WO2024094521A1 - Security optical device - Google Patents

Abstract

The present invention relates to a security optical component (100) that is transferable to a blank of a document to be secured, comprising: - a support film (110) intended to be removed after transfer; - a detachment layer (120) for removing the support film (110) after transfer; - a set of security layers (140) providing a recognizable optical effect; - a protective varnish layer (130), arranged on a first face of the security layers (140); - a first transparent glue layer (150), arranged on a second face of the security layers (140), for fixing the security layers (140) when transferring the security optical component (100) onto the blank. It is essentially characterized in that it further comprises: - a second transparent glue layer (160) intended to fix the set of security layers (140) onto the blank.

Description

Optical security device.

The present invention relates to the field of security films.

Security films are typically implemented on government identity documents.

Increasingly, identity documents include at least one layer of polycarbonate, for example identity cards in smart card format, known as “ID1”, personal data pages in passports, driving licenses, etc. ...

On identity documents, a polycarbonate layer is personalized by laser marking.

Although personalization by carbonization inside one of the layers of an identity document is recognized as difficult to falsify, recent years have seen the accessibility of personalization lasers increase, leading to a need for protection of variable mentions still current.

Many authentication elements have recently been developed to secure plastic-based identity documents, in particular holographic films of the DOVID type (acronym for “Diffractive Optically Variable Image Device” in English).

These DOVIDs are incorporated by a heat transfer process onto a polycarbonate sheet, which is assembled with other polycarbonate sheets containing other functions of the identity document. All these sheets are then hot laminated under pressure to obtain the final identity document.

In the present case, the optically variable element (DOVID) used to secure the identity document is not made of polycarbonate. Therefore, during the fusion of the polycarbonate layers which sandwich the optically variable element, the latter does not fuse with said polycarbonate layers. There is therefore a risk of extraction of the DOVID at this location of the identity document. It must therefore be constituted in such a way that any attempt at extraction leads to at least partial destruction of the DOVID.

To incorporate them into an identity document, DOVIDs include an adhesive layer whose resins are chosen to obtain optimal adhesion. However, for various reasons, there is still a fragility in the adhesion of DOVID, which can subsequently result in delamination of the layers between them for fraudulent purposes, for the manufacture of a false identity document. An object of the invention is to provide an optical security component that can be heat transferred onto a polycarbonate sheet and hot laminated under pressure, which aims to limit or even avoid its reuse by delamination in the manufacture of a false identity document. .

To this end, according to a first of its objects, the present invention relates to an optical security device (1000) transferable to a polycarbonate substrate (200) of a document to be secured, the device comprising:

- a set of security layers (140) giving a recognizable optical effect to the optical security component (100);

- a layer of protective varnish (130), placed on a first face of the set of security layers (140), in contact with the detachment layer (120);

- a first layer of transparent glue (150), placed on a second face of the set of security layers (140), opposite the first, intended to fix the set of security layers (140) during the transfer of the security optical component (100) on the polycarbonate substrate (200); And

- a support film (110) intended to be eliminated after transfer;

- a release layer (120), in contact with the support film (110) and allowing the support film (110) to be removed after transfer;

It is essentially characterized in that the optical security component (100) further comprises:

- a second layer of transparent glue (160), in contact with the first layer of transparent glue (150), and intended to fix the set of security layers (140) during the transfer of the optical security component (100) to the polycarbonate substrate (200),

- at least one of the first glue layer (150) and the second glue layer (160) being discontinuous in at least one direction of elongation and representing a set of at least one predetermined pattern.

It can be provided that the first glue layer (150) presents a first bonding force on the polycarbonate substrate (200), and the second glue layer (160) presents a second bonding force on the polycarbonate substrate (200). , different from the first bonding force. It can be expected that the first layer of glue (150) is in the form of at least one of:

- a uniform layer continuous in at least one direction of elongation,

- a uniform discontinuous layer in at least one direction of elongation,

- a set of at least one first predetermined pattern.

It can be expected that the second layer of glue (160) is in the form of at least one of:

- a uniform layer continuous in at least one direction of elongation,

- a uniform discontinuous layer in at least one direction of elongation,

- a set of at least one second predetermined pattern.

It can be provided that the second glue layer (160) is printed on the first glue layer (150), so that the first glue layer (150) and the second glue layer (160) are at least locally superimposed.

