JP2009270002A - Structure, laser processing method, and authenticity determination method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily subject a process object made of plastics showing transparency to laser marking by a simple technique without using a light absorbent. <P>SOLUTION: A structure 10 is disclosed, which at least partially includes a polymer compound showing transparency to laser light, wherein the structure is modified by irradiating at least a part of the polymer compound with light so as to increase absorption of laser light. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a structure that is an object of laser processing, a laser processing method that performs predetermined processing by irradiating laser light, and an authenticity determination method that uses this laser processing method. The present invention relates to a laser marking structure, a laser processing method, and an authenticity determination method.

Applying letters, symbols, marks, etc. to various industrial products is called marking. Examples of objects to be marked include product containers, housings, substrates, tags, and the like, and identification numbers, lot numbers, bar codes, manufacturing dates, and the like are given to these objects.
Marking methods include, for example, stamps, labels, engravings, laser markings, etc. Among them, laser markings are beautiful in appearance, have almost no deterioration, have a short processing time, and can save labor. Therefore, it is used in various fields.

Although laser marking is intended for many industrial products, it is difficult to apply it to polymer processed products (plastics) that are transparent to laser light.
This is because in such a workpiece, the absorption of laser light is small, and the interaction between light and a substance (for example, photothermal conversion) hardly occurs.

Therefore, a technique has been proposed that enables laser marking even on a workpiece made of a polymer workpiece that is transparent to laser light.
For example, a technique has been proposed in which a substance (light absorber) that absorbs a large amount of laser light is dispersed in a workpiece or applied to the surface of the workpiece (for example, see Patent Document 1).
According to this technique, since the absorption rate of the laser beam is increased by the dispersed or applied substance, laser marking is possible. In particular, in a molded article coated with a thermoplastic resin composition containing a predetermined amount of carbon black, laser marking having a clear contrast becomes possible.

Also, a hole formed in the interface portion of the transparent body that comes into contact with the solution by irradiating the transparent body with a solution having a high laser light absorption rate to the bottom surface and irradiating a laser beam condensed using a lens from the top surface. A technique has been proposed in which the transparent body is etched while changing the relative position of the lens and the transparent body so that the focus of the laser beam is aligned with the deepest part of the hole as the laser beam advances into the transparent body (for example, patents) Reference 2).
According to this technology, the laser beam that has passed without being absorbed by the transparent body is absorbed by the solution, so the laser energy is indirectly transmitted to the transparent body in contact with the solution to etch the surface of the transparent body. can do.
Japanese Patent Laid-Open No. 05-92657 JP 2007-175778 A

However, the technique described in Patent Document 1 or 2 described above has the following problems.
For example, the technique described in Patent Document 1 has led to an increase in cost because a new light absorber is required.
In addition, since a step of dispersing or applying the light absorber is added, the operation is complicated.
Furthermore, when carbon black is used as the light absorber, the transparent workpiece becomes black, so that it cannot be commercialized in a transparent state.

Further, the technique described in Patent Document 2 is not practical because it requires an advanced technique of changing the relative position between the lens and the transparent body so that the focus of the laser beam is in the deepest part of the hole. .
Furthermore, a new light absorbing solution is required, leading to an increase in cost.

  The present invention has been made to solve the above problems, and has at least a part of a plastic that is transparent to laser light by a simple method without using a light absorber or a light absorbing solution. It is an object of the present invention to provide a structure, a laser processing method, and an authenticity determination method capable of easily performing laser marking on a workpiece.

  In order to achieve this object, the structure of the present invention is a structure having at least a part of a polymer compound that is transparent to the laser beam, and the structure of the polymer compound is enhanced so as to enhance the absorption of the laser beam. At least a portion is irradiated with light and modified.

  The laser processing method of the present invention is a laser processing method for performing laser processing on a workpiece, and the workpiece has a polymer compound that is transparent to laser light at least in part, In this method, at least a part of the polymer compound is irradiated with light and modified, and then the modified part is irradiated with laser light to perform predetermined processing.

  In addition, the authenticity determination method of the present invention is an authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by irradiating a laser beam. A preparation stage in which at least a part of a workpiece to be determined to be genuine is irradiated and modified, and when marking is performed when the workpiece is irradiated with laser light, the workpiece or The determination object to which the workpiece is attached is determined to be a genuine product. On the other hand, if the marking is not applied, the method includes an authenticity determination step of determining that the product is a counterfeit product.

