WO1990001418A1

WO1990001418A1 - Process for marking composite elements with laser beams and composite element thus produced

Info

Publication number: WO1990001418A1
Application number: PCT/DE1989/000514
Authority: WO
Inventors: Martin Wehner; Reinhart Poprawe
Original assignee: Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
Priority date: 1988-08-03
Filing date: 1989-08-03
Publication date: 1990-02-22
Also published as: DE3826355C2; DE3826355A1; AU4043089A; EP0428575A1

Abstract

Process for marking composite elements with laser beams, in particular compound glass, where one of several assembled layers is at least partially transparent. In order to obtain a sufficiently clear inscription with a laser beam without damaging the surface of the composite element, the transparent layer is made of a material where the transmission rate of the laser beam used for the inscription is greater than the transmission rate in the material of the second layer, and said second layer is marked through the first transparent layer with a beam of such intensity and power that it leaves the transparent layer unharmed.

Description

Method for labeling composite components with laser radiation and composite component produced using this method

description

Technical field

The invention relates to a method for labeling composite components with laser radiation, in particular for security panes, in which one of several interconnected component layers is at least partially transparent.

State of the art

Laminated glass panes are used in automobile construction and safety panes are used in apparatus construction, each of which has to be labeled with a test number. These are attached by means of a label.

Conventionally, such labeling is done either by applying a dye to the outer surface of a composite pane by screen printing, or by etching the glass pane surface with a doctor's stamp using hydrofluoric acid. By both

Mechanical contact is required, namely either the contact between the template and the composite pane to be labeled, or between the latter and the etching stamp. The etching process has the disadvantage of relatively high wear of the etching die.

It has therefore already been proposed to label glass with laser radiation using a carbon dioxide laser. The laser radiation effects the inscription by melting the glass, combined with evaporation of the top layers of material. The one that occurs

Thermal shock effects cause cracks that can reach the deeper layers of the material from the surface.

As a result, defects are created in this labeling process, in particular for highly unbreakable applications of security windows for which labeling is required

Security is mainly important, is out of the question. In addition, it has already been suggested that the inscription be blown with laser radiation, through which ablation takes place with a negligible thickness of the enamel layer and without any visible formation of heat. However, this also makes the identification of the lettering relatively poor, so that additional measures must be taken to improve the identification.

Presentation of the Invention

In contrast, the invention is based on the object of a

To improve the method of the type mentioned at the outset in such a way that sufficiently recognizable labeling with laser radiation is possible without damaging the surface of the composite component.

This object is achieved in that a material is used for the transparent component layer, the

Transmission rate for the laser radiation used for labeling is greater than the transmission rate of the material of the second component layer, and that the labeling of this second layer through the first, transparent layer with the latter leaving undamaged intensity and power parameters of the radiation.

The labeling is carried out without contact.

The laser radiation passes through the transparent component layer and acts on the second component layer, which has a lower transmission rate of its material. This is inside the composite component and is protected accordingly, so the labeling cannot be falsified. The labeling on the inside of the composite component also increases the security of the composite component by avoiding any interference with the surface of the transparent component

Component layer. It is essential for the method according to the invention that the component layers have different transmission rates for the laser radiation, so that by appropriate selection of the transmission rates and the intensity and power parameters of the laser radiation it can be determined that the latter is only effective in one of the component layers,

namely in the second structural layer, and there in the border area to the first component layer. The caption without the

Additional material is used, is and remains protected from abrasive and corrosive influences by the outer pane. Labeling the second layer with laser radiation allows intensity and performance parameters to be controlled by a computer in accordance with the respective requirements.

The first component layer is advantageously εine

Glass layer used, which has a significant transmission rate for laser radiation. This glass layer absorbs only comparatively little energy from the laser radiation, and the process can be controlled so that the absorption in the glass layer does not lead to its melting or decomposition, while the transmitted laser radiation is able to pass onto the second Component layer act. In particular, they are used for glass

Wavelengths of light from the visible range to the UV range. The selection becomes second depending on the absorption properties of the material used

Component layer hit and depending on what change or decomposition of the material is to be achieved. As such

Changes come the changes in chemical structure

in question whereby a change in the color impression is achieved by chemical conversion, or a change in the macroscopic structure, z. B. evaporation with subsequent recondensation is effected.

As a second component layer, a polymer layer is used that bonds two glass panes together. In this case, such polymer layers are crystal-clear and are known per se with regard to their composition for bonding glass. With this method, conventional three-layer laminated glass panes can be produced.

In particular, the labeling can be done after the safety window has been completed, that is, as the last step in the manufacturing process, for B. after the final inspection. This procedure ensures that the product actually has and retains the properties guaranteed by its labeling, that is to say that the labeling process ensures that the product

Properties are not affected.

A xenon fluoride eximer laser or, if necessary, a neodymium-YAG laser is used for the labeling, the wavelengths of which are in the range of high transmission or even close to a local maximum of the transmission rate for glass and thus ensure that a minimum of the radiation energy in the glass pane remains when it is irradiated.

In an embodiment of the invention, the laser radiation is pulsed and the inscription is made by decomposing the Polymer layer when using several successive pulses. As a result, the labeling can be controlled by the choice of the pulse sizes, for example by the choice of pulse height and length and by the choice of the pulse pause length. The use of laser pulses avoids overloading the irradiated layer and allows a targeted and metered decomposition of the layer to be labeled.

Furthermore, the method is advantageously carried out in such a way that the inscription is projected onto the composite component by the laser radiation using a mask with the desired imaging scale and / or

f oku s i ert he laser beam uses the deflection optics to label.

