EP3867204A2 - Method for producing an electronic structure on a glass pane and glass sheet having at least one glass pane of this type - Google Patents

Abstract

The present invention relates to a method for producing an electronic structure on a glass pane (2) which has, at least on one of its two glass pane surfaces (2a; 2b), a functional coating (3) with at least one electrically conductive functional layer, preferably with multiple electrically conductive functional layers, the functional coating (3) being structured by means of laser radiation in such a way that the electronic structure, preferably a capacitive sensor system or a conductor loop, is created. The invention also relates to a glass sheet (1) having at least one glass pane (2) of this type.

Description

 Method for producing an electronic structure on a glass pane and glass sheet with at least one such glass pane

The present invention relates to a method for producing an electronic structure on a glass pane and a glass sheet with at least one such glass pane.

Flat glass is any glass in the form of disks or sheets, regardless of the manufacturing process used.

The glass panels can consist of a single glass pane or glass plate (single-pane glass) or it can be laminated glass. A laminated glass sheet is generally understood to mean a glass sheet formed from two or more glass panes or glass plates with the same or different thickness, the glass panes being connected to one another by an intermediate layer made of plastic.

In order to provide flat glass panels with filter, mirror, heating functions or other functions, a wide variety of single or multi-layer functional coatings are applied to the glass panes. The functions can e.g. Thermal protection, sun protection, or heating. With low-E glass (low-E = low emissivity = low heat radiation), one or more metal layers reduce the emissivity of the glass panes and serve as a heat and / or sun protection layer.

As a rule, the functional coating or functional coating is a single functional layer or a layer structure with several functional layers with a total thickness <2 pm. The layer structure is generally obtained by deposition processes, preferably sputtering. The individual functional layers are therefore usually metallic and / or ceramic layers. For example, it is metallic low emission layers or electrical heating layers. One or more dielectric (functional) layers, for example made of an oxide, such as aluminum oxide, can be arranged between the individual metallic functional layers of a functional coating. In addition, an adhesion-promoting layer made of tin oxide is usually present between the functional coating and the glass surface.

Special laminated glass panels have e.g. B. a first, in particular inner, glass pane from a usually un-coated glass pane and a second, in particular outer, coated, in particular provided with a heat protection layer, glass pane.

Train window panes usually have such a heat-insulating functional coating. The problem here is that the functional coating brings about energy savings, but the cell phone connection suffers as a result. Because of the metallic functional coating, a Faraday cage is formed that shields the interior of the train from electromagnetic waves. Because of this, ETH Zurich has developed a new window glass in which the functional coating has been changed so that it is more relaxed for electromagnetic mobile radio waves and light (www.20min. Ch_wissen_news_story_ETH-Superglas-macht- Handy.pdf). The Faraday cage is interrupted by processing the metallic functional layer with a laser. A structure is engraved into the metallic functional layer using the laser, with approximately 2.5% of the surface being removed.

Furthermore, a method for producing a bird protection device is known from DE 10 2014 002 644 A1. In this method, an optical structure is introduced into a transparent material, in particular glass, by using laser radiation. This can be done, for example, in that the transparent material is provided with metallic and / or color pigment-containing layers and these layers are partially removed and / or converted by means of laser radiation, so that structuring takes place. Furthermore, laser marking methods for marking glass panels are known from the two publications DE 10 2005 026 038 A1 and DE 102005025982 A1.

According to DE 10 2005 026 038 A1, a glass-like layer with metal nanoparticles is applied to the surface of the glass pane using a laser. For this purpose, a donor or carrier medium is brought into contact with the glass pane surface to be labeled and a marking is generated on the glass pane surface by laser-induced processes. The carrier medium has e.g. a PET film, which e.g. has a low-E functional coating, this having at least one metallic functional layer. For marking, a laser beam is directed onto the functional coating and, due to the laser beam irradiation, material from the functional coating is transferred from the PET carrier film to the glass pane surface to be marked. The material adheres to the glass pane surface as a glass-like matrix with metallic nanoparticles, the matrix being formed from the substances originally present in the functional layers of the functional coating. The PET carrier film remains intact.