It can be provided that the second layer of glue (160) is coplanar with the first layer of glue (150), the first layer of glue (150) comprising at least one recess whose shape is complementary to that of the pattern of the second layer glue (160), the pattern of the second glue layer (160) being printed in said recess, so that the first glue layer (150) and the second glue layer (160) are at least locally adjacent.

We can predict that:

- either only the first layer of glue (150) comprises luminescent pigments which emit in a first spectral band when they are excited in a first spectral band; Or

- either only the second glue layer (160) comprises luminescent pigments which emit in a second spectral band when they are excited in a second spectral band; Or - either the first glue layer (150) and the second glue layer (160) comprise different luminescent pigments which emit in a respective color in the same spectral band when they are excited in the same spectral band; Or

- either the first glue layer (150) comprises luminescent pigments which emit in a first spectral band when excited by a first spectral band, and the second glue layer (160) comprises luminescent pigments which emit in a second spectral band when they are excited by a second spectral band, different from the first spectral band.

It can be expected that at least one of the first pattern and the second pattern is invisible to the naked eye under natural light, but becomes visible to the naked eye when the luminescent pigments emit.

We can predict that:

The surface ratio between the first pattern and the second pattern is between two predetermined values.

According to another of its objects, the invention relates to a secure document comprising:

- a substrate;

- at least one optical component resulting from the transfer, onto one face of the polycarbonate substrate, of an optical security device (100) according to the invention.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description given by way of illustrative and non-limiting example and made with reference to the appended figures.

Figures are not to scale. Some details have been omitted and others amplified, to facilitate understanding.

DESCRIPTION OF THE DRAWINGS

[Fig. 1] illustrates an optical security component according to the prior art before transfer,

[Fig. 2] illustrates an optical security component according to the prior art after transfer, [Fig. 3] illustrates an optical security component according to the invention before transfer,

[Fig. 4] illustrates the optical security component of Figure 3 after transfer, hot deposition and lamination,

[Fig. 5] illustrates a partial view of an optical security component according to the invention in exploded, three-quarter view, and in partial transparency,

[Fig. 6] illustrates an embodiment of a first pattern and a second pattern according to the invention, in top view,

[Fig. 7] illustrates another embodiment of a first pattern and a second pattern according to the invention, in top view,

[Fig. 8] illustrates another embodiment of a first pattern and a second pattern according to the invention, in top view,

[Fig. 9] illustrates the embodiment of the first pattern and the second pattern of Figure 8, in cross section,

[Fig. 10] illustrates another embodiment of the first pattern and the second pattern of Figure 8, in cross section,

[Fig. 11] is a photograph of an embodiment of an optical security component according to the invention after a “cross test”;

[Fig. 12] illustrates an optical security component according to the invention before transfer,

[Fig. 13] illustrates the optical security component of Figure 12 after transfer, hot deposition and lamination, and

[Fig. 14] illustrates the selective destruction on the optical component of Figure 4.

An optical security device 1000 according to the prior art is illustrated in Figure 1 and Figure 2. The optical component 100 is intended to be transferred to a substrate of a document to be secured.

Typically the document to be secured is an official, state identity document, for example a national identity card, a passport, a driving license, etc.

The document to be secured comprises a polycarbonate page 200 or is made up of a polycarbonate page 200. In known manner, the polycarbonate page 200 comprises a plurality of polycarbonate sheets 200 laminated together. For a document to be secured such as a passport, the polycarbonate page 200 is the data page, called "datapage", which includes a certain number of variable data relating to the bearer of the passport.

These data are individual and make it possible to identify the passport holder. It is therefore necessary to secure at least this data page, to prevent counterfeiters from reusing it to create false documents.

To this end, the optical security component 100 is associated with a support film 110. In the process of manufacturing the secure document, the support film 110 is made of plastic polymer (PET, PP, PS, etc.). It facilitates the transfer of the optical security component 100 but it is intended to be eliminated after transfer.

For this, the support film 110 is in contact with a release layer 120, which allows the support film 110 to be removed after transfer.

The security of the optical security component 100 is ensured in particular by a set of security layers 140, which give it a recognizable optical effect. For example, the set of security layers 140 form an OVD type component for “Optical Variable Device” and particularly the DOVID type components for “Diffractive Optical Variable Image Device”, adapted to generate diffractive effects, in reflection or transmission , commonly called “holograms”.

The set of security layers 140 comprises a first face and a second face, opposite the first face, and notably comprises:

- an adhesion layer 141, also called adhesion primer, or adhesion primer,

- a layer of stamping varnish 142, and

- one or more reflective layers, for example a metal layer 143.