  In addition, the authenticity determination method of the present invention is an authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by irradiating a laser beam. A preparation stage in which a workpiece to be determined as a genuine product is irradiated with light through a shielding plate having an opening formed in the shape of a character or a figure, and a laser beam is applied to the workpiece. When marking is performed with the same letter or figure shape as the opening when irradiated, it is determined that the workpiece or the determination target to which the workpiece is attached is genuine, while the marking is The method includes an authenticity determination step of determining that the product is a counterfeit product when marking is performed in a shape that is not applied or different from a predetermined shape.

  The authenticity determination method of the present invention is an authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by illuminating the authenticity determination method. A preparation stage in which at least a part of the workpiece to be determined is irradiated and modified, and when the light appears in the transmitted or reflected light when the workpiece is illuminated, the workpiece or the workpiece It is a method having an authenticity determining step in which it is determined that the determination target to which the workpiece is attached is a genuine product, and on the other hand, if no shade appears, the product is determined to be a counterfeit product.

  The authenticity determination method of the present invention is an authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by illuminating the authenticity determination method. A preparatory stage in which the workpiece to be judged is irradiated with light through a shielding plate having an opening formed in the shape of a character or a figure, and transmitted light or light when the workpiece is illuminated When the shade appears in the shape of the same letter or figure as the opening in the reflected light, it is determined that the workpiece or the determination target attached to the workpiece is a genuine product, while the shade does not appear. Alternatively, the method includes an authenticity determination step of determining that the product is a counterfeit product when shading appears in a shape different from the predetermined shape.

According to the structure, the laser processing method, and the authenticity determination method of the present invention, the polymer compound of the workpiece can be modified by irradiating light, and the laser light absorption rate can be increased. Thereby, even if it is a to-be-processed object which has a polymer compound which shows transparency with respect to a laser beam in at least one part, the laser marking can be easily given to the polymer compound.
Further, since the method for increasing the absorption rate of the laser light is light irradiation, it is not necessary to use a light absorbent or the like, so that an increase in cost can be suppressed. In addition, since there is no step of dispersing or applying the light absorber, the work process can be simplified.
Furthermore, since the technique for increasing the absorption rate of laser light is light irradiation, the transparency of the workpiece is not impaired, and the product can be commercialized while maintaining the transparency.

  Hereinafter, preferred embodiments of a structure, a laser processing method, and an authenticity determination method according to the present invention will be described with reference to the drawings.

[Laser processing method]
First, an embodiment of the laser processing method of the present invention will be described with reference to FIG.
This figure is a process diagram showing the procedure of the laser processing method of this embodiment (process for forming a workpiece (structure)).
As shown in the figure, the laser processing method of the present embodiment includes a modification process (FIG. (I)) and a laser processing process ((ii)).

Here, the modification step refers to a step of irradiating light for the purpose of modifying the workpiece 10.
The workpiece 10 has a polymer compound at least partially. That is, the case where a part of the workpiece 10 is formed of a polymer compound and the case where the entire workpiece 10 is formed of a polymer compound are included.
In addition, the following can be included as an example of the former. For example, it may include a case where the workpiece 10 has a laminated structure of two or more layers, and at least one of them is formed of a polymer compound. Further, for example, the workpiece 10 may be formed in a sheet shape, and a part thereof may be formed of a polymer compound.

A high molecular compound shows transparency with respect to a laser beam.
“Transparency” is defined as follows.
When a substance has a transmittance of 70% or more with respect to the wavelength of the laser beam, it is “transparent”, and when the transmittance is 10% or more and less than 70%, it is “translucent”. The case of “Opacity” is assumed.

A specific example is shown in FIG. The figure is a graph showing a transmission spectrum of a stretched PET sheet which is a polymer compound.
As shown in the figure, when the workpiece 10 is a stretched PET sheet, it exhibits a property of “transparency” for a laser beam having a wavelength of about 330 nm or more, and for a laser beam having a wavelength of about 325 nm. Indicates a “translucent” property, and an “opaque” property for a laser beam having a wavelength of 320 nm or less.

Thus, in the workpiece 10, the portion formed of the polymer compound exhibits any of the above properties depending on the wavelength of the laser beam.
And when a high molecular compound shows transparency with respect to a certain wavelength, the laser beam of the wavelength penetrates into the inside of a high molecular compound. That is, the absorption of laser light is small, and the interaction between light and a substance (for example, photothermal conversion or the like) hardly occurs.
On the other hand, in the case of showing opacity, the laser light enters only near the surface of the polymer compound.