According to DE 10 2005 025 982 A1, the low-E functional coating of a glass pane is changed in color by laser radiation in a similar manner by laser radiation so that a marking is generated.

In addition, it is known in the field of organic electronics to structure thin functional layers on glass, among other things, using a laser.

Alarm glasses are also known in the art. These are glasses that trigger an intrusion alarm system if damaged or destroyed. For this purpose, a conductor loop, the so-called alarm loop or alarm spider, i.e. a network of electrical conductors, is placed on the alarm glass or embedded in a laminated safety glass. If the alarm glass breaks, the alarm loop is cut, the current is interrupted and it alarm is triggered. The alarm loop is usually brought up and burned in by means of screen printing.

Furthermore, gesture recognition or gesture control is also known in particular in the automotive sector or for controlling household or kitchen appliances or as a light switch. Gesture recognition is the automatic recognition of gestures performed by humans using a computer. This can be done without contact. Systems are controlled without contact by spatial hand, finger or whole body movements and gestures. For this purpose, sensor systems with electrical fields are used to record or track the hand position. Leading objects, such as The human body leads to a change in the electrical fields, which is then processed accordingly by a signal processor control and a computer program.

As already explained, it is e.g. known to control the light in living rooms contactlessly using gesture control. In kitchens e.g. Kitchen glass rear walls are increasingly used as splash protection. In this case, the appropriate sensors for contactless gesture control are attached to the back of the kitchen rear wall. As a rule, these are foils or thin boards that are glued to the glass surface and contain the necessary conductor tracks.

The object of the present invention is to provide a simple and inexpensive method for producing an electronic structure, preferably in front of a capacitive sensor system or an alarm loop, on a glass pane. Another object of the invention is to provide an inexpensive glass panel with an electronic structure.

These objects are achieved by a method according to claim 1 and a glass sheet according to claim 21. Advantageous further developments of the inven tion are characterized in the subsequent subclaims. Within the scope of the invention it was found that it is possible to structure the already existing functional coating of a glass pane in regions or in a specific section or region by means of laser radiation in such a way that an electronic structure, preferably a capacitive sensor system or a conductor loop, is generated .

An electronic structure has at least one electronic component. In addition, it can have conductor tracks in a manner known per se. An electronic structure is therefore an electronic module or an electronic functional unit or an electronic circuit or an electronic component.

In the following, the invention is explained in more detail by way of example using a drawing. It shows:

Figure 1: Very simplified and schematic a section through a glass pane (single-pane glass) with a functional coating and protective layer and with a structuring device for the method according to the invention

The glass sheet 1 to be structured according to the invention (FIG. 1) is, for example, a single-pane glass sheet which has only a single or a single glass sheet 2. The glass pane 2 has two glass pane surfaces 2a, b. In addition, the glass pane 2 has a superficial functional coating 3 on at least one of its two glass pane surfaces 2a; b. The functional coating 3 has an outer functional coating surface 3a facing away from the glass panes 2.

The functional coating 3 can have one or more individual functional layers. In the case of several functional layers, it is therefore a functional layer laminate. The functional layers change certain properties of the glass pane 2 or give it certain functions. The functions can be, for example, heat protection, sun protection or heating. The functional coating 3 is preferably a wavelength-selective or low-E coating.

The functional coating 3 of the glass sheet 1 has at least one, preferably several, electrically conductive metal-containing functional layers. In addition, the functional coating 3 can have at least one electrically semiconducting functional layer. It is preferably in each case a metal or a, preferably ceramic, metal oxide layer. The metallic functional layers are preferably in oxidic functional layers, e.g. embedded in a metal oxide, preferably tin oxide, which increases transmission and durability.

