 may be formed, for example, according to a predetermined motif. The choice of motive shown here is absolutely arbitrary and it is clear that the first area 6 and / or the second area 8 can represent any motive. In Fig. 1 is depicted as a motif of the capital letter H, H here being the second area 8, and the surrounding area being the first area 6. The first region 6 and / or the second region 8 can in this case be in the form of a contiguous region, as in FIG Fig. 1 represented, or be formed of a plurality of sub-areas.

Particularly preferably, it can be provided that the first region 6 is formed as a recess 9 with respect to the second region 8. In other words, the optical element 5 can be provided with a height profile. The optical element 5 may in this case be provided in particular with an embossing, wherein, as in Fig. 2 to 6 illustrated, the first region 6 as a recess, and the second region 8 is formed as a survey 13. As a result, the optical element 5 can be produced particularly easily. Furthermore, the motif can be represented congruently by the embossing as well as by the optical element 5. In Fig. 2 to 6 the dimension is reproduced very distorted for better understanding.

Alternatively it can be provided that the second region 8 is formed as a recess 9 with respect to the first region 6.

In particular, it can be provided that the first region 6 is formed as a depression 9 by at least a height of 0.05 mm with respect to the second region 8. Furthermore, it can be provided that the first region 6 and / or the second region 8 have a further embossing, but which have a smaller depth than 0.05 mm. This further embossing can preferably represent fine details of the motif here.

For the production of thin oxide layers, many different methods are known to those skilled in the art.

The first oxide layer 7 may be made, for example, by a physical vapor deposition method. Such physical vapor deposition processes, in particular sputtering or sputtering, offer the advantage that a large number of possible oxides can be applied. As a result, the material of the first oxide layer 7 can be selected substantially independently of the material of the metal plate 1.

The first oxide layer 7 may be manufactured as a further example also by means of a chemical vapor phase-off method. Again, many methods for producing uniform oxide layers are known.

Alternatively, the first oxide layer 7 may be made by a thermal process, for example tempering. In this case, the metal plate 1 is heated in such a way that a first oxide layer 7 of predeterminable thickness is formed.

Particularly preferably, it can be provided that the first oxide layer 7 is produced electrochemically. An electrochemical coating process has the advantage that it can be carried out with simple means and with good controllability.

It has proven to be particularly advantageous in this case if the first oxide layer 7 is produced electrochemically by anodic oxidation. Anodic oxidation is also known by the term anodic dip coating, ATL for short. For aluminum, anodic oxidation is often referred to as anodization. An oxide layer produced by anodic oxidation advantageously has a particularly uniform layer thickness. Furthermore, the Anodic oxidation well controlled, the coating process is depending on the coating parameters at a certain thickness self-stopping. Self-stopping means in this context that due to the high electrical resistance of the growing oxide layer, it comes from a certain layer thickness to no further, or only an insignificant, layer growth. As a result, a final first thickness of the first oxide layer 7 can be specified particularly well by the different coating parameters. Furthermore, in the case of anodic oxidation, a particularly good mechanical toothing of the first oxide layer 7 with the remaining metal plate 1 is provided.

In particular, it can be provided that the first oxide layer 7 comprises an oxide of the material of the metal plate 1. As a result, the first oxide layer 7 is particularly stable, and has a particularly high adhesion to the metal plate 1.

Particularly preferably, it may be provided that the metal plate 1 consists of a metal or a metal alloy of group 4, 5 and / or 6 of the Periodic Table, in particular Ti, Mo, and / or Nb. It has been found that these metals or metal alloys are particularly suitable for the optical element 5 due to the properties of the metals or the associated metal oxides.

In particular, it can be provided that the metal plate 1 consists of Nb, ie niobium, since Nb has been found to be particularly suitable.

The second region 8 can be designed in different ways. For example, it can be provided that the second area 8 is painted, painted and / or printed.