In the reforming step, the light applied to the workpiece 10 includes ultraviolet light.
Ultraviolet light (ultraviolet light, UV) is an invisible electromagnetic wave having a wavelength of 10 to 400 nm, that is, shorter than visible light and longer than soft X-rays.
By irradiating the ultraviolet light, the polymer compound is modified.
For example, when UV irradiation is performed on a sheet of polyethylene terephthalate (PET), which is a kind of polymer compound (plastic), polymer chains are decomposed and oxidized from the surface on the irradiation side. And an oxidation functional group is produced | generated in an oligomer and PET principal chain, This oxidation functional group will absorb the light of a specific wavelength. The polymer compound thus modified has a high absorptance of the laser beam contained in the above-mentioned wavelength, and the interaction between the light and the substance is likely to occur.

The inventor analyzed the surface of the workpiece 10 (specifically, a PET sheet that is a polymer compound) after UV treatment. As a result, it was found that oligomers were generated.
Further, in claim 4 and claim 11 of the claims, “the light irradiated for modification includes ultraviolet light having a wavelength of 400 nm or less”. It is ultraviolet light having a wavelength that contributes to decomposition and oxidation of a polymer compound (workpiece).

The laser processing step refers to a step of performing predetermined processing by irradiating part or all of the modified portion with a laser beam with respect to the polymer compound partially or entirely modified in the modification step. .
Since the polymer compound has an increased absorption rate of laser light by irradiation with ultraviolet light, predetermined laser processing can be easily performed. Here, the predetermined laser processing includes, for example, laser marking.
In the present embodiment, laser marking refers to a region in which a part that expresses a structural color is uniformly formed, or a character, a figure, a symbol, etc. drawn by appropriately arranging a part that expresses a structural color. Point to. As an example of this laser marking, for example, as shown in FIG. 9 (iii-1), a star-shaped figure or the like applied to the surface 11 of the workpiece 10 can be cited.

[Laser marking method]
Next, a laser marking method in the laser processing step will be described with reference to FIGS.
FIG. 3 is a diagram illustrating a state in which a workpiece is irradiated with light having a periodic intensity distribution.

In the laser processing step, the workpiece 10 is irradiated with light having a wavelength included in a wavelength region in which the workpiece 10 exhibits transparency. Specifically, light having a wavelength of 330 nm or more (for example, YAG laser third harmonic (THG-YAG): wavelength 355 nm (see FIG. 2)) is irradiated.
Here, when the workpiece 10 has not undergone the reforming step, the laser beam absorptivity is low, so that laser marking cannot be performed even when laser light having a wavelength of 330 nm or more is irradiated.
On the other hand, when the workpiece 10 undergoes a modification step, the laser beam has a high absorptance, so that laser marking can be performed by irradiating laser light having a wavelength of 330 nm or more.

Further, as shown in FIG. 3, the fine periodic structure 12 can be formed on the surface 11 of the workpiece 10 by irradiating the workpiece 10 with light (irradiation light) having a periodic intensity distribution. . The fine periodic structure 12 is formed with the same period as the periodic intensity distribution.
In particular, as shown in FIG. 4, when the workpiece 10 is irradiated with a laser beam having a wavelength indicating transparency in the interference region, a periodic light intensity distribution is excited on the surface 11 of the workpiece 10, resulting in high intensity. Laser ablation occurs at the part.
Laser ablation refers to a phenomenon in which when a substance is irradiated with laser light, the substance becomes a molecular cluster and scatters from the surface.
When this laser ablation occurs, a periodic structure 12 is formed on the surface 11 of the workpiece 10.

[Structure]
Next, an embodiment of the structure of the present invention will be described with reference to FIGS. 3, 5, and 6.
FIG. 5 is a schematic cross-sectional view showing the cross-sectional shape of the workpiece (structure) 10 before the reforming process is performed, and FIG. 6 shows the cross-sectional shape of the structure 10 after the reforming process is performed. It is a cross-sectional schematic diagram.

The structure 10 has a polymer compound at least partially (see FIG. 5). This polymer compound has a property of being transparent to laser light.
The structure 10 has a portion (modified portion) in which the absorption rate of the laser beam is increased after the modifying step (see FIG. 6). This is because, in the modification step, part or all of the polymer compound is irradiated with ultraviolet light, and the irradiated portion is modified.
Further, the structure 10 has a fine periodic structure 12 on the surface 11 after the laser processing step (see FIG. 3). This is because, in the laser processing step, when the modified portion is irradiated with laser light, the fine periodic structure 12 is formed on the surface 11.