In addition, the functional coating 3 can have a functional layer, preferably ceramic, metal oxide, preferably tin oxide, which is connected directly to the glass pane surface 2a; b and connects the remaining layers of the functional coating 3 to the glass pane surface 2a; b. The functional layer made of metal oxide, preferably tin oxide, thus also serves as an adhesive layer.

A metal-containing, preferably a metallic functional layer preferably has silver, copper or gold. A functional layer made of metal oxide preferably consists of tin oxide.

Of course, the ceramic functional layer does not have to consist of oxide ceramics. For example, also act as a non-oxide ceramic functional layer.

The functional coating 3 can also have at least one electrically insulating functional layer.

The functional coating 3 of the glass sheet 1 thus has at least one electrically conductive, metallic and / or at least one, preferably metalliferous, ceramic functional layer. The application of the functional layers on the glass pane 2 is preferably carried out by sputtering or wet chemical.

Furthermore, the functional coating 3 preferably has a thickness of <2 pm, preferably <1 pm. In addition, the glass sheet 1 on at least one of the two glass pane surfaces 2a, b may have a known protective coating 4 in the form of a polymer protective layer or a removable protective film. The protective coating 4 protects in particular the functional coating 3 arranged under the protective coating 4 or, if no functional coating 3 is present, the pure glass pane surface 2a; b against mechanical damage. In contrast to the functional coating 3, the protective coating 4 is completely removed before the glass panel 1 is finally used.

As already explained, the electronic structures are introduced in the method according to the invention by laser structuring of the functional coating 3.

A structuring device 5 preferably used for this purpose (FIG. 1) has a laser beam generating device 6 for generating a laser beam 7. For this purpose, the laser beam generating device 6 has a laser radiation source and an associated optical system. The laser beam 7 is focused by means of the optics. The laser beam 7 can be pivoted or deflected from an initial position in which it is oriented vertically or perpendicularly to the glass pane surface 2a; b.

The laser radiation source preferably generates a laser beam 7, the wavelength of which is 170 nm to 2 pm, preferably 300 nm to 1200 nm, particularly preferably 1000 nm to 1100 nm.

In addition, the laser radiation source preferably generates a laser beam 7, the laser power of which is particularly preferred at <500 W, preferably at <200 W is <100 W, and / or> 0.5 W, preferably> 1 W, particularly preferably> 2 W.

In addition, the laser radiation source preferably generates a pulsed laser beam 7. However, it can also generate a continuous laser beam 7.

To introduce the structures, the glass pane 1 and the laser beam 7 have to be moved relative to one another parallel to the glass pane surfaces 2a, b. Preferably only the laser beam 7 is moved. The movement of the laser beam 7 is preferably carried out by means of the optics of the laser beam generating device 6. The optics of the laser generating device 6 is preferably able to use two adjustable mirrors (scanning optics) to move the laser beam 7 in a range of e.g. 100 mm x 100 mm (scan field) to move.

In the case of laser structuring, some or all of the functional layers of the functional coating 3 are completely ablated in some areas by means of the laser beam 7, in particular evaporated or burned or changed in such a way that they are no longer electrically conductive, ie electrically insulating. If the respective functional layer is only to be modified, the radiation is therefore below the removal threshold. No material is removed during the modification. In particular, the composition of the functional layer is changed chemically and / or physically during the modification. For example, the functional coating 3 can have functional layers made of atomic silver, which are modified under the action of the laser beam 7 in such a way that the syllable agglomerates and forms nanoparticles. As a result, the functional layer made of atomic silver loses its electrical conductivity and becomes insulating. The functional layers made of atomic silver are preferably embedded in functional layers, preferably electrically insulating, designed as protective layers, for example made of metal oxide, in particular of tin oxide. The laser power and / or the wavelength of the laser beam 7 is thus adjusted depending on the desired result and depending on the functional layer to be processed.

The protective coating 4 can be removed before the laser structuring, e.g. also by means of laser radiation and / or mechanically. Or the protective coating 4 is removed during the laser structuring by the laser radiation in the area of the electronic structure by being removed by the laser radiation, preferably being burned.