It may preferably be provided that the second region 8 is uncoated, that is, no further coloring layer is artificially applied to the second region. In this case, the second region 8 essentially has the color of the material of the metal plate 1. The second region 8 can also be regarded as uncoated if a natural oxide layer forms by reaction of the bare metal plate 1 with the surrounding atmosphere, for example aluminum oxide on aluminum. An uncoated second area 8 is light and has a good contrast to the first region 6 with its interference color.

Particularly preferably, it can be provided that the second region 8 has a second oxide layer 10, and in particular the second color is an interference color. As a result, an optically particularly sophisticated optical element 5 can be formed, in particular from a distance, whereby now also the second region 8 through the second oxide layer 10 is inert to external environmental influences.

The second oxide layer 10, like the first oxide layer 7, can be produced by different coating methods.

In particular, it can be provided that the second oxide layer 10 is produced electrochemically, in particular by anodic oxidation. The anodic oxidation here has the additional effect that, if the thickness of the first oxide layer 7 is already self-stopping, there is no further increase of the first thickness, whereby the manufacturing process is particularly easy to control.

It can preferably be provided that the first oxide layer 7 and the second oxide layer 10 are produced by the same coating method, and in particular, except for the thickness, substantially the same as the first oxide layer 7 is formed.

In particular, it can be provided that the second oxide layer 10 has a second thickness of 20 nm to 2000 nm, in particular 30 nm to 1000 nm, particularly preferably 50 nm to 500 nm.

Particularly preferably, it can be provided that the second thickness of the second oxide layer 10 is substantially constant over the entire area of the at least one second area 8.

Furthermore, it can be particularly preferably provided that the first oxide layer 7 is thicker than the second oxide layer 10. By the thicker first oxide layer 7, a good contrast of the two interference colors of the first region 6 and second area 8 can be achieved. In particular, it may be provided here that the first oxide layer 7 is thicker than the second oxide layer 10 by 25 nm, in particular 50 nm, particularly preferably 100 nm.

Alternatively it can be provided that the first oxide layer 7 and the second oxide layer 10 have substantially the same thickness. The different color of the first region 6 and of the second region 8 can in this case take place in that the first region 6 and the second region 8 have a different surface roughness, whereby already differently perceivable interference colors of the first region 6 and the second region 8 can be achieved.

According to the preferred embodiment of a coin in Fig. 1 It is particularly preferable to provide a coin 2 with pill 3 and ring 4, wherein at least the pill 3 is designed as a metal plate 1 as an advantageously formed metal plate 1 with an optical element 5. The ring 4 of the coin may in this case particularly preferably be formed from a metal other than the pill 3, in particular silver. The advantage of this is that the ring 4 protects the pill 3, and thus also the optical element 5, from mechanical wear.

Furthermore, the invention comprises methods for producing the two-color optical element 5 on at least one side of the metal plate 1, in particular a coin 2, a pill 3 of a coin 2 or a ring 4 of a coin 2, comprising an oxide layer generating step and a surface modification step.

In the oxide film forming step, an oxide film 11 having an interference color is formed at least on the one portion of the surface of the metal plate 1.

Furthermore, in a surface modification step, the at least one second region 8 of the subregion of the surface is changed by means of an erosive method in order to achieve different optical properties of a first region 6 of the subregion of the surface. The different optical property can, for example, as a different color or different Dullness be formed.

As a result, a coin 2, a pill 3 of a coin 2 or a ring 4 of a coin 2 with an advantageous optical element 5 can be produced in a particularly simple and reliable manner.

Although coating methods are also known which coat, for example by means of a mask, specifically only the first region 6 with an oxide layer 11, however, it has proved advantageous and simpler to coat a whole subregion of the surface of the metal plate 1 and separate from the oxide layer production step selectively altering optical properties of the surface by means of an erosive method, which surface modification step may be performed before or after the oxide layer forming step. This surface modification step may include partially ablating the oxide layer 11, but may also involve merely modifying the surface prior to the oxide layer forming step, for example, by roughening or polishing the surface, whereby the color of the oxide layer 11 formed thereon may be changed.