The first method with a mask is used in particular when a large number of composite components are each provided with the same lettering. The use of a focused laser beam is particularly recommended when the composite components are to be labeled differently, because a computer control can then be used to achieve the different typefaces with short cycle times. The computer control can also be used if the same image is to be used for differently designed composite components that have to be irradiated with different intensity and power parameters.

The invention also relates to a composite component made of several interconnected layers, in particular to a safety pane for automobile or apparatus construction, one of which is at least partially transparent, which is characterized in that the composite component is one of the

Transparent component layer has covered lettering, which consists of a laser radiation through the transparent Component layer changed material structure of the

irradiated material. This change affects either the chemical structure, including e.g. B. a chemical

Conversion of the material of the composite component to be labeled is to be understood to achieve a certain color impression, or a change in the macroscopic structure of the material, for example evaporation with subsequent recondensation.

Brief description of the drawings

The invention is explained in more detail with reference to diagrams shown in the drawing. It shows:

Fig. 1 shows the transmission rate T as a function of

Wavelength λ for different materials, and Fig. 2 shows the laser intensity I and the absorbed intensity I _ABS depending on the path X through different media.

Best way to carry out the invention

The different absorption properties of the materials used are important for the application of the method according to the invention. 1 shows, as the upper curve 3, the course of the transmission rate T in the range from 350 to 400 nm for glass. It can be seen that this material has a relative maximum at approximately 371 nm. The transmission rate is particularly high in this area. In comparison, the transmission rate of polymer according to curve 4 at wavelengths less than 375 nm is less than 1%, that is, the radiation is practically completely absorbed. For the method according to the invention it follows that the optimal wavelength for

Labeling is around 371 nm because the majority of the energy of the beam passes through this material, but on the other hand a thin layer of the polymer is already sufficient to cover the entire energy of the light radiation

absorb.

The 371 nm wavelength range is currently only accessible to dye lasers. In neighboring wavelength ranges, in which the transmission rate is not quite as high, for example, the xenon fluorine eximer laser can be used, which has a transmission rate of 35% at a wavelength of 351 nm, or solid-state lasers can be used, with a harmonic, e.g. . B. the third harmonic of the neodymium-YAG laser with a wavelength of 355 nm at a transmission rate of 45% in the glass.

Fig. 2 shows representations for the successive

Radiation through different layers with laser light, namely an air layer, a glass layer and a polymer layer. The

Glass layer is referred to as component layer 1 and the

Polymer layer as component layer 2. In addition, the bottom

Part of FIG. 2 shows the decomposition threshold of glass, which lies above the decomposition threshold of the polymer layer, the latter being an area, while the decomposition threshold of glass is assigned to a single I _ABS due to the fixed melting temperature.

The air does not absorb laser radiation, so the

Curve in FIG. 2 above is parallel to the X axis and coincides with the X axis in FIG. 2 below. Only little laser radiation is absorbed in glass because glass has a high transmission rate T. As a result, the intensity I drops in the

Component layer 1 only slightly. The absorbed intensity shows small and decreasing values over the thickness of the layer 1, which are below the decomposition threshold of the glass, so that the latter is not damaged. The falling values of I _ABS in glass can be explained by the decreasing intensity with increasing thickness according to FIG. 2, upper part, so that the intensity I _ABS absorbed per unit volume also decreases accordingly.

The component layer 2 has a low transmission rate T or a high absorption, so that the intensity of the radiation drops very quickly to very low values. The absorbed intensity I _ABS is correspondingly large with a peak value 5 which reaches and exceeds the decomposition threshold of polymer, so that changes in the structure of the polymer are achieved there.

To label the component layer 2 through the component layer 1, the intensity and power parameters of radiation with a suitable wavelength are set so that the different thermal properties of the materials are used. While the polymer layer or the component layer 2 is deliberately damaged, but only in a partial area of its thickness, the component layer 1 remains undamaged overall because the absorbed power is not sufficient for melting.

Commercial usability

The method according to the invention enables a sufficiently recognizable inscription with laser radiation without damaging the surface of the composite component.

Claims

1. Method for marking composite components with laser radiation, in particular for security panes, in which one of several interconnected component layers is at least partially transparent, that is to say that for the transparent

Component layer (1) εin material is used, the transmission rate (T) for the laser radiation used for labeling is greater than the transmission rate (T) of the material of the second component layer (2), and that the labeling of this second layer (2) by the first, transparent layer (1) with the latter leaving the intensity and power parameters of the radiation undamaged.

2. The method of claim 1, d a d u r c h g e k e n n z e i c h n e t that sine glass layer is used as the first component layer (1).

3. The method according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that as a second component layer (2) a two glass panes adhesive polymer layer is used.

Method according to claim 3, characterized in that the inscription takes place after the safety pane has been completed.

5. The method according to one or more of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t that a

Xenon fluoride eximer laser or a frequency-multiplied neodymium-YAG laser is used.

6. The method according to one or more of claims 1 to 5, d a d u r c h g e k e n n z e i c h n e t that the

Laser radiation is pulsed and the label is made by decomposing the polymer layer when using several successive pulses.

7. The method according to one or more of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t that the inscription using a mask with the desired imaging scale from the laser radiation to the

Composite component is projected and / or that a focused laser beam uses the deflection optics to label it.

8. Composite component made of several interconnected

Layers, especially safety window for the

Automobile or apparatus engineering, one of which is at least partially transparent, so that the composite component has a label covered by the transparent component layer (1), which consists of a material structure of the irradiated material that has been modified with laser radiation through the transparent component layer (1).