The laser radiation can be radiated through the glass pane 2 through or not through the glass pane 2.

It is within the scope of the invention that layers and structures structured by means of laser radiation are combined with further layers and structures applied subsequently. In this case, the functional coating 3 is structured as described above by means of laser radiation, so that an electronic structure, for example a conductor loop, is generated. Then at least one further electronic structure, for example one or more conductor loops, is applied to the structured area or to the structure produced, preferably by printing or by laser sintering, for example using the method according to DE 10 2006 040 352 B3. In the event that there is no protective coating on the glass pane or on the electronic structure produced by means of laser radiation, the additional layers and / or structures are preferably applied using the method according to DE 10 2005 026 038 A1. This means that functional layer material is printed from a donor or carrier medium by means of laser radiation onto the surface of the glass pane with the structure already created. For this purpose, the carrier medium having a surface functional coating made of the functional layer material is brought into contact with its coated side with the area to be printed on the glass pane. brings. Then, by means of the laser radiation focused on the functional coating, the functional layer material from the functional coating is transferred onto the glass pane, in particular onto the outwardly facing, already generated electronic structure or onto the structure and at least partially the functional coating (3) and / or glass surface, and fixed on this. By absorbing the laser radiation from the functional layer material, it is detached from the carrier medium and conveyed onto the glass pane.

In the event that a protective coating 4 is provided on the glass pane or on the electronic structure generated by means of laser radiation, the additional layers and / or structures are preferably applied using the method according to DE 10 2018 207 181 A1. That is, the protective coating is removed by means of laser radiation, preferably burned or burned away, and in the same operation, functional layer material is printed from a donor or carrier medium by means of the laser radiation onto a exposed surface of the glass pane which was previously coated under the protective coating Glass pane. In this case, the surface of the carrier medium having a superficial functional coating made of the functional layer material is brought into contact with the protective coating of the glass pane in the area to be printed. Then the protective coating is removed by means of the laser radiation and, as described, the functional layer material is transferred from the functional coating onto the glass pane, in particular onto the outwardly facing, already generated electronic structure or onto the structure and at least partially the functional coating (3) and / or glass surface and fixed on it.

In both of the methods described for producing additional layers and / or structures, a laser beam is preferably generated, the wavelength of which is 190 nm to 12 pm, preferably 500 nm to 2 pm, and / or the laser power is <20 W, preferably <10 W, and / or> 0.5 W, preferably> 5 W. The donor or carrier medium is preferably a coated plastic film, preferably made of PET. The carrier medium is preferably band-shaped. The carrier medium has the functional coating made of functional layer material, which has at least one metal-containing, preferably metallic, functional layer and / or the at least one ceramic functional layer. By combining with subsequently applied layers and structures, the functional coating present on the glass pane or the structure produced by means of laser structuring is supplemented, so that a combined electronic structure is produced which has a total of more functional layers than was originally contained in the functional coating. In this way, the areas or structures structured according to the invention can be supplemented or expanded, for example in the form of a subsequently applied contact pad, in such a way that a multi-layered overall structure with several layers one above the other, including insulating layers, is formed. The advantage of the method according to the invention is that an electronic structure or a sensor field on the glass pane 2 can be produced in a simple and inexpensive manner. Because only the full-surface functional coating 3 already present on the glass pane 2 must be structured using laser radiation. There is no additional application, in particular printing, of the electronic structure.

As a result, alarm glass panels can be produced in a very simple manner, for example, by the alarm loop or alarm spider being generated by laser structuring of the functional coating 3. The glass pane can also be provided with a large-area proximity sensor, which when approached causes a light to come on or an alarm to be triggered.

Capacitive sensor systems for operating household or medical devices, for example on kitchen rear glass panels for the production of a kitchen rear wall, can also be produced. Furthermore, openings in the functional coating 3 are created by removing the functional layers, which can also be used for the design, for example in interior elements. For example, it is possible to design these openings as symbols, to backlight them and thus to show the operator the area of a gesture sensor system as a "control room".