[Laser irradiation equipment]
Next, a laser light irradiation apparatus for generating laser light having a periodic intensity distribution will be described with reference to FIG.
FIG. 2 is a schematic perspective view showing the configuration of the laser beam irradiation apparatus.
As shown in the figure, the laser beam irradiation apparatus 20 includes a laser oscillator 21, a beam splitter (transmission type diffractive optical element) 22, a convex lens 23, a mask 24, and a convex lens 25.

The laser oscillator (laser light source) 21 is a device that outputs a laser. For example, a nanosecond laser or a picosecond laser such as a YAG laser, a YVO ₄ laser, or a YLF laser, or a femtosecond laser such as a Ti: sapphire laser. Can be used. These pulse lasers have a repetition frequency of several Hz to several tens kHz, and emit energy stored during this repetition period in a very short time width of several fs to several tens ns. Therefore, a high peak power can be efficiently obtained from a small input energy.

The laser oscillator 21 has a function of adjusting the number of irradiation pulses. The laser oscillator 21 can also control the energy density (fluence: energy per irradiation area of one pulse) by adjusting the output of the laser.
The energy density can be controlled not only by adjusting the laser output in the laser oscillator 21, but also by changing the irradiation beam diameter with the same laser output.

The beam splitter 22 is a transmissive optical element that diffracts because fine concave portions or convex portions are periodically carved on the surface, and divides the laser light into a plurality of light beams.
As the convex lens 23, for example, a synthetic quartz plano-convex lens having a focal length of 200 mm can be used. In this case, the convex lens 23 is placed at a position 200 mm from the beam splitter 22. The convex lens 23 passes a plurality of light beams divided by the beam splitter 22.

The mask 24 is placed at a position where the light beam that has passed through the convex lens 23 is focused, blocks a light beam unnecessary for interference among the plurality of light beams, and allows only the necessary light beam to pass.
As the convex lens 25, for example, a synthetic quartz plano-convex lens having a focal length of 100 mm can be used, and the light flux that has passed through the mask 24 is condensed, and the light flux intersects and interferes. As shown in FIG. 4, the interfering region has a high intensity region distribution, and the workpiece 10 is irradiated in this region.

[Example]
Next, examples will be described.

Example 1
A plurality of stretched PET sheets having a thickness of 150 μm were prepared as the workpiece 10.
One or several of these stretched PET sheets were irradiated with ultraviolet light emitted from a mercury / xenon lamp (manufactured by Ushio) for 10 minutes from a distance of 12 cm.
Here, as a result of measuring the transmittance of the stretched PET sheet at a wavelength of 355 nm, it was 82.3% before irradiation and 76.7% after irradiation.

Subsequently, the above-mentioned stretched PET sheet irradiated with UV and unstretched stretched PET sheet are prepared, and a Q-switch pulse YAG laser third harmonic (wavelength 355 nm) showing transparency in the stretched PET sheet is emitted by a laser light irradiation device. Irradiated.
Here, the specifications of the pulse YAG laser were a pulse width of 5 ns and a repetition frequency of 10 Hz. When the irradiation energy density was 400 [mJ / cm ² ], one pulse was emitted, and when the irradiation energy density was 100 [mJ / cm ² ], 15 pulses were emitted.

The results are shown in FIGS. 8 (i) to (iii). As shown in FIG. 6 (i), no change was observed in the unirradiated PET sheet. On the other hand, as shown in FIGS. (Ii) and (iii), in the PET sheet that had been irradiated with UV, laser marking was applied to the UV irradiated surface, and a structural color was observed.
In the image shown in FIG. 2 (ii), the laser marking applied to the upper half is the laser marking applied to the lower half when the fluence is 400 [mJ / cm ² ]. The case where 15 laser beams having a fluence of 100 [mJ / cm ² ] are irradiated is shown.
FIG. 3 (iii) is an enlarged SEM image of the portion of the stretched PET sheet shown in FIG.
Thus, as a result of performing Example 1, it turned out that laser processing can be performed by irradiating a polymer compound with ultraviolet light beforehand.

(Example 2)
A plurality of stretched PET sheets having a thickness of 150 μm were prepared as the workpiece 10.
One or several of these stretched PET sheets were irradiated with ultraviolet light emitted from a mercury / xenon lamp (manufactured by USHIO INC.) For 5 seconds from a distance of 55 mm.
Here, as a result of measuring the transmittance of the stretched PET sheet at a wavelength of 355 nm, it was 82.3% before irradiation and 82.1% after irradiation.