By “metal layer” 143 is meant a reflective layer which can be opaque metallic (in particular based on at least one of the metals or alloys among: Aluminum, Copper, Chrome) or transparent (in particular based on ZnS or of TiO2).

In known manner, the optical security component 100 also comprises a layer of protective varnish 130, which is placed on the first face of the set of security layers 140, and which is in contact with the detachment layer 120. To secure the optical security component 100 and the polycarbonate support 200 of the document to be secured, it is known that the optical security component 100 also comprises a first layer of glue 150, continuous at least over the entire surface of the optical security component 100, transparent, arranged on the second face of the set of security layers 140, at least over the entire surface of the optical security component 100.

A transfer step makes it possible to glue the optical security component 100, provided with the support film 110 and the detachment layer 120, thanks to the first layer of continuous glue layer 150 which comes into contact with a layer of polycarbonate and which is activated in a hot stamping step which ends with the peeling of the support film 110 thanks to the detachment layer 120. During the transfer, the first layer of glue 150 secures the optical security component 100 to the polycarbonate support 200.

After transfer, a lamination step is provided in which: at least a second layer of polycarbonate 210 is positioned on the assembly constituted by the layer 200 and the optical component 100 transferred,

A pressing operation under temperature is then carried out, which makes it possible to fuse the two layers of polycarbonate 200, 210 together.

It is thus possible to sandwich the optical security component 100 between the polycarbonate support 200 and the second polycarbonate layer 210 which is in contact with the protective varnish layer 130.

An optical security component 100 according to the invention is intended to be transferred to a polycarbonate support 200. As explained previously, it is desirable to limit the risks of fraudulent delamination of the layers between them.

For this purpose, it is possible to modify the chemical composition of the glue used for the first layer of glue 150, which is intended to fix the set of security layers 140 during the transfer of the optical security component 100 to the polycarbonate 200 substrate.

However, the present invention proposes a different approach which makes it possible to detect any delamination of the layers between them, in this case by selective and controlled destruction of the hologram in the event of delamination of the latter from its polycarbonate support 200.

With this objective in mind, a second layer of transparent glue 160 is provided, in contact with the first layer of glue 150, and intended to fix the set of security layers 140 during the transfer of the optical security component 100 to the substrate. , as illustrated in Figure 3 and Figure 4. In Figure 3, the first layer of glue 150 is in contact with the metallization layer 143 before transfer and the second layer of glue 160 is printed on the first layer of glue 150.

It can also be provided, as illustrated in Figure 12 and Figure 13, that the second layer of glue 160 is printed on the metallization layer 143 before transfer, and that the first layer of glue 150 is coated on the second layer of glue 160, that is to say that the printed surface of the first layer of glue 150 is greater than that of the second layer of glue 160.

The chemical composition of the second layer of glue 160 may be the same as that of the first layer of glue 150, provided that the luminescent pigments mentioned subsequently are different. In this case, there is no selective and controlled destruction but optical control by luminescence color.

Preferably, however, the chemical composition of the second layer of glue 160 is different from that of the first layer of glue 150, as explained below.

Preferably, the first glue layer 150 has a first bonding force on the polycarbonate substrate 200, and the second glue layer 160 has a second bonding force on the polycarbonate substrate 200, different from the first bonding force.

The bonding force is described for example at https://www.3mfrance.fr/3M/fr_FR/solutions- adhesives-assemblage/formation-apprenticeship/les-forces-de-collage/

In this case, the first bonding force on the polycarbonate substrate 200 is greater than the second bonding force on the polycarbonate substrate 200.

It can be expected that when the second layer of glue 160 is deposited on the first layer of glue 150, therefore superimposed on it, the bonding force of the first layer of glue 150 on the second layer of glue 160 is greater than one predetermined threshold value; and for example greater than at least one of: the first bonding force of the first glue layer 150 on the polycarbonate substrate 200, and the second bonding force of the second glue layer 160 on the polycarbonate substrate 200 In this case, in the event of an attempt to tear off the optical security component 100, then the two superimposed layers of glue 150, 160 are torn off at the same time as it. In the case where the bonding force of the first layer of glue 150 on the second layer of glue 160 is greater than the bonding force of the second layer of glue 160 on the polycarbonate substrate 200, there is controlled destruction because the areas where the first layer of glue 150 and the second layer of glue 160 are superimposed there will be tearing because the adhesion between these two glues is greater than the adhesion of the second layer of glue 160 on the polycarbonate 200.

