Security element with metallization

The present invention relates to a security element (20) for security papers, value documents and the like, having a substrate (22) and an opaque metallization 24, 26) arranged on the substrate. According to the invention in the security element is provided, that the metallization (24, 26) comprises a first opaque metal layer (24) and a second opaque metal layer (26) arranged above the first metal layer (24), and that the two metal layers (24, 26) have substantially the same tone of color in the visible spectral region.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is the U. S. National Stage of International Application No. PCT/EP2007/009687, filed Nov. 8, 2007, which claims the benefit of German Patent Application DE 10 2006 055 680.1, filed Nov. 23, 2006; both of which are hereby incorporated by reference to the extent not inconsistent with the disclosure herewith.

The invention relates to a security element for security papers, value documents and the like having a substrate and an opaque metallization arranged on the substrate. The invention further relates to an associated production method, a security paper as well as a data carrier having such a security element.

Value objects, such as branded articles or value documents, are often provided with security elements for protection, which allow a verification of the genuineness of the value object and which serve at the same time as protection from unauthorized reproduction.

A number of these security elements, such as hologram bands or so-called hologram-patches comprise thin opaque metal coatings which typically have a thickness between 10 nm and about 100 nm. Due to the good availability, the excellent reflection properties, the relatively good chemical durability and the low cost predominantly aluminum is employed for the metal coatings of bank note holograms, security threads and the like.

Bank notes are possibly exposed to strong mechanical and partially also chemical stress during their circulation. Thereby it has been observed, that the thin aluminum coatings of the security elements may corrode and thereby may be strongly damaged, whereby the optical impression of the banknote is strongly altered. Chemically very durable metals, such as gold, palladium or platinum, are generally considerably too expensive for a use in security elements. Other chemically more durable metals than aluminum are indeed more inexpensive, but optically less brilliant ant therefore visually less appealing.

From this starting point the invention is based on the object to avoid the disadvantages of the state of the art. In particular, a security element of the type stated in beginning, having improved circulation durability and/or increased counterfeiting security shall be specified.

This object is solved by the security element having the features of the main independent claim. A corresponding production method as well as a security paper and a data carrier, which are provided with such a security element are specified in the other independent claims. Developments of the invention are subject of the subclaims.

According to the invention in a security element of the generic kind it is provided that the metallization comprises a first opaque metal layer and a second opaque metal layer arranged above the first metal layer, and that the two metal layers have substantially the same tone of color in the visible spectral region. Thereby, complete identity in tone of color is not required. As explained in the following in more detail it is sufficient for the purpose of the invention if the tones of color of the two metal layers are as similar to each other, that they appear the same at swift observation.

In an advantageous development of the invention, the two metal layers differ significantly in their chemical and/or mechanical durability. An increased circulation durability is in particular achieved if the second metal layer is chemically and/or mechanically more durable than the first metal layer.

Despite their substantially equal tone of color, the metal layers can differ in their reflectivity, wherein the arrangement of the metal layers is advantageously chosen for a good visual impression such, that the first metal layer reflects stronger than the second metal layer.

The layer thickness of thin layers is typically given in units of the optical density, which is a measure for the attenuation experienced by the light when passing through the thin layer. As optical density OD the decade logarithm of the quotient of 100 and the transmission (in percent), thus OD=log (100/T) is denoted. For example, an optical density of 1.0 corresponds to an attenuation of the light to one tenth of the original irradiance, an optical density of 2.0 to an attenuation to one hundredths.

For the purpose of the invention “opaque” is to be understood as an optical density of at least 0.5, preferably of at least 0.7, especially preferably of at least 1.0.

According to an advantageous embodiment of the invention, the layer thicknesses of the two metal layers are chosen such, that their optical density is substantially the same. For example, the optical densities of the two metal layers may differ by less than 0.3, in particular by less than 0.2.

While good reflection properties and good corrosion durability may be obtained already starting at an optical density of about 0.5, the optical density of the two metal layers is preferably larger than 1.0, in particular larger than 1.2, respectively. Thereby it is expedient, if the two metal layers are adapted to each other such, that the optical density of the opaque metallization, therefore of the two metal layers together, is between 1.5 and 5.0, preferably between 1.5 and 3.0.

For the second metal layer a layer of a corrosion-resistant metal, in particular a platinum layer, a palladium layer or a chrome layer advantageously comes into consideration in line with the invention. Currently, the use of a chrome layer is particularly preferred, as this material combines low cost, high durability and still relatively good reflection properties. The second metal layer is therefore preferably a chrome layer, in particular having a thickness of about 25 nm or more.

Due to its excellent reflection properties, the use of aluminum layers, in particular having a thickness of 15 nm or more, is preferred for the first metal layer.

The combination of a chrome layer as second metal layer with an aluminum layer as first metal layer is particularly advantageous, as chrome and aluminum both have a substantially flat reflection spectrum in the visible spectral region and therefore both effect a white color impression. In this way, the advantages of the high reflectivity of aluminum and the high durability of chrome may be combined with each other. In case of a substantially undamaged aluminum layer, the visual impression of the metallization of the security element is determined by the highly glossy aluminum layer.

