FR2698964A1 - Identification marking of wood and paper based supports - uses fluorescent or phosphorescent substances acted on by light emitted from optical fibre - Google Patents

Abstract

The support has deposited on it a luminous substance which can easily be seen by the human eye either directly of by means of a detector. The substance(s) are dissolved in the light conductors by specific illumination. The substances may be fluorescent or phosphorescent, and the light conductors may be polymer or mineral fibre optic type with a jump or gradient indices. The phosphorescent substances have a long life and the fluorescent substances have a short relaxation time. USE/ADVANTAGE Provides simple, reliable and effective method for marking surfaces.

Description

 Device for marking and identifying a sUDDOrt nar optiauf fibers.

 The invention relates more particularly to the marking of parts or support based on wood, paper or other.

 It appeared necessary to locate objects, in order to follow them during their life. In addition, the use of computer means requires the use of sensors that can be connected to computers directly delivering digital information. To keep track of parts during manufacture, or to identify rare parts, the systems included in these parts must be available. Such systems can not be removed or torn.

 Examples that may be mentioned include processes using fluorescent inks or sandblasting operations for marking, for example, car windows.

 In order to mark and identify a paper, it has also been proposed to use a fluorescent material in the form of a solid matrix consisting of a polymer doped with an organic compound itself fluorescent.

 This state of the art emerges, for example, from the teaching of patent FR 8601589. In this patent, to identify the paper, the latter is exposed to a radiation source whose wavelength corresponds to the band of excitation of the organic compound for doping. It is supposed that the paper re-emits the energy received in the form of a double light emission with different lifetimes. Means make it possible to check the remanence of one of the emissions and to observe its extinction law, characteristic of the doped polymer. The measurement or identification of this light emission allows the identification of the paper concerned.

 If the results obtained can be considered satisfactory, the recognition is relatively delicate. In fact, on the one hand, the use of polymers doped with fluorescent substances only imperfectly permits a good transport of the optical information and, on the other hand, the lifetime of the electronic excited states of the organic molecules. is usually very weak. This results in a signal of low amplitude and short duration after the excitation.

 The object of the invention is to remedy these disadvantages in a simple, safe, effective and rational manner.

 The problem to be solved by the invention is to control experimental photophysics by better knowledge of optical transducers.

 To solve such a problem, it has been designed and developed a marking device and identification of a support consisting of at least one phosphor deposited in the support to be easily observable by the human eye directly or by the intermediate of a sensor, by specific illumination, said substance or substances are dissolved in light conductors.

 The substance or substances are of the fluorescent or phosphorescent type.

 The support may also contain fluorescent and phosphorescent substances.

 Light conductors are made of polymer materials or mineral materials.

 Advantageously, the luminescence of the substance or substances is selected either in the red orange field of the visible spectrum, or in the blue field, or in a yellow green spectrum.

 To solve the problem of obtaining a security paper, with internal marking means using light conductors and fluorescent and / or phosphorescent products, is solved in that the fluorescent substance (s) have a short relaxation time, while the phosphorescent substance (s) have a long life.

The invention is described below in more detail with the aid of the accompanying drawings, in which:
Figure 1 is a large-scale schematic view showing the principle of the optical fiber tracking system in a wooden support.

 Figure 2 is a view similar to Figure I showing the use of a fluorescent fiber.

 Figure 3 is a view showing the principle of absorption.

 Figure 4 is a view showing the fluorescence emission.

 Fig. 5 is a view showing fluorescence absorption and emission spectrum of fluorescein at pH 12.

 Fig. 6 is a view showing an example of fiber optic mounting for tracking.

 Fig. 7 is a large scale and schematic view showing a paper support using the fluorescence and phosphorescence emission of an optical fiber from a pulsed excitation.

 Figures 7a and 7b show the temporal resolution curves involving fluorescence and phosphorescence.

 Figure 8 is a view similar to Figure 7 showing the use of a phosphorescent secondary source.

 FIGS. 8a, 8b and 8c show the curves corresponding to the excitation and to the emissions corresponding to the embodiment of FIG. 8.

 As indicated, the general principle of the invention is based on the application of luminescence. In this respect, it is necessary to recall what is meant by luminescence.

 When a substance absorbs visible light or ultraviolet rays, an electron of a binder orbital of said substance is promoted in an anti-binding orbital thereof of higher energy than the ground state. An electronically excited state is formed.

 However, given the speed of the absorption process, the resulting molecule can be considered fixed during the promotion of the electron. As a result, an excited molecule is created having the same geometry as the molecule in its ground state. Since this geometry is not the most stable in the excited state, a first relaxation occurs, making it possible to obtain an electronically excited molecule, but in thermal equilibrium with the medium.