The functional layers are produced by the glass manufacturers with the purpose of a specific function, for example thermal insulation. The possibility of locally changing individual properties of the layers that are not actually used for the primary application (eg thermal insulation) with the laser tool in order to achieve additional properties in the overall product is not obvious. Rather, it was only through the provision of suitable laser tools (in recent years) and the trend of increasing the comfort of construction products (keyword: smart home) that the tool base and the need for “more” functions in window panes, for example, emerged. This led to the question: How can you integrate more functions in a cost-effective manner in windows? One solution is to implement laser structuring with the aim of changing the properties by local changes in properties - without significantly damaging the original primary function of the layers (eg thermal insulation)! It is also within the scope of the invention to introduce the structures into a glass pane 2 of a laminated glass sheet made from a plurality of glass panes 2 connected to one another (not shown). In this case, the structuring can be produced both on an outer glass pane surface 2a; b and on an inner glass pane surface 2a; b, provided that it has a functional coating 3. Execution example:

According to the invention, an alarm loop is produced on a single-pane glass (ESG) with a low-E coating in that the low-E layer is decoated inversely by the laser beam, a conductor loop being generated between two insulation lines using the following parameters:

Wavelength of the laser beam 1064 nm,

 - track width 100 gm,

 Length of the track about 50 mm, and

 Electrical resistance of the track about 12 ohms. The conductor loop is subjected to voltages <24 V in the building. Shatters the glass, e.g. in the event of a break-in, the current flow through the conductor loop is interrupted and an alarm is triggered.

Claims

Expectations

1. A method for producing an electronic structure on a glass pane (2) which has at least on one of its two glass pane surfaces (2a; b) a functional coating (3) with at least one electrically conductive functional layer, preferably with several electrically conductive functional layers, having,

 characterized in that

 the functional coating (3) is structured by means of laser radiation in such a way that the electronic structure, preferably a capacitive sensor system or a conductor loop, is generated.

2. The method according to claim 1,

 characterized in that

 during laser structuring, some or all of the functional layers of the functional coating (3) can be completely removed, in particular vaporized or burned, by means of a laser beam (7).

3. The method according to claim 1 or 2,

 characterized in that

 in the laser structuring, individual or all electrically conductive functional layers of the functional coating (3) are modified in some areas by means of a laser beam (7), in particular chemically and / or physically changed, so that they are electrically insulating.

4. The method according to claim 3,

 characterized in that

 Functional layers made of atomic silver, in particular embedded in functional layers designed as protective layers, preferably made of

Metal oxide, such as tin oxide, are changed so that the silver atoms agglomerate and form nanoparticles, so that the functional layers made of atomic silver lose their electrical conductivity. 5 Method according to one of the preceding claims,

 characterized in that

 a laser beam (7) with a wavelength of 170 nm to 2 pm, preferably from 300 nm to 1200 nm, particularly preferably from 1000 nm to 1 100 nm, and / or with a laser power <500 W, preferably with a laser power <200 W, particularly preferably with a laser power <100 W, and / or with a laser power of> 0,

5 W, preferably with a laser power of> 1 W, particularly preferably with a laser power> 2 W, is used.

6. The method according to any one of the preceding claims,

 characterized in that

 the glass pane (2) has a protective coating (4) covering the functional coating (3), which is removed, in particular burned, by means of laser radiation in the region of the electronic structure to be produced, and the electronic structure is generated in the same operation by means of the laser radiation.

7. The method according to any one of the preceding claims,

 characterized in that

 a pulsed laser beam (7) or a continuous laser beam (7) is used ver.

8. The method according to any one of the preceding claims,

 characterized in that

 the electronic structure is produced on a single-pane glass sheet (1) or a glass sheet (2) of a laminated glass sheet.

9. The method according to any one of the preceding claims,

 characterized in that

the functional layer is a metal layer or a, preferably ceramic, metal oxide layer.