Subsequently, the stretched PET sheet irradiated with UV and the unstretched stretched PET sheet are prepared, and a Q-switch pulse YAG laser third harmonic (wavelength 355 nm) showing transparency in the stretched PET sheet is applied to the interference optical system (laser). Irradiation was performed by a light irradiation device 20).
Here, the specifications of the pulse YAG laser were a pulse width of 5 ns and a repetition frequency of 10 Hz. Further, one pulse was irradiated when the irradiation energy density was 400 [mJ / cm ² ].
As a result, no change was observed in the unirradiated PET sheet. On the other hand, in the UV-irradiated PET sheet, laser marking was applied to the UV-irradiated surface, and a structural color was observed.
As described above, as a result of performing Example 2, it was found that laser processing can be performed even when ultraviolet light is irradiated for 5 seconds from a position 55 mm away from the polymer compound.

(Example 3)
Four stretched PET sheets having a thickness of 150 μm were prepared as the workpiece 10.
Of these, one stretched PET sheet was irradiated with a UV lamp (black light) having an emission peak wavelength of 254 nm for 90 minutes. The other sheet was irradiated with a 302 nm UV lamp for the same time. The other one was irradiated with a 365 nm UV lamp for the same time. The remaining stretched PET sheet was not irradiated with a UV lamp.
Here, the transmittance of the stretched PET sheet at a wavelength of 355 nm was 82.3% for unirradiated, 80.4% after 254 nm irradiation, 77.9% after 302 nm irradiation, and 81.8% after 365 nm irradiation. It was.

Subsequently, YAG laser third harmonic (wavelength 355 nm) was irradiated to the four stretched PET sheets by a laser beam irradiation apparatus.
Each PET sheet irradiated with UV at each peak wavelength was irradiated with one pulse at an irradiation energy density of 400 [mJ / cm ² ]. As a result, no change was observed in the 365 nm irradiated PET sheet. Laser marking was applied to the UV irradiation surface of the 302 nm irradiated PET sheet.

[Authenticity judgment method]
Next, the authenticity determination method using the laser marking of this embodiment will be described with reference to FIGS.
FIG. 9 is a diagram showing the procedure of the first embodiment of the authenticity determination method. FIG. 10 is a diagram showing the procedure of the second embodiment of the authenticity determination method.

(First Example)
In the first embodiment, the workpiece or counterfeit product is irradiated with laser light to determine the authenticity of the workpiece or the like.
As shown in FIG. 9, the authenticity determination method of the present embodiment includes a reforming stage (preparation stage, FIG. (I)), a distribution stage (FIG. (Ii)), and an authenticity determination stage (FIG. (Iii) -1)).

Here, the modification step is a step of irradiating all or part of the polymer compound of the workpiece 10 with ultraviolet light.
The ultraviolet light may be applied to the entire polymer compound or a part thereof.
When a part of the workpiece 10 is irradiated with ultraviolet light, a shielding plate 30 can be used as shown in FIG.
The shielding plate 30 is a member provided between an ultraviolet light irradiation device (not shown) and the workpiece 10 and has an opening 31 formed therein.

The opening 31 is an open part for allowing a part of the ultraviolet light to pass therethrough. Since the shielding plate 30 has the opening 31, the ultraviolet light output from the ultraviolet light irradiation device is partially blocked by the body of the shielding plate 30 and does not reach the workpiece 10, but the other passes through the opening 31. Then, the workpiece 10 is reached.
The surface 11 of the workpiece 10 is irradiated with ultraviolet light in the same shape as the opening 31, and the irradiated range is recorded as a range where laser marking is possible.
The opening 31 can be formed in various shapes such as characters, figures and symbols.
In addition, the reforming stage is a stage in which the workpiece 10 to be determined as a genuine product in the authenticity determination stage is preliminarily irradiated and modified before shifting to the distribution stage. Including the meaning.

The distribution stage is a stage in which the workpiece 10 irradiated with ultraviolet light is distributed in the form of the product itself or the product.
In this distribution stage, the workpiece 10 has already been irradiated with ultraviolet light. However, since the change in the transmittance of the UV-irradiated portion is small, the change in the color of the irradiated portion has almost no visual difference, and is indistinguishable from the portion not irradiated with UV. For this reason, when the counterfeit distribution product 40 (imitation product of the workpiece 10) which is not irradiated with ultraviolet light is available, the counterfeit distribution product 40 and the workpiece 10 cannot be visually distinguished.