In this case, it can preferably be provided that, prior to the surface modification step, at least the one subarea of the surface of the metal plate 1 is roughened, in particular pickled. As a result, both the adhesion of the oxide layer 11 can be improved and a better and more uniform optical sensation of the oxide layer 11 can be achieved. Furthermore, by selectively polishing and / or abrading the roughened surface, a first region 6 and a second region 8 of the surface can be produced which have different optical properties, in this case gloss or mattness.

For producing an optical element 5, it may be provided that the surface modification step is carried out before the oxide layer generation step. In this case, in particular by selective roughening, grinding or polishing of the portion of the still metal surface of the metal plate 1, a first region 6 and a second region 8 with different optical properties can be produced. By the subsequent generation of the Oxide layer 11 on the portion of the surface, the oxide layer 11 has substantially the same thickness, but by the different structure of the underlying metal surface, the optical effect of the oxide layer 11 can be changed, whereby the first region 6 and the second region 8 perceived differently colored become. Thereby, a particularly simple method of manufacturing an optical element 5 can be provided because the oxide layer forming step can be formed as a final manufacturing step, and with the generation of only one oxide layer, an interference color-having first region 6 and second region 8 having different colors can be provided.

Alternatively, it may be preferable that the oxide layer generating step is performed before the surface modification step, and that in the surface modification step, the oxide layer 11 is removed in the at least one second region 8 and left in the at least one first region 6. This also makes it possible to produce an optical element 5 in a particularly simple manner, since first an oxide layer 11 is applied to the at least one subregion of the surface, and then the oxide layer 11 is selectively removed only in the second region 8.

Particularly preferably, it can be provided that, prior to the surface modification step, a height profile is impressed on the at least one subregion of the surface of the metal plate 1. In this case, in particular, the first region 6 as a recess 9, and the second region 8 can be formed as a survey 13. As a result, it can be determined by the height profile in which regions of the at least one subregion of the surface of the metal plate 1 the ablative process of the surface modification step removes the surface.

By means of the height profile, for example, the selective removal of the oxide layer 11 in the second region 8 can be simplified. The embossment of the height profile may be performed before or after the oxide layer forming step. It has proven to be advantageous if the height profile is impressed on the metal plate before the oxide layer generating step, since thereby the oxide layer 11 is not injured by the embossing process.

Preferably, it can further be provided that after the removal of the oxide layer 11 in the second region 8, the metal plate 1 is again embossed. This re-stamping can in particular include fine details.

When the surface modification step takes place before the oxide layer production step, the impressing of the height profile enables the first region 6 and the second region 8 to be lifted apart from one another such that in the ablation process of the surface modification step the second region 6 is changed and the first region 8 is not.

It can preferably be provided that a mechanical method, in particular planer grinding and / or polishing, is selected as the removing method of the surface modification step. If the first region 6 is formed as a depression 9, and the second region 8 as an elevation 13, it can be provided, in particular, that the at least one second region 8 is removed mechanically by abrading and / or polishing. This offers the great advantage that the shaping of the first region 6 and of the second region 8 can be effected by the embossing which is usual in any case with a coin 2. As a result, no complicated further method for shaping the first region 6 and the second region 8 is necessary.

The selective removal of the second region 8 can also be effected by other ablation methods. For example, by a laser, an ion and / or plasma jet, or by engraving. If the oxide layer generating step has already taken place, the oxide layer 11 can also be removed by means of a lithographic process.

In particular, it may be provided that an oxide of the material of the metal plate 1 is produced as oxide layer 11 of the oxide layer generation step. As a result, the oxide layer 11 is particularly resistant, and has a particularly high adhesion to the metal plate 1.

Preferably, it may be provided that the oxide layer 11 of the oxide layer generation step by means of an electrochemical process, in particular by an oxidation of the metal plate 1 by anodic oxidation, is produced. By an electrochemical method, the oxide layer 11 can be produced particularly easily. Particularly preferably, it can be provided that the oxide layer 11 is produced by oxidizing the metal plate 1 by anodic oxidation. The advantages of anodic oxidation are, as already described above, the uniform layer thickness and the good controllability. Alternatively, the oxide layer 11 may be formed by a physical vapor deposition method, a chemical vapor deposition method, or thermal annealing.

