LT4108B - Method and apparatus for laser marking of products from transparent materials - Google Patents

Abstract

Method of marking products made of transparent materials involves (i) concentration of a laser beam (2) in the material (5), which does not absorb the beam, at a predetermined location (4), (ii) destruction of the material by laser pulses and (iii) formation of the marking symbol by displacement of the laser beam. Destruction of the material at that location takes place in two stages. In the first stage, the resistance of the material to laser radiation is altered, while, in the second stage, destruction of the material takes place at that location. Also claimed is an appts. for implementation of the method.

Description

The present invention relates to the field of laser optics and is intended for an internal marking method and device for solids, and can be used to label transparent materials, providing a clearly visible, indelible marking on the product.

The invention, according to International Application WO 92/03297, describes a laser marking method comprising selecting a marking site inside a product to be labeled, concentrating the laser beam not absorbed by the product material, selecting the product material in the concentration region by exposure to high energy laser beams. changing the position of the area inside the product by creating a fixed shape mark.

The aforementioned international patent application WO 92/03297 discloses a laser marking device for carrying out said marking method, comprising a laser generating a high-energy light beam not absorbed by the material of the article, a focusing device which concentrates the laser beam inside the article. and means for adjusting the position of the beam focus region within the product, respectively, to create a fixed shape mark.

The disadvantage of the known method and device is that the resulting mark is non-contrasting, i.e. it can be blurred and deformed because it is exposed to high-energy laser beams during the destruction of the material inside the product. The beam has a maximum energy density of 10 J / cm ² , a power of 10 ⁷ W / cm ² and a pulse duration of less than 10 ' ^{6 s} throughout the focus area. This energy beam can change not only the mechanical properties of the material in the focus area , resulting in opacity of the degraded material, but these effects can also create internal stresses, which in turn cause uncontrolled cleavage around the focus area or offer surface breakouts that reduce the brightness and distortion of the markings.

The invention, according to International Application WO 94/14567, describes a method for internal labeling of a solid product comprising selecting a labeling site within the product to be labeled, concentrating the laser beam not absorbed by the product material at a selected location, impulses and changing the position of the concentration area inside the product, creating a fixed shape sign.

Higher contrast of the mark is obtained when the direction of the laser beam is 90 ° with the direction of the mark observation.

The aforementioned international patent application WO 94/14567 discloses an internal marking device for a solid product comprising a pulsed laser generating high power light beam pulses, a focusing device which concentrates the laser beam inside the product in a selected area, and means for changing the focal points accordingly. position of the area inside the product to create a fixed shape mark. The parameters of the laser beam are selected so that the material is disrupted within the focus area and is not compromised around this area.

The disadvantage of the known method and device is that the small size marking is blurred and deformed because of the high power and uniform intensity across the fiber cross-section of the product by laser beam pulses (pulse energy - 50 mj, pulse duration - 10 - ^β). s and pulse frequency - 1 Hz) not only can the mechanical properties of the material be altered, resulting in opacity and visualization of the material, but it also creates internal stresses that can cause uncontrolled decomposition around the concentration range and offer breakouts in the form of surface, which prevents the device and the device from obtaining a small disintegrated area close to the sphere, which reduces the brightness of the markings and distorts the shape. As a result, this device and device cannot receive very small-sized characters, make internal markings on thin details, and receive contrasting notes.

It is an object of the present invention to provide a laser marking method and device capable of obtaining small, contrasting marking symbols inside a transparent material article, as well as performing marking on the thin walls of the article.

The essence of the solution to this problem is that the transparent material in the laser marking method of the product comprises selecting a marking site inside the product, concentrating the laser beam not absorbed by the product material, disrupting the structure of the product material by concentration by laser beam pulses and forming, by changing the position of the concentration region inside the product, the disrupted material structure in the concentration area within the product is obtained in two steps, in the first step reducing the laser resistance of the material in the concentrating area and in the second step disrupting the material structure.

The two-step disruption of the structure of the material is obtained by operating the material at a selected location on at least two laser pulses of different parameters, the first or first pulses in their concentration area reducing the laser resistance and the subsequent or multiple pulses in said area destroying the material structure. becomes visible. One such parameter is the intensity of the laser pulse. The intensity of one or more of the first laser pulses is selected such that the laser beam in its concentration area changes the resistance of the material to laser radiation, i. y. it would reduce it and select one or more successive pulses less than the intensity of one or more first pulses, but would disrupt the structure of the material in an area where the laser's radiation resistance was reduced by the first (first) pulse.