In the authenticity determination step, the authenticity depends on whether laser marking is applied when the workpiece 10 or counterfeit distribution product 40 is irradiated with laser light, or whether the applied laser marking has a predetermined shape. This is a stage for judging whether or not the product is a product.
For example, when laser marking is applied when laser light is irradiated, or when the laser marking is in a predetermined shape, this irradiation target is a workpiece that has been irradiated with ultraviolet light in advance. 10 can be determined. The workpiece 10 itself or the product (determination target) to which the workpiece 10 is attached can be determined to be a genuine product.
On the other hand, if the laser marking is not performed even when the laser beam is irradiated, or if the applied laser marking is not in a predetermined shape, the irradiation target is a counterfeit distribution product 40 that is not irradiated with the ultraviolet light. It can be judged that there is. The counterfeit distribution product 40 itself or the product to which the counterfeit distribution product 40 is attached can be determined to be a counterfeit product.

In the modification stage, when the entire workpiece 10 is irradiated with ultraviolet light without using the shielding plate 30 or the like, the laser beam is irradiated on the workpiece 10 when the laser beam is irradiated in the authenticity determination stage. Authenticity is determined by checking whether marking has been applied.
On the other hand, when the modified portion having a predetermined shape is formed on the workpiece 10 by irradiating the ultraviolet light through the shielding plate 30 in the modification stage, when the laser is irradiated in the authenticity determination stage. The authenticity is determined by checking whether the workpiece 10 has been laser-marked with the predetermined shape.

  In this manner, whether or not laser marking is performed or a specific shape is applied even when counterfeit products that have not been irradiated with UV are mixed in the process in which the workpiece 10 irradiated with UV in advance is distributed in the market. It is possible to easily determine the authenticity by trying whether it is applied or not.

(Second embodiment)
In the second embodiment, the authenticity of a workpiece or the like is determined by illuminating a workpiece or a counterfeit distribution product and checking whether or not a light and shade of a predetermined shape appears in the transmitted or reflected light. To do.

As shown in FIG. 10, the authenticity determination method of this embodiment includes a reforming stage (preparation stage, FIG. 10 (i)), a distribution stage (FIG. 10 (ii)), and an authenticity determination stage (FIG. -2)).
Here, the reforming stage and the distribution stage are the same as the reforming stage and the distribution stage in the first embodiment.

In the authenticity determination step, whether illumination light is applied to the workpiece 10 or the counterfeit distribution product 40 (illumination target object), whether the density of the transmitted light or reflected light appears on the projection object 50 in a predetermined shape. This is the stage for judging whether or not the product is genuine.
For example, by illuminating the illumination object, when the shade 50 appears in the projection target 50 and the dark shadow portion appears in a predetermined shape, it can be determined that the illumination object is the workpiece 10. . The workpiece 10 itself or the product (determination target) to which the workpiece 10 is attached can be determined to be a genuine product.
On the other hand, when the shade 50 does not appear in the projection target 50 even when illuminated, or the shade does not appear in a predetermined shape, it can be determined that the irradiation object is the counterfeit distribution product 40. The counterfeit distribution product 40 itself or the product to which the counterfeit distribution product 40 is attached can be determined to be a counterfeit product.

The reason why such a determination can be made is as follows.
The workpiece 10 which is a genuine product is irradiated with ultraviolet light in a predetermined shape in advance in the reforming stage. Since this irradiated portion is modified, the absorption rate of light having a predetermined wavelength is higher than that of other portions.
In the authenticity determination stage, when the illumination light is applied to the workpiece 10, the modified portion absorbs light more than the other portions. Therefore, a shadow corresponding to the shape of the modified portion is projected on the projection target 50.
On the other hand, the counterfeit distribution product 40 which is a counterfeit product is not irradiated with ultraviolet light, and there is no modified portion like the workpiece 10. For this reason, even if illumination light is applied to the counterfeit distribution product 40 at the authenticity determination stage, light and shade are not projected on the projection target 50.

A specific example of this embodiment will be described. Here, the case where PET is used for the workpiece 10 will be described.
The modified portion of PET has an increased absorptance in the vicinity of a wavelength of 355 nm (referred to as a modified wavelength band) compared to the unmodified portion. For this reason, when the determination target is illuminated with light including the modified wavelength band, the amount of light is reduced only at the portion corresponding to the modified portion of transmitted light or reflected light. Authenticity is determined by the presence or absence or shape of this shading (ie, shadow).
At this time, since the modified wavelength band is an invisible range, the image pickup device such as a camera is used. Even if the illumination light to be used has the same wavelength as the laser light, the light intensity is low, so that the processing is not performed like the laser light.