10. The method according to any one of the preceding claims,

 characterized in that

 the functional coating (3) is a low-E coating.

11. The method according to any one of the preceding claims,

 characterized in that

 the laser radiation is radiated through the glass pane (2) through or not through the glass pane (2).

12. The method according to any one of the preceding claims,

 characterized in that

 a focused laser beam (7) is used.

13. The method according to claim 12,

 characterized in that

 the laser beam (7) is focused on the coated glass pane surface (2a).

14. The method according to any one of the preceding claims,

 characterized in that

 the functional coating (3) has an electrically semiconducting functional layer and / or an electrically insulating functional layer.

15. The method according to any one of the preceding claims,

 characterized in that

at least one further electronic structure is applied to the electronic structure generated by the functional coating (3) by means of laser radiation, so that a related electronic structure is generated.

16. The method according to claim 15,

 characterized in that

 the electronic structure generated by means of laser radiation is supplemented with at least one further electronic structure, so that a combined electronic structure is produced, the total more

Has functional layers than were originally contained in the functional coating (3).

17. The method according to claim 16,

 characterized in that

 the at least one further electronic structure is applied in such a way that a multilayered overall structure with a plurality of layers lying one above the other is formed.

18. The method according to any one of claims 15 to 17,

 characterized in that

 to apply the at least one further electronic structure

Carrier medium, preferably a, in particular tape-shaped, carrier film, which has a surface functional coating of functional material with at least one metal-containing and / or at least one ceramic functional layer, is provided, and by means of laser radiation the functional layer material of the functional coating of the carrier medium in the form of the further ones to be applied Structure is transferred to the previously generated electronic structure and, if necessary, to the glass surface and / or the functional coating (3).

19. The method according to any one of claims 15 to 17,

 characterized in that

the glass pane (2) has the protective coating (4) and to bring on the at least one further electronic structure a carrier medium, preferably a, in particular band-shaped, carrier film which has a surface functional coating made of functional material has at least one metal-containing and / or at least one ceramic functional layer, is provided, and the protective coating (4) in the area of the at least one further structure to be applied is removed by laser radiation, in particular burned, and in the same operation the functional layer material of the functional coating of the carrier medium in the form of the at least one further structure to be applied to the previously generated electronic structure exposed by the removal of the protective coating (4) and, if appropriate, to the glass surface and / or the functional coating (3) by means of the laser radiation.

20. The method according to claim 18 or 19,

 characterized in that

 the laser radiation is absorbed by the functional coating of the carrier medium in such a way that the functional layer material is blasted off the carrier medium and conveyed onto the surface of the glass pane (2) to be coated, the protective coating (4) preferably being removed by the energy released during the blasting will.

21. Glass sheet (1) comprising at least one glass pane (2) which has a functional coating (3) with at least one electrically conductive functional layer, preferably with several electrically conductive functional layers, on at least one of its two glass pane surfaces (2a; b),

 characterized in that

the glass pane (2) has an electronic structure, preferably a capacitive sensor system or a conductor loop, which is generated by laser structuring of the functional coating (3).

22. glass sheet (1) according to claim 21,

 characterized in that

 the electronic structure is generated according to the method according to one of claims 1 to 1420.

23. glass sheet (1) according to claim 21 or 22,

 characterized in that

 the glass panel (1) is an alarm glass panel which has an electronic structure in the form of an alarm loop or in the form of a proximity sensor, in particular a large area.

24. glass sheet (1) according to claim 21 or 22,

 characterized in that

 the glass panel (1) is a kitchen rear wall glass panel for the production of a kitchen rear wall, which has an electronic structure in the form of a capacitive sensor system.

25. glass sheet (1) according to claim 21 or 22,

 characterized in that

 the glass panel (1) is provided on a household or medical device and has an electronic structure in the form of a capacitive sensor system for operating the kitchen or medical device.

26. glass sheet (1) according to any one of claims 21 to 25,

 characterized in that

 the glass sheet (1) is a single-pane glass sheet or a laminated glass sheet.