In this way, by selecting the laser pulse parameters accordingly, which in the first step reduces the laser resistance of the material and in the second step performs the disintegration of the material structure in the affected area, the laser pulse energy required to destroy the material is reduced. Because the magnitude of the cracks due to internal stresses around the concentration area is proportional to the magnitude of the laser pulse energy, a reduction in the magnitude of the energy of these pulses automatically reduces the magnitude of said cracks. By reducing the size of the cracks, the marking becomes more contrasting and can also be marked with small symbols.

The size of the labeled symbol can be further reduced and the contrast enhanced if the laser beam is shaped such that the intensity at the edges of the beam is highest and centered at the lowest, i.e.. the intensity distribution in the fiber would be ring-shaped.

The above effect will be further enhanced by selecting the shortest laser beam or its harmonic wavelength for which the material of the product is transparent.

The laser marking method thus provided according to the invention can:

- make small-sized, various markable symbols (tens of microns in order to obtain areas of disrupted material structure);

- apply markings on thin details, such as less than 0.5 mm thick;

- apply markings in a thin layer beneath the surface, for example, to mark tempered glass;

- receive contrasting markings.

The proposed method of laser marking also includes the steps of determining the degree of reduction of laser radiation resistance caused by the first (at least one) pulse, which evaluates the parameters of the following pulses, i.e. y. pulse energy density (intensity), number, duration, frequency, etc., which can be controlled by the size and shape of the disrupted material area, respectively.

Alternatively, the degree of decrease in material resistance caused by one or more of the first pulses is determined by the luminous intensity of the region in which the laser beam is concentrated.

One such case is when the degree of material resistance reduction caused by one or more of the first pulses is determined by the magnitude (intensity) of the acoustic waves emanating from the area where the laser beam is concentrated.

To solve the above problem, the proposed device comprises a pulsed laser generating a wavelength beam of light which is not absorbed by the product material, a focusing device which concentrates the laser beam inside the product at a selected location and means for changing the position of the concentration region inside the product. a marking symbol was created, and a means was introduced to reduce the laser resistance of the material in the first stage in the area of laser beam concentration and in the second stage to disrupt the structure of the material in said area.

The aforesaid means is to ensure the destruction of the material in two stages by creating different parameters of the laser pulses acting in the concentration field and controlling these parameters in the second stage depending on the degree of decrease of the laser resistance of the material by the laser pulses in the first stage.

In addition, the device has a beamform intensity distributing shaper located on the beam path between the pulsed laser and the focusing unit and shaping the laser beam intensity distribution with the highest intensity at the edges of the beam and the lowest intensity at its center.

The device employs a pulsed laser to generate a beam having a wavelength, or a harmonic, which is the shortest in the wavelength range in which the material is transparent.

DETAILED DESCRIPTION OF THE INVENTION The drawings, which schematically depict laser marking devices, will explain the invention in more detail.

FIG. 1 is a schematic view of a first embodiment of a laser marking device.

FIG. 2 is a schematic view of a second embodiment of a laser marking device.

The proposed method of laser marking of a transparent material product consists of the following sequence of operations: choosing a marking site inside the product, concentrating laser beam pulses at the chosen place which are not absorbed by the product material, performing two steps of fiber structure disintegration; and in the second step destroys the material structure in said area.

The two-step disruption of the structure of the material is obtained by operating the material at a selected location on at least two laser pulses of different parameters, the first or first pulses in their concentration area reducing the laser resistance and the subsequent or multiple pulses in said area destroying the material structure. becomes visible. One such parameter is the intensity of the laser pulse. The intensity of one or more of the first laser pulses is selected such that the laser beam in its concentration area changes the resistance of the material to laser radiation, i. y. and reducing the intensity of one or more subsequent pulses to less than the intensity of one or more of the first pulses so as to disrupt the structure of the material in an area where the laser resistance to radiation is reduced by the first (s) of the pulse. For example, in silicate glass labeling, the intensity of the first pulse is set at 1.5 to 2 times that of the subsequent pulses. This achieves a diameter of up to 50 microns in the region of the disrupted material.