It can also be provided that the bonding force of the first layer of glue 150 on the second layer of glue 160 is less than a predetermined threshold value; and in this case less than at least one of: the first bonding force of the first layer of glue 150 on the polycarbonate substrate 200, and the second bonding force of the second layer of glue 160 on the substrate in polycarbonate 200. In this case, in the event of an attempt to tear off the optical security component 100, then the first layer of glue 150 is torn off at the same time as it, and the second layer of glue 160 remains stuck to the substrate in polycarbonate 200. In this case, there is no controlled destruction because the rupture will take place between the first layer of glue 150 and the second layer of glue 160 and not between a layer of glue and the polycarbonate substrate 200 .

The principle of selective and controlled destruction is illustrated in Figure 14. An attempt to tear off the optical component generates tearing forces which oppose the bonding forces and the adhesion forces of the layers of the optical component. This results in zones of fragility A, where the bonding forces and the adhesion forces are the weakest.

These fragile zones A are represented by dotted lines in Figure 14. In Figure 14, the second layer of glue 160 is represented in the form of dots.

The fragile zones A, in this case Al, A2 and A3, depend on the position of the glue pads of the second glue layer 160 and the adhesion forces.

At the level of a glue pad of the second layer of glue 160, the fragility can be located: either on the zone of fragility Al, at the interface between the second layer of glue 160 and the first layer of glue 150; either on the fragile zone A2, at the interface between the second layer of glue 160 and the polycarbonate substrate 200. Between two glue pads adjacent to the second layer of glue 160, generally to the right of them, the fragility is located on zone A3, at the interface between the hologram 14 and the second layer of polycarbonate 210. By hologram 14, we mean all of the following layers, integral with each other: the protective varnish layer 130, all of the security layers 140 which includes the adhesion layer 141, the stamping varnish layer 142 and the metallization layer 143.

For this purpose, we preferably provide at least one of the following inequalities:

- the bonding force between the second layer of glue 160 and the polycarbonate support 200 is lower than the adhesion force between the hologram 14 and the second layer of polycarbonate 210, itself lower than the bonding force between the first layer of glue 150 and the polycarbonate support 200, itself lower than the bonding force between the hologram 14 and the first layer of glue 150;

- the adhesion force between the hologram 14 and the second layer of polycarbonate 210 is greater than the bonding force between the first layer of glue 150 and the second layer of glue 160;

- the adhesion force between the hologram 14 and the second layer of polycarbonate 210 is greater than the bonding force between the second layer of glue 160 and the polycarbonate support 200.

It can be expected that there is not necessarily a comparison relationship between: on the one hand the bonding force between the second layer of glue 160 and the polycarbonate support 200; and on the other hand on the other hand the bonding force between the first layer of glue 150 and the second layer of glue 160.

It can be expected that the bonding force between the first layer of glue 150 and the polycarbonate support 200 is greater than or equal to the bonding force between the first layer of glue 150 and the hologram 14. Preferably, these two bonding forces bonding are greater than the adhesion force between the hologram 14 and the second layer of polycarbonate 210.

For example, the glue of the first layer of glue 150 can be considered “strong” glue and is an glue based on polyester and/or acrylic copolymer and/or styrene-acrylic copolymer and/or an epoxy resin and/or a polyurethane. and/or ethylene vinyl acetate copolymer (EVA). A crosslinking agent can also be added. The families of crosslinking agents are following, taken alone or in combination, a carbodiimide, a melamine resin, an aziridine, an isocyanate.

The glue of the second layer of glue 160 can be considered “weak” glue. It is, for example, an adhesive based on an acrylic copolymer and/or a styrene-acrylic copolymer and/or a polyester and/or an epoxy resin and/or a polyurethane and/or ethylene vinyl acetate copolymer (EVA). .

The first layer of glue 150 can be in the form of a uniform layer, continuous in at least one direction of elongation, and typically covers the entire surface of the hologram.

Alternatively, it can be provided that the first layer of glue 150 is in the form of a discontinuous layer, comprising a set of at least one first predetermined pattern.

Similarly, the second layer of glue 160 can be in the form of a continuous uniform layer in at least one direction of elongation, or, preferably, in discontinuous form, and in this case in the form of a set of at least one second predetermined pattern. Preferably, the second pattern is smaller than the first pattern, and included in the first pattern when it is observed perpendicular to the plane of the optical security component 100.

For example, as illustrated in Figure 5, the second pattern matches the shape of the first pattern.