  In this way, even when a pre-UV irradiated workpiece 10 is distributed in the market, even if a counterfeit product that has not been irradiated with UV is mixed, the workpiece 10 is illuminated and its transmitted or reflected light is reflected. It is possible to easily determine the authenticity by seeing whether or not shade appears in the image.

The illumination light may be light that illuminates brighter than the surroundings, and light or shade appears in transmitted light or reflected light. The illumination device is specified, and lower limit values such as light intensity, luminance, illuminance, and light quantity are limited. It is not something to do.
Further, the projection target 50 may be any surface that can project the density of transmitted light or reflected light, and the material, shape, size, color, and the like are not limited.

(Advantage of the second embodiment)
Next, the superiority of the second embodiment will be described with reference to FIG.
This figure is a diagram comparing the first embodiment with the second embodiment regarding the authenticity determination method.
As shown in the figure, the first embodiment and the second embodiment share the reforming stage (i) and the distribution stage (ii), but differ in the authenticity determination stage (iii).

In the authenticity determination step (iii-1) of the first embodiment, as shown in FIG. 5 (α) (determination method by laser marking), the workpiece 10 is irradiated with laser light, and marking is performed in a predetermined shape. The authenticity is judged by seeing whether it is applied or not.
Here, since laser marking is an irreversible change, once applied, it cannot be returned to the state before application. For this reason, the work piece and the added object cannot be distributed thereafter.

On the other hand, in the authenticity determination step (iii-2) of the present embodiment, as shown in (β) (determination method using illumination light) in FIG. The authenticity is determined by checking whether or not a shade of a predetermined shape appears.
Here, the workpiece 10 is merely illuminated and no change occurs. For this reason, the workpiece 10 can be distributed even after passing through the authenticity determination step (iii-2).

  As described above, when the first embodiment and the second embodiment of the authenticity determination method are compared, the common effect is that the authenticity of the distribution product can be determined. In the case where the attached product is put on the distribution process thereafter, it is desirable to use the second embodiment.

As described above, according to the structure, the laser processing method, and the authenticity determination method of this embodiment, the workpiece including transparent plastic is irradiated with light containing ultraviolet light (UV) having a wavelength of 400 nm or less, By modifying the workpiece, the absorption of laser light in the workpiece increases, so that laser marking can be easily performed.
In addition, since the light absorbent disclosed in Patent Document 1 described above and the light absorbing solution disclosed in Patent Document 2 are not used, the laser marking process can be simplified and the cost can be reduced.
Furthermore, the forgery prevention function can be provided by using the hidden marking that appears only in the UV irradiated portion.

The preferred embodiments of the structure, laser processing method, and authentication method of the present invention have been described above. However, the structure, laser processing method, and authentication method of the present invention are not limited to the above-described embodiments. Needless to say, various modifications can be made within the scope of the present invention.
For example, in the above-described embodiment, polyethylene terephthalate (PET) is used as the material of the workpiece. However, the material is not limited to PET. For example, polystyrene, polyethylene, polypropylene, polycarbonate, nylon resin, acrylic resin, chloride High molecular compounds such as vinyl resin and phenol resin can be used as the material. Polyester compounds such as polyethylene naphthalate (PEN), polybutylene terephthalate (PBT), and polytrimethylene terephthalate (PTT) can also be used as a material. However, the periodic structure 12 needs to be formed by laser light irradiation.

  Further, in the embodiment of the authenticity determination method described above, the authenticity is determined based on the presence or absence of the formation of the laser marking. However, the present invention is not limited to this determination method. For example, even when laser marking is performed, a specific mark is determined. If it is not a shape, it can also be determined that it is a counterfeit product.

  So far, the laser marking has been described as the predetermined laser processing, but this case is considered to be an effective laser processing method for other laser processing such as drilling and cutting. In this case, a thin workpiece is particularly suitable.

  Since the present invention relates to laser processing, the present invention can be used for a method of performing laser processing, an article as an object thereof, an apparatus used for laser processing, authenticity determination using laser processing, and the like.