A preferred embodiment of the laser marking method is to form the laser beam, prior to concentrating it at a selected location on the product, such that the intensity at the edges of the beam is highest and at the center, i.e. lowest. the intensity distribution in its cross-section would be ring-shaped. For example, labeling with sapphire (AI2O3) using a ring-shaped fiber achieves a diameter of about 15 microns in the region of the disintegrated material, and 3 times the size of the region of the disintegrated region.

In addition, the laser marking method includes determining the degree of material resistance reduction caused by the first (at least one) pulse, which evaluates the parameters of the subsequent pulses, i.e. y. the number of pulses, the energy (intensity). the duration .the repetition frequency that changes to give the desired size and shape of the disrupted area. One way to determine the degree of resistance of a material is to measure the magnitude (intensity) of the acoustic waves emitted from the area where the laser beam is concentrated or otherwise measure the intensity of the glow in the concentration area.

The effect mentioned above will be even greater if the shortest laser beam or its harmonic wavelength is selected for which the material of the product is transparent.

One embodiment of the device implementing the proposed method is schematically illustrated in FIG. 1. This device comprises a pulsed laser 1 having a focusing device 3 in the path of the beam 2 which concentrates the laser beam 2 in a selected concentration area 4 located inside the transparent material article 5 where labeling will be performed. The focusing device is mounted on the positioning device 6 which is connected to the controller 7. The marking product 5 is on a moving platform 8 which is connected to the controller 9. A converter 10, such as an optical transducer, is mounted next to the focusing device 3. a plasma glow in the concentration area 4 or an acoustic transducer. which registers an acoustic wave emanating from the concentration area 4. The transducer 10 is connected via a matching unit 11 to a control unit 12 having corresponding outputs connected to the laser 1 and the controllers 7 and 9. 5, where we want to carry the marking, can be made of clear glass, colored glass, optical crystal, plastic. The product material must not absorb the laser beam. Laser 1, for example, can be a solid-state pulsed laser such as an Nd-YAG laser. Other laser parameters are selected depending on the material of which the product is made. 5. The laser pulse energy should be approximately 5 mJ, pulse frequency 50 Hz, pulse duration 5-20 ns. In addition, the wavelength of the laser beam or its harmonic is selected in the range in which the material of the article is transparent, ideally the shortest wavelength in this range, for example 530 nm in the case of silicone glass.

First, the positioning device 6 and the movable platform 8 select the laser beam focus area 4 inside the article 5. Provides one or more of the first laser pulses whose effects on the material in the concentration domain 4 are recorded by the optical transducer 10. If there is no signal at the output of the transducer, the intensity of the first laser pulses is increased until the material changes in concentration. The resulting electrical signal at the output of the transducer 10 passes through the matching unit 11 to the computer 12, which determines the parameters of the subsequent pulses so that the material affected by the first pulses is disrupted, i.e. an opaque, light-scattering area would form. If the parameter controlled by the laser pulse is the pulse intensity, the intensity of the following pulses is lower than the intensity of the first pulses. For example, in silicate glass labeling, the intensity of the first pulse is set at 1.5 to 5 times that of the subsequent 2 to 5 pulses. This achieves a diameter of up to 50 microns in the region of the disrupted material. After the material structure is disrupted within the defined concentration area, the computer 12 transmits a signal to the positioning device 6, and the laser beam concentration area is moved to another location in the article and, similarly, to the new concentration area. Such successive operations form a symbol.

FIG. Another embodiment of the device shown in Figure 2 has all the same units as the device shown in FIG. 1, only additionally has a laser pulse intensity distribution shaper 13 located on the path of the laser beam 2 between the pulsed laser 1 and the focusing device 3. The shaper 13 distributes the intensity in the laser beam so that the highest intensity is at the beam edges. Such a shaper may consist of a telescope extending a laser beam and an opaque disk-shaped screen covering the central portion of the expanded beam, or two identical conical optical members disposed at opposite cone bases (not shown). At this intensity distribution, the laser beam incident on the lens of the focusing device is annular and concentrating such a beam in the selected region of the article and performing the above described two-step disintegration results in even greater contrast and reduced size of the labeled symbol. For example, in sapphire labeling (Al2O3), the annular fiber achieves a diameter of about 15 microns in the region of the disintegrated material, while the size of the disintegration region in the conventional fiber is 3 times greater.