Individual steps of a first preferred embodiment of such a method are described in Fig. 2 to Fig. 4 shown.

In Fig. 2 a part of the metal plate 1 is shown, which has been provided with a height profile. In this case, a height profile has already been embossed on the metal plate 1. Fig. 3 will be the body of the Fig. 2 in which the metal plate has been coated with the oxide layer 11 which covers the first region 6 and the second region 8 in the same way, ie the oxide layer generation step has already taken place. In Fig. 4 In the surface modification step, the surface of the metal plate 1 was ground flat as indicated by the dot-and-dash line, whereby the oxide layer 11 in the second region 8 was ablated and left in the first region 6.

Fig. 4 also represents a first preferred embodiment of the two-colored optical element 5. Here, the oxide layer 11 left in the first region 6 represents the first oxide layer 7 of the optical element 5. The second region 8 is uncoated.

Preferably, when the surface modification step is performed after the oxide layer forming step, it may be provided that after the surface modification step, a further oxide layer 12 is formed on the at least a portion of the surface of the metal plate 1. In this case, it can preferably be provided, in particular, that the further oxide layer 12 is produced by the same method as the oxide layer 11. As a result, an optical element having a first region 6 and a second region 8 to be provided, wherein both areas 6,8 have an interference color.

Particularly preferably, it can further be provided that the further oxide layer 12 is produced such that the first region 6 has a first oxide layer 7 with a first thickness, and the second region 8 has a second oxide layer 10 with a second thickness, and that the first Thickness is greater than the second thickness. This results in two different interference colors, which are well distinguishable from each other. By the thicker first oxide layer 7, a good contrast of the two interference colors of the first region 6 and the second region 8 can be achieved.

In particular, it can be provided that the further oxide layer 12 in the second region 8 represents the second oxide layer 10.

Fig. 5 Here, the first oxide layer 7 has a self-stopping first thickness, and the further oxide layer 12 was produced by means of anodic oxidation, which is why there was essentially no further layer growth in the first region 6. Therefore, also in the second preferred embodiment, the oxide layer 11 left in the first region 6 represents the first oxide layer 7 of the optical element 5. The further oxide layer 12 in the second region 8 represents the second oxide layer 10 of the optical element 5 in the second preferred embodiment.

In the third preferred embodiment in FIG Fig. 6 In the coating process for producing the further oxide layer 12, further layer growth occurred in the first region 6. This is the case, for example, if the further oxide layer 12 was produced by means of a physical vapor deposition process, where layer growth occurs independently of the substrate, or because in the case of an anodic oxidation, the first thickness before the production of the further oxidation layer was not self-stopping. The first oxide layer 7 in the first region 6 therefore consists of the oxide layer 11 and the further oxide layer 12 in the third preferred embodiment. The further oxide layer 12 in the second region 8 also constitutes the second oxide layer 10 of the third preferred embodiment optical element 5 is.

According to a fourth preferred embodiment, not shown, it can preferably be provided that the at least one subregion of the surface of the metal plate 1 is embossed and roughened, in particular pickled. This creates a height profile with a roughened surface. Then, the surface modification step is performed by grinding and polishing the second region 8, whereby the second region 8 is glossy, but the first region is still dull. Subsequently, in the oxide layer generation step, the oxide layer 11 is produced on the at least one subregion of the surface, different interference colors being produced by the different surface structure and resulting optical properties of the first region 6 and second region 8.

In order to produce an optical element 5 with more than two colors, it may be provided, for example, that a third region, which is in particular a subregion of the second region 8, is removed. As a result, an optical element 5 having three colors can be manufactured. By further coating with oxides, and / or again abrading area by area, an optical element 5 with any number of colors can be produced.