In case the aluminum layer obtains defects or cracks by great wear and tear the chrome layer with its substantially equal tone of color takes over the light reflection. The smaller reflectivity of the chrome layer is thereby, especially in greatly used banknotes, practically non-apparent for the bare eye. The characteristic appearance of the metallization of the security element therefore remains intact also in case of great wear and tear.

According to a development of the invention a spacing layer is provided between the two metal layers, which in particular forms an electrical and/or chemical isolation layer. The spacing layer is advantageously formed by a transparent printing layer or a transparent vapor deposited layer. In an expedient embodiment the spacing layer is formed by a ceramic layer, in particular a SiOX-layer, an Al2O3-layer, a MgF2-layer, or also by an organic layer. Alternatively or additionally the spacing layer may form a barrier layer against the permeation of gases and vapors, in particular of oxygen and hydrogen.

In particularly preferred embodiments of the invention the security element comprises a diffraction structure in form of a relief structure. The diffraction structure thereby advantageously encompasses an embossing lacquer layer and at least a partial area of the metal layers. In case certain partial areas of the diffraction structure are to be optically accentuated, advantageously the first metal layer may be present only in these partial areas. The security element then comprises first areas, in which the first metal layer is visible, and second areas, in which the second metal layer is visible. Although the optical impression in both areas is naturally very similar due to the substantially equal tone of color, nuances in the appearance of the partial areas may be perceived in case of different reflection properties of the metal layers.

Besides diffraction structures the security element may also comprise scattering structures (matte patterns), anti-reflection topographies, refractive structures, zero order gratings, blazed gratings, optically variable topographies by means of micromirrors and/or retro-reflective structures.

In further advantageous embodiments the two metal layers comprise gaps in the form of patterns, characters or a code, which reach through both metal layers. In the area of the gaps the security element may then be transparent or translucent, or an information arranged below the metallization may emerge.

The security element preferably represents a security thread, a security band or a patch.

The invention also comprises a method of producing a security element for security papers, value documents and the like, in which a substrate is provided, a first opaque metal layer is arranged on substrate, and a second opaque metal layer is arranged above the first metal layer, which second metal layer has substantially the same tone of color in the visible spectral region as the first metal layer.

The two metal layers are thereby preferably applied by means of a vacuum coating process. In a particularly advantageous method an aluminum layer is applied as first metal layer and a chrome layer as second metal layer.

Between the first and the second metal layer a spacing layer may be applied, which is expediently printed or vapor deposited in a vacuum coating process.

In a development of the method according to the invention the security element is provided with a diffraction structure in form of a relief structure. Thereby, an embossing lacquer is applied onto the substrate, the embossing lacquer is embossed into the form of a desired diffraction structure and the first and second metal layer are applied one after the other, when indicated by interposition of a spacing layer, onto the embossed lacquer layer.

Gaps reaching through both metal layers and being in the form of patterns, characters or a code, may by introduced into the metal layers, in particular using the washing process known from the document WO 99/13157 A1.

The invention further comprises a security paper for the manufacture of value documents or the like as well as a data carrier, in particular a value document, such as a bank note, an identity card or the like. The security paper and the data carrier, respectively, are equipped with a security element of the described type according to the invention.

The invention is now illustrated using security elements for bank notes as example. To that regardFIG. 1shows a schematic representation of a bank note10, which is provided with two metallized security elements of high circulation durability according to the invention. The first security element represents a security thread or a security band12, the second security element is formed by a bonded transfer element14of arbitrary shape.

The layer composition of security elements according to the invention and the effect according to the invention are now described in more detail based on the sectional representations ofFIGS. 2 to 6, wherein only the layers essential for the invention are shown, respectively. Depending on the intended application, the finished security elements certainly will contain further layers known to the person skilled in the art, such as gluing layers, protection layers, primers or the like.

The security element20ofFIG. 2comprises a plastic foil22as substrate, on which two opaque metal layers24and26are vapor deposited on top of each other, which have substantially the same tone of color in the visible spectral region. In the exemplary embodiment the first metal layer24is formed by a thin aluminum layer, the second metal layer26by a thin chrome layer.

The layer thicknesses of the two metal layers are thereby chosen such, that the optical density of the aluminum layer and of the chrome layer is about 1.5, respectively.

The vapor deposited chrome layer26and the aluminum layer24both have an almost flat reflection spectrum in the visible spectrum region and therefore appear of having white color impression. The reflectivity of the chrome layer26, however, is at about 50% smaller than the reflectivity of the aluminum layer24, which is about 90%, so that the chrome layer with the same tone of color appears by itself somewhat darker than the aluminum layer.

The metallized substrate is preferably applied onto a security paper with the metallized side, so that the substrate foil22points to the viewer.

The chrome layer26is then, as seen by the viewer, covered completely by the opaque aluminum layer24, so that the overall visual impression of the security element is given only by the highly glossy aluminum layer24. Depending on the embodiment, the substrate22may remain on the already applied security element or may preferably be removed.