Preferably, the first layer of glue 150 and the second layer of glue 160 are not both uniform and continuous in two directions of elongation.

In this case, at least one of the first glue layer 150 and the second glue layer 160 is discontinuous in at least one direction of elongation and represents a set of at least one predetermined pattern, so as to allow to selective destruction.

It can be expected that each first pattern includes a plurality of second patterns.

In Figure 6 and Figure 7, the first pattern represents a possibly distorted oval shape, and the second pattern represents the “Fail” characters in Figure 6 and polygons in Figure 7.

The shape of the first pattern can be any.

Typically, it can be provided that the surface ratio between the first pattern and the second pattern is between two predetermined values, so that the first pattern and the second pattern are both observable, advantageously with the naked eye. As the second layer of glue 160 has a bonding force lower than the bonding force of the first layer of glue 150, it is advantageously provided that the surface ratio between the first pattern and the second pattern is at most '/z.

In a first variant, the second layer of glue 160 is printed on the first layer of glue 150.

In a second variant, the second layer of glue 160 is coplanar with the first layer of glue 150. In this case, the first layer of glue 150 comprises at least one recess whose shape is complementary to that of the pattern of the second layer of glue. glue 160, the pattern of the second layer of glue 160 being printed in said recess, for example as illustrated in Figure 9. In this case, the second layer of glue 160 is interposed with the first layer of glue 150.

Luminescent pigments

It can be provided that at least one of the first glue layer 150 and the second glue layer 160 comprises luminescent pigments, that is to say phosphorescent or, in this case, fluorescent.

Luminescent pigments are pigments which emit in a determined emission spectral band when they are previously excited by photons in a first excitation spectral band, in particular UV. The emission spectral band is generally different from the excitation spectral band.

We can thus use: either the absorption spectral band, that is to say the excitation spectral band of the luminescent pigments, or the emission spectral band of the luminescent pigments, as described in the variants below .

In a first variant, only the first layer of glue 150 comprises luminescent pigments.

In a second variant, only the second layer of glue 160 comprises luminescent pigments.

In a third variant, the first layer of glue 150 and the second layer of glue 160 each comprise luminescent pigments. The luminescent pigments of the first layer of glue 150 and the luminescent pigments the second layer of glue 160 all emit in the same predetermined emission spectral band, but the luminescent pigments of the first layer of glue 150 emit in a first color, and the luminescent pigments of the second layer of glue 160 emit in a second color different from the first color. That is to say that the luminescent pigments of the first glue layer 150 emit in a first emission spectral band, and the luminescent pigments of the second glue layer 160 emit in a second emission spectral band, such that the first emission spectral band and the second emission spectral band are at least partially identical.

For example (non-limiting), the first layer of glue 150 comprises luminescent pigments which emit blue light when they are previously excited by UV light, and the second layer of glue 160 comprises luminescent pigments which emit yellow light when they are previously excited by the same UV light.

When the first layer of glue 150 and the second layer of glue 160 are superimposed, as illustrated for example in Figure 8 or Figure 10, it is thus possible to implement an additive synthesis whose result is, in this case, colored green.

When the first layer of glue 150 and the second layer of glue 160 are juxtaposed, the first pattern appears blue in color and the second pattern appears yellow.

In a fourth variant, the first glue layer 150 and the second glue layer 160 also each comprise luminescent pigments, but which are excited in a respective spectral band. For this purpose, the first glue layer 150 comprises luminescent pigments which emit in a first emission spectral band when they are previously excited by photons of a first excitation spectral band, and the second glue layer 160 comprises luminescent pigments which emit in a second emission spectral band, possibly the same as the first emission spectral band, but when they are previously excited by photons of a second excitation spectral band, different from the first excitation spectral band.

For example, the luminescent pigments of the first glue layer 150 emit when they have been excited by UV-A photons, and the luminescent pigments of the second glue layer 160 emit when they have been excited by UV photons. -B or UV-C. Whatever the above variant, it is thus possible to check the optical security component 100, possibly on its polycarbonate support 200, by subjecting it to UV light. Advantageously, this type of control is non-destructive.

Preferably, at least one of the first pattern and the second pattern is invisible to the naked eye under natural light, thanks to transparent glues, but becomes visible to the naked eye when the luminescent pigments emit.

Whatever the above variant, preferably at least one of the patterns among the first pattern and the second pattern does not have symmetry, which adds an additional level of security by making any attempt at fraudulent copying even more difficult. .