Claims (18)

1. A metal plate (1) for a coin (2), for a centre pill (3) of a coin (2) or for a ring (4) of a coin (2), wherein at least a subregion of a surface on at least one side of the metal plate (1) comprises a dual-coloured optical element (5), wherein the optical element (5) comprises at least one first region (6) with a first oxide layer (7) with a first colour, which first colour is an interference colour, and at least one second region (8) with a second colour, wherein the first colour is different from the second colour, wherein a height profile is formed by minting in the at least one subregion of the surface of the metal plate (1), wherein the first region (6) is formed as a depression (9) of the height profile in relation to the second region (8), characterized in that a motif is displayed in a congruent manner by both the minting of the height profile and also by the optical element (5).
2. A metal plate (1) according to claim 1, characterized in that the first oxide layer (7) is produced electrochemically, especially by anodic oxidation.
3. A metal plate (1) according to one of the claims 1 to 2, characterized in that the first oxide layer (7) comprises an oxide of the material of the metal plate (1).
4. A metal plate (1) according to one of the claims 1 to 3, characterized in that the metal plate (1) consists of a metal or a metal alloy of the group 4, 5 and/or 6 of the periodic system, especially Ti, Mo, and/or Nb.
5. A metal plate (1) according to one of the claims 1 to 4, characterized in that the second region (8) comprises a second oxide layer (10), and the second colour in particular is an interference colour.
6. A metal plate (1) according to claim 5, characterized in that the second oxide layer (10) is produced electrochemically, especially by anodic oxidation.
7. A metal plate (1) according to claim 5 or 6, characterized in that the first oxide layer (7) is thicker than the second oxide layer (10).
8. A coin (2), comprising a metal plate (1) according to claim 1 to 7.
9. A coin (2), comprising a centre pill (3) and a ring (4), characterized in that at least the centre pill (3) is formed as a metal plate (1) according to claim 1 to 7.
10. A method for producing a dual-coloured optical element (5) on at least one side of a metal plate (1), especially a coin (2), a centre pill (3) of a coin (2) or a ring (4) of a coin (2), comprising

    - an oxide layer production step, in which an oxide layer having an interference colour is produced at least on a subregion of a surface of a metal plate (1),

    - and a surface modification step, wherein before the surface modification step a height profile is formed by minting onto the at least one subregion of the surface of the metal plate (1), wherein at least one first region (6) of the subregion of the surface is formed as a depression (9) of the height profile in relation to at least one second region (8) of the subregion of the surface, wherein in the surface modification step the second region (8) of the subregion of the surface is modified through an abrasive process for achieving different optical properties between the second region (8) and the first region (6) of the subregion of the surface, wherein a motif is displayed in a congruent manner by both minting of the height profile and also by the optical element (5).
11. A method according to claim 10, characterized in that before the surface modification step at least the one subregion of the surface of the metal plate (1) is roughened, especially pickled.
12. A method according to claim 10 or 11, characterized in that the surface modification step is carried out before the oxide layer production step.
13. A method according to claim 10 or 11, characterized in that the oxide layer production step is carried out before the surface modification step, and that in the surface modification step the oxide layer (11) is removed in the at least one second region (8) and is left in the at least one first region (6).
14. A method according to one of the claims 10 to 13, characterized in that a mechanical process, especially flat grinding and/or polishing off, is selected as the abrasive process of the surface modification step.
15. A method according to one of the claims 10 to 14, characterized in that an oxide of the material of the metal plate (1) is produced as the oxide layer (11) of the oxide layer production step.
16. A method according to one of the claims 10 to 15, characterized in that the oxide layer (11) of the oxide layer production step is produced by means of an electrochemical process, especially by oxidising the metal plate (1) through anodic oxidation.
17. A method according to one of the claims 13 to 16, characterized in that after the surface modification step a further oxide layer (12) is produced on the at least one subregion of the surface of the metal plate (1).
18. A method according to claim 17, characterized in that the further oxide layer (12) is produced in such a way that the first region (6) has a first oxide layer (7) with a first thickness, and the second region (8) has a second oxide layer (10) with a second thickness, and that the first thickness is greater than the second thickness.

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