It is a schematic diagram which shows the process of the laser processing method in embodiment of this invention, Comprising: (i) shows a modification process and (ii) shows a laser processing process. It is a graph which shows the transmission spectrum of a to-be-processed object (stretched PET sheet). It is the wave form diagram and a cross-sectional schematic diagram which show a mode that the light which has periodic intensity distribution is irradiated to a workpiece. It is a figure which shows the interference area | region of the light irradiated to a to-be-processed object. It is a cross-sectional schematic diagram which shows the structure of the structure in embodiment of this invention. It is a cross-sectional schematic diagram which shows the structure of the structure in a modification | reformation process. It is a perspective view which shows the structure of a laser beam irradiation apparatus. It is an enlarged view which shows the external appearance of the to-be-processed object after being irradiated with a laser beam, Comprising: (i) is a case where ultraviolet light is not irradiated, (ii) is a case where ultraviolet light is irradiated beforehand, (iii) ) Shows an SEM image in the case of (ii). It is a schematic diagram which shows the procedure of the 1st Example of an authenticity determination method, Comprising: (i) is a modification | reformation stage, (ii) is a distribution | circulation stage, (iii-1) shows an authenticity determination stage. It is a schematic diagram which shows the procedure of the 2nd Example of an authenticity determination method, Comprising: (i) is a modification | reformation stage, (ii) is a distribution | circulation stage, (iii-2) shows an authenticity determination stage. It is a schematic diagram which shows each procedure of the 1st Example and 2nd Example of an authenticity determination method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Workpiece 11 Surface 12 Fine periodic structure 20 Laser light irradiation device 21 Laser oscillator 30 Shielding plate 31 Aperture 40 Counterfeit distribution product 50 Projected object

Claims (11)

A structure having a polymer compound that is transparent to laser light at least in part,
A structure characterized in that at least a part of the polymer compound is irradiated with light so as to enhance absorption of the laser light. The structure according to claim 1, wherein a fine periodic structure is formed in the modified portion by laser light irradiation. A laser processing method for performing laser processing on a workpiece,
The workpiece has at least a part of a polymer compound that is transparent to laser light,
A laser processing method, comprising: modifying at least a part of the polymer compound by irradiating light, and then performing predetermined processing by irradiating the modified part with the laser beam. The laser processing method according to claim 3, wherein the light irradiated for the modification includes ultraviolet light having a wavelength of 400 nm or less. 5. The laser processing method according to claim 3, wherein the modified portion of the workpiece is irradiated with the laser light with a periodic intensity distribution to form a fine periodic structure on a surface of the modified portion. . 6. The laser according to claim 3, wherein the modified portion of the workpiece is irradiated with the light through a shielding plate having an opening formed in the shape of a character or a figure. Processing method. An authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by irradiating laser light,
A preparatory stage in which at least a part of the workpiece to be determined to be genuine is irradiated with light and modified;
If marking is performed when the workpiece is irradiated with laser light, it is determined that the workpiece or a determination target to which the workpiece is attached is genuine, while no marking is applied. And an authenticity determination step for determining that the product is a counterfeit product. An authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by irradiating laser light,
A preparatory stage in which a workpiece to be determined as a genuine product is modified by irradiating light through a shielding plate having an opening formed in the shape of a character or a figure,
When marking is performed with the same character or figure shape as the opening when the workpiece is irradiated with laser light, the workpiece or the determination target to which the workpiece is attached is genuine. An authenticity determination method comprising: determining whether the product is a counterfeit product when it is determined that the product is not marked or is marked with a shape different from a predetermined shape. An authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by illuminating,
A preparatory stage in which at least a part of the workpiece to be determined to be genuine is irradiated with light and modified;
When light and shade appear in transmitted light or reflected light when the workpiece is illuminated, it is determined that the workpiece or the determination target to which the workpiece is attached is genuine, while light and shade appear. If not, there is an authenticity determination step for determining that the product is a counterfeit product. An authenticity determination method for determining whether or not a workpiece or a determination target to which the workpiece is attached is genuine by illuminating,
A preparatory stage in which a workpiece to be determined as a genuine product is irradiated with light through a shielding plate having an opening formed in the shape of a character or a figure, and modified.
When light and shade appear in transmitted light or reflected light in the same character or figure shape as the opening when the workpiece is illuminated, the workpiece or the determination target to which the workpiece is attached is genuine. On the other hand, the authenticity determining method includes: an authenticity determining step of determining that the product is a counterfeit product when the contrast does not appear or when the contrast appears in a shape different from the predetermined shape. The authenticity determination method according to any one of claims 7 to 10, wherein the light irradiated for the modification includes ultraviolet light having a wavelength of 400 nm or less.