Claims (17)

DEFINITION OF INVENTION 1. A method of laser marking a transparent material product, comprising selecting a marking site within the product, concentrating the laser beam not absorbed by the material of the article at a selected location, disrupting the structure of the article material by pulsed laser beams and forming a marking symbol within the article, characterized in that the disintegrated material structure in the concentration area is obtained by at least two steps, in the first step reducing the laser resistance of the material in the concentration area and in the second step in said area, disrupting the material structure. 2. A method according to claim 1, characterized in that the disrupted structure of the material is obtained by operating the material at a selected location on at least two laser pulses of different parameters, the first or first pulses in their concentration reducing the laser resistance and impulses in said area disrupt the structure of the material. 3. The method of claim 2, wherein the laser pulse parameter is a laser pulse intensity and the intensity of one or more of the first laser pulses is selected such that the laser beam in its concentration area reduces the laser resistance of the material and one or more further pulses. The intensity is selected to be less than the intensity of said first pulses, but to disrupt the structure of the material in an area where the first (first) pulse is exposed to a decrease in laser resistance. 4. A method according to claims 1-3, characterized in that the laser beam is formed in such a way that the intensity at the edges of the beam is highest and at the center lower, i.e. the intensity distribution in the fiber would be ring-shaped. 5. A method according to claims 1-4, characterized in that it selects the shortest laser beam or its harmonic wavelength for which the material of the article is transparent. 6. A method as claimed in any one of claims 1 to 5, characterized in that, in a first step, it determines the degree of reduction of the laser resistance of the material, which evaluates the parameters of the subsequent pulses, i. y. pulse energy density (intensity), number, duration, frequency, controlled by the size and shape of the disordered material structure area, respectively. 7. The method of claim 6, wherein the degree of reduction of laser resistance of the material in the first step is determined by the magnitude (intensity) of the acoustic waves emanating from the region in which the laser beam is concentrated. 8. The method of claim 6, wherein the degree of reduction in laser resistance of the material is determined by the intensity of the luminous intensity of the region in which the laser beam is concentrated. 9. A laser marking device for a transparent material product, consisting of a pulsed laser generating a wavelength of light that is not absorbed by the material of the product, a focusing device for concentrating the laser beam inside the product at a selected location, and means for changing , in order to create a sign symbol, characterized in that it has a means for ensuring, in the first stage, a reduction in the laser radiation resistance of the material in the concentration region and in a second stage a destruction of the structure of the material in said area. 10. A device according to claim 9, characterized in that said means is capable of disrupting the structure of the material in two steps by generating different parameters of the laser pulses acting in the concentration of the material in the first and second stages respectively. 11. Apparatus according to claim 10, characterized in that said means is comprised of a transducer (10) having an inlet communicating with a concentration area (4) and an outlet connected to an inlet by a control unit (12) via a matching block (11). a first output connected to a control input of a pulsed laser (1), a second output via a controller (7) connected to a control input of a positioning device (6) having a focusing device (3) and a transducer (10) and a third output of the control unit (12) connected via a controller (9) to a movable platform (8) on which the product to be marked (5) is mounted. 12. Apparatus according to claim 11, characterized in that the transducer (10) is an optical transducer, which registers plasma luminosity in the laser beam concentration area (4) and transmits an electrical signal through the matching unit (11) to the control unit (12), which changes the laser pulse. parameters in proportion to the intensity of the glow. 13. Apparatus according to claim 11, characterized in that the transducer (10) is an acoustic transducer, which registers an acoustic wave emitted from the laser beam concentration area and transmits an electrical signal through the matching unit (11) to the control unit (12). the corresponding parameters of the pulses in proportion to the intensity of the acoustic wave. 14. A device according to claims 9-13, characterized in that it has a beam intensity distribution shaper located on the beam path between the pulsed laser and the focusing device and forming a laser beam intensity distribution having a maximum intensity at the edges of the beam part. Apparatus according to claim 14, characterized in that the beamformer is a telescope which extends the laser beam and an opaque disk-shaped screen covering the central part of the expanded beam. 16. Apparatus according to claim 14, characterized in that the beamforming beamformer is two optical cones of uniform cone disposed on opposite cone bases. 17. A device according to any one of claims 9 to 16, characterized in that the beam produced by the pulsed laser has a beam or its harmonic wavelength in the shortest wavelength range in which the material of the article is transparent.