 The excitation remains carried by the molecule a variable time, which depends, on the one hand, of the molecule itself and, on the other hand, of its environment. The disappearance of the electronic energy can be done with a determined relaxation time in different ways, namely, non-radiative relaxation, chemical process, emissive process.

 The invention relates more particularly to the application of the emissive process. In this respect, this emission is defined by a fluorescence or phosphorescence spectrum and by a quantum yield defined by the number of photons re-emitted in fluorescence relative to the number of photons absorbed.

 As shown in FIGS. 3 and 4, the emission results in a conservation of the geometry of the molecule, so that the excitation or absorption and fluorescence or phosphorescence spectra virtually do not overlap (FIG. ).

 The marking and identification device according to the invention aims at recognizing a material (wood, paper, etc.) by using at least one phosphor that emits in the visible spectrum. and properly distributed on the support considered. This or these substances are dissolved in light conductors, such as optical fibers. The light conductors are made of polymeric or inorganic materials, such as silica, glass, and more generally any substance that can be used both from the point of view of emitting dyes and transparent materials, which is perfectly known to those skilled in the art.

 The device according to the invention is based on the location of luminescent optical fibers, according to a known code of the barcode type or other distinctive mark. Under these conditions, the use of a reading system such as that shown in Figure 6, allows a recognition of the positions of the fibers at a given wavelength.

In the illustrated example, the reading system includes
- in (1), a reflective fiber
- in (2), a hole without fiber
in (3), a fluorescent fiber of wavelength Xi
- in (4), a fluorescent fiber of wavelength # 2># 1
in (5), a fluorescent fiber of wavelength k1
in (6), a fluorescent fiber of wavelength h1 - in (7), a fluorescent fiber of wavelength k3,>
In correspondence with this example of montage, the principle of the logical measurement by space-resolved spectral analysis is established as follows, considering the excitation at # 0># 1, # 2, # 3.

<Tb>

N <SEP> OF <SEP> FIBERS <SEP> (1) <SEP> (2) <SEP> (3) <SEP> (4) <SEP> (5) <SEP> (6) <SEP> (7) )
<tb><SEP> ANALYSIS <SEP>#<SEP><SEP> 1 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 0
<tb><SEP> ANALYSIS <SEP>#<SEP><SEP> 0 <SEP> 0 <SEP> 1 <SEP> 0 <SEP> 1 <SEP> 1 <SEP> 0
<tb><SEP> ANALYSIS <SEP>#<SEP><SEP> 0 <SEP> 0 <SEP> 0 <SEP> 1 <SEP> 0 <SEP> 0 <SEP> 0
<tb><SEP> ANALYSIS <SEP> 23 <SEP> o <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 0 <SEP> 1
<Tb>
In this table, logic state 1 corresponds to a positive signal, while logic state 0 corresponds to a lack of signal.

The operation of the device can be explained as follows:
A light excitation is carried out at wavelengths less than or close to the wavelength of maximum absorption of the emitting substances. Undoped fibers reflect light at this same wavelength.

 On the other hand, for each dye used, there is schematically the same emission in areas of wavelengths that can be disjoint. These emissions or reflections can be analyzed through optical fibers, by a photo detector capable of delivering the logic signal 0/1 allowing or not the identification.

 The marking device, according to the invention, advantageously implements one or more substances whose luminescence is selected in the orange-red field of the visible spectrum, corresponding to wavelengths of between 550 and 650 nm, or else in the blue field, corresponding to wavelengths between 400 and 500 nm or finally, a green-yellow spectrum corresponding to wavelengths of between 500 and 550 nm.

 As indicated, the device finds applications for the marking and identification of any type of support. FIG. 1 shows the application of the device to a wooden support (B) in which a hole (B1) has been applied for the placement of an optical fiber represented by the corresponding arrows (F1) and (F2) respectively to excitement and reflection. The bottom of the hole is treated to obtain a total reflection either by the size of the end, or by metallization to create a mirror effect.

 FIG. 2 shows the use of a fluorescent fiber in a wooden support (B), the arrow (F3) symbolizes an excitation Xo while the arrow (F4) symbolizes the emission of a wavelength Xi> B0.

 In the case of an application to a paper medium, the optical fiber is placed in said paper, with or without a sheath and contains a fluorescent product which can be excited by an external light source, through said paper. There is re-emission of this light by fluorescence, therefore, very short relaxation time, partly by the fiber.

 For fluorescent substances, rapid relaxation generally does not allow the easy use of a temporal resolution technique. On the other hand, if the substance is both fluorescent and phosphorescent, or if the fiber contains at least two substances of which at least one is fluorescent, it will be possible to perform quality recognition.