However, as illustrated in Figure 7, Figure 8 or Figure 11, it can be provided that at least one of the patterns among the first pattern and the second pattern is repeated, the patterns being arranged in a network. Note that the network arrangement also makes it possible to secure the document, for example by controlling the distance between each pattern in the network.

Nomenclature

Al, A2, A3 selective destruction zone

14 hologram including the protective varnish layer 130 and the security layers 140

100 optical security component

110 support layer / support film

120 peel layer

130 coat of protective varnish

140 security layers including bonding layers 141, stamping varnish 142 and metallization 143

141 bonding layer

142 layer of stamping varnish

143 metallization layer

150 first layer of glue, having a first bonding force

160 second layer of glue, having a second bonding force

200 polycarbonate backing/polycarbonate layer

210 layer polycarbonate

1000 optical security device

Claims

Claims

1. Optical security device (1000), for transferring an optical security component (100) to a polycarbonate substrate (200) of a document to be secured, the device comprising:

The optical security component (100), comprising:

- a set of security layers (140) giving a recognizable optical effect to the optical security component (100);

- a layer of protective varnish (130), placed on a first face of the set of security layers (140), in contact with the detachment layer (120);

- a first layer of transparent glue (150), placed on a second face of the set of security layers (140), opposite the first, intended to fix the set of security layers (140) during the transfer of the security optical component (100) on the polycarbonate substrate (200); And

- a support film (110) intended to be eliminated after transfer;

- a release layer (120), in contact with the support film (110) and the protective varnish layer (130), and allowing the support film (110) to be removed after transfer; characterized in that the optical security component (100) further comprises:

- a second layer of transparent glue (160), in contact with the first layer of transparent glue (150), and intended to fix the set of security layers (140) during the transfer of the optical security component (100) to the polycarbonate substrate (200),

- at least one of the first glue layer (150) and the second glue layer (160) being discontinuous in at least one direction of elongation and representing a set of at least one predetermined pattern.

2. Optical security device (1000) according to claim 1, wherein the first layer of glue (150) has a first bonding force on the polycarbonate substrate (200), and the second layer of glue (160) has a second bonding force on the polycarbonate substrate (200), different from the first bonding force.

3. Optical security device (1000) according to any one of the preceding claims, in which the first layer of glue (150) is in the form of at least one of:

- a uniform layer continuous in at least one direction of elongation,

- a uniform discontinuous layer in at least one direction of elongation,

- a set of at least one first predetermined pattern.

4. Optical security device (1000) according to any one of the preceding claims, in which the second layer of glue (160) is in the form of at least one of:

- a uniform layer continuous in at least one direction of elongation,

- a uniform discontinuous layer in at least one direction of elongation,

- a set of at least one second predetermined pattern.

5. Optical security device (1000) according to any one of the preceding claims, in which the second layer of glue (160) is printed on the first layer of glue (150), so that the first layer of glue (150) ) and the second layer of glue (160) are at least locally superimposed.

6. Optical security device (1000) according to any one of claims 1 to 4, in which the second layer of glue (160) is coplanar with the first layer of glue (150), the first layer of glue (150) comprising at least one recess whose shape is complementary to that of the pattern of the second layer of glue (160), the pattern of the second layer of glue (160) being printed in said recess, so that the first layer of glue ( 150) and the second glue layer (160) are at least locally adjacent.

7. Optical security device (1000) according to any one of the preceding claims, in which: - either only the first layer of glue (150) comprises luminescent pigments which emit in a first spectral band when they are excited in a first spectral band;

- either only the second glue layer (160) comprises luminescent pigments which emit in a second spectral band when they are excited in a second spectral band;

- either the first glue layer (150) and the second glue layer (160) comprise different luminescent pigments, which emit in a respective color when they are excited in the same spectral band;

- either the first glue layer (150) comprises luminescent pigments which emit in a first spectral band when excited by a first spectral band, and the second glue layer (160) comprises luminescent pigments which emit in a second spectral band when they are excited by a second spectral band, different from the first spectral band.

8. Optical security device (1000) according to claim 7, wherein at least one of the first pattern and the second pattern is invisible to the naked eye under natural light, but becomes visible to the naked eye when the luminescent pigments emit.

9. Optical security device (1000) according to any one of the preceding claims, in which:

The surface ratio between the first pattern and the second pattern is between two predetermined values.

10. Secure document including:

- a polycarbonate substrate (200);

- at least one optical component resulting from the transfer, onto one face of the polycarbonate substrate (200), of an optical security device (1000) according to any one of the preceding claims.