During the circulation of the banknotes provided with the security element20partial corrosion of the thin aluminum layer24may occur in case of particularly high wear and tear, for example in tropical countries or in case of high exposure to sweat. The aluminum layer, which is less durable with regard to highest levels of wear and tear may thereby obtain light transmitting cracks and defects.

In these light transmitting areas the chrome layer, which is chemically and mechanically significantly more durable, takes over the light reflection according to the invention. The reflectivity of the chrome layer26may be somewhat smaller than the same of the aluminum layer24, but the change of the reflecting metal area is hardly apparent for the viewer, especially in case of mechanically and/or chemically highly stressed bank notes. In particular, also in case of high wear and tear the basic optical impression of the security element, namely its metallic appearance and the color impression of the metallization is preserved.

Increased circulation durability can be preserved in a wide area of layer thicknesses for the two metal layers24,26. For the first metal layer, which points towards the viewer, layer thicknesses starting at an optical density of about 0.5 are possible, for a very good visual impression and high reflection, however, optical densities of 1.0 or more are typically chosen.

Also the second, highly durable metal layer leads starting at an optical density of 0.5 already leads to a significant increase in the circulation durability of the security element. In case of the utilization of chrome layers optical densities above 1.0 have proven of value for a good corrosion protection. In case very costly metals, such as platinum and palladium are used for the second metal layer, the second metal layer is formed due to cost reasons in the minimally necessary layer thickness, so that also optical densities significantly below 1.0 are possible.

The thicknesses of both metal layers are advantageously adapted to each other according to the invention such, that the optical density of the metal layers together is above 1.5, in particular in the region of 1.5 to 3.0. In the exemplary embodiment ofFIG. 2, the optical densities of the metal layers add up to ODges=ODAl+ODCr=1.5+1.5=3.0.

In the further exemplary embodiment ofFIG. 3, between the two metal layers24,26of the security element30an electrically and, if applicable, also chemically isolating transparent spacing layer32is arranged. The spacing layer32may in particular prevent a local element formation and thereby an accelerated corrosion due to pitting.

Transparent printing layers, transparent layers applied in a vacuum coating process, such as layers of SiOx, wherein x is between 1.5 and 2, Al2O3or MgF2, but also organic coatings are possible as suitable spacing layers. The layer thickness of the spacing layer32is of little significance and may be between 10nm and several micrometers.

Instead of or in addition to its electrical isolation, the spacing layer32may also be configured as a barrier layer against the permeation of gases and vapors, in particular of oxygen and hydrogen.

FIG. 4shows a security element40provided with a metallized hologram as a further exemplary embodiment of the invention. In this case an embossing lacquer layer44was printed onto a carrier foil42, and the desired diffraction structure of the hologram was embossed in form of a relief structure.

In order to obtain the described advantages of increased circulation durability, a first metal layer46of aluminum and a second metal layer48of chrome is applied as a hologram metallization. Between the two metal layers46,48a spacing layer50be provided. Due to the variable surface topography of the relief structure the spacing layer50has to be in the position to follow the surface topography of the first metal layer46. For this purpose in particular ceramic, transparent vapor deposition layers, such as SiOx, Al2O3or MgF2, having layer thicknesses of 10 nm or more, are suitable. Also thin organic coatings, which follow the surface topography, may be used.

In further embodiments, the security elements according to the invention may also contain negative information in the form of patterns, characters or codes, which are formed by corresponding gaps in the metallization. For illustrationFIG. 5shows a security element60, in which a substrate62is provided with a metallization64, which is formed by an aluminum layer66, a transparent ceramic spacing layer68and a chrome layer70.

The metallization64may also form a metal coating of a diffraction structure, such as a hologram. In this case the substrate62comprises in addition to a carrier foil in particular also an embossed lacquer layer, as shown for example inFIG. 4.

Reverting back toFIG. 5, gaps72in the form of the desired negative information, for example in the form of negative text, are introduced into the metallization64, wherein the gaps72reach through both metal layer66,70and the ceramic spacing layer68. The demetallized areas72may for example be generated by means of a washing process, as known from the document WO 99/13157 A1.

A further embodiment of the invention is illustrated inFIG. 6. The security element80shown there corresponds in its layer composition largely to the security element60ofFIG. 5, however with the difference, that the chrome layer70is applied as first metal layer and an aluminum layer66as second metal layer and that now gaps82are provided, which are only present in the aluminum layer66. This security element is viewed from the side having the aluminum layer66.

In this variant according to the invention the second metal layer70is applied onto the first metal layer only in partial areas. In this novel security element80nuanced visual appearances may be perceived in the areas with and without gaps82, respectively, due to the different reflectivities of the two metal layers66,70. Although the optical impression in the two areas is according to the interpretation very similar, minute differences of certain design elements, in particular holograms (FIG. 4) may be stressed and accentuated.

With increasing wear of the security element80the recognizability of the nuanced appearances formed by the shape and position of the gaps82decreases typically and may finally disappear completely in case of the highest level of wear. The increased circulation durability of the security element80, however, is secured by the highly resistant chrome layer70, even in case of the highest level of wear.