 Reference is made to FIGS. 7, 7a, 7b, which show the temporal resolutions including fluorescence and phosphorescence. In particular, FIG. 7 shows a paper support (P) including an optical fiber (FO). In this figure, the arrow (F) symbolizes the pulsed excitation, while the arrow (F5) symbolizes the emission of fluorescence and phosphorescence. FIGS. 7a and 7b are respectively curves of the intensity of emission as a function of the wavelength λ and the excitation of the emissions with respect to time.

 The diffusing paper support may advantageously contain a luminescent material whose deposit may or may not be surface-resolved in said paper support. At this phosphorescence emission, which can be seen by the eye under intermittent lighting, may be associated, a complementary emission of fluorescence or phosphorescence, short relaxation time from the same material or a substance included in the support material paper.

 In pulsed or periodic excitation, the excitation of the paper medium by a light source emitting light radiation of suitable wavelengths simultaneously allows the excitation of the phosphorescent substance and the excitation of the fluorescent substance dissolved in the optical fiber.

 If the phosphorescence emission is partially absorbed by the fluorescent substance, the emission from the optical fiber follows a relaxation of amplitude which is a function of the excitation source (direct fluorescence) and function of the phosphorescent source (fluorescence secondary indirect). Figures 8a, 8b, 8c, 8d qualitatively show the results as defined. More particularly, FIG. 8 shows the paper support (P) including an optical fiber (FO) containing a fluorescent product of emission h1 and of absorption X2.

At the level of the optical fiber, the paper has a surface deposition zone (Z) or deep inclusion zone of a fluorescence substance with a high emission relaxation time Xi. The arrows (F6) show fluorescence emission by a light conductor of the type
FO.

 FIGS. 8a, 8b and 8c respectively show the excitation by the source X 0 as a function of time, the phosphorescence emission of the support paper as a function of time and the secondary and direct fluorescence as a function of time.

 According to the invention, it therefore appears possible to work with fluorescent optical fibers of any type known in the trade and which are associated in the support, secondary sources fluorescent or phosphorescent surface resolved and allowing a better security or protection of documents.

 In addition, if the direct environment of an optical fiber contains a substance with a short relaxation time, the secondary emission from the optical fiber will also have a short relaxation time.

On the contrary, this relaxation time will be long for a phosphorescent secondary source with long relaxation time.

 Moreover, given the nature of the optical transducer and the possibility of using optical fibers well known in the state of the art, it is relatively easy to separate the fluorescence emissions from phosphorescence emissions.

It therefore appears that the marking and identification device according to the invention results from the application:
a source emitting light radiation absorbed at least by the material included in the support,
a fluorescent or phosphorescent substance dissolved in the optical fiber that absorbs at least the radiation emitted by the second fluorescent or phosphorescent area source.

 It is recalled that the optical fibers can be made using any type of mineral material known to a person skilled in the art, these materials being dopable with luminescent mineral substances containing metals, such as uranium or rare earths such as europium , the terbium ...

Such compositions for making the fibers are known to be polymers containing fluorescent or phosphorescent organic substances. Fluorescence emissions
can be delayed with eosin of organo-mineral substances
such as rare earth chelates. Optical fibers
can be index jump or index gradient.

Likewise, the substances contained in the support are of any known and appropriate type. They may be luminescent mineral substances such as metal sulphides, whether or not doped with them
organic or organo-mineral substances.

The advantages are apparent from the description.

Claims (12)

-1- Device for marking and identification of a support, characterized in that it consists of at least one phosphor deposited in the support to be easily observable by the human eye directly or via a sensor, by specific illumination, said substance or substances are dissolved in light conductors. -2- Device according to claim 1, characterized in that the substance or substances are of the fluorescent type. -3- Device according to claim 1, characterized in that the substance or substances are of the phosphorescent type. -4- Device according to claim 1, characterized in that it uses fluorescent and phosphorescent substances.  -5- Device according to claim 1, characterized in that the light conductors are of polymeric materials.  -6- Device according to claim 1, characterized in that the light conductors are made of mineral materials.  -7- Device according to claim 1, characterized in that the one or more luminescent substances are established on the support to constitute a code or a distinctive mark.  -8- Device according to claim 1, characterized in that the luminescence of the substance or substances is selected either in the red orange field of the visible spectrum, or in the blue field, or in a yellow green spectrum.  -9- Device according to claim 1, characterized in that the fluorescent substance (s) are at a short relaxation time.  -10- Device according to claim 1, characterized in that the or phosphorescent substances are of long life.  -11- Device according to claim 1, characterized in that the light conductor enters the composition of the support.  -12- Device according to claim 1, characterized in that the light conductor is a doped fiber index jump or index gradient.