DE102008040636B4 - Glass ceramic plate whose operational underside is provided with a coating and method for applying the coating - Google Patents

Abstract

Glass ceramic plate, the operational bottom is provided with a baked coating, characterized in that the coating consists of a sintered glass ceramic Engobe.

Description

The The invention relates to a glass ceramic plate whose operational Bottom is provided with a baked coating.

The The invention further relates to a method for applying the Coating.

in the In particular, the invention relates to a thermal operation highly loaded, underside coated glass ceramic plate, preferably on a glass ceramic plate, which serves as a cooking surface in a hob. With reference to this preferred embodiment the problem which underlies the invention is exemplary explained.

modern kitchens typically have hobs with a glass ceramic plate as Cooking surface. Without additional activities is such a glass ceramic plate with predominantly high quartz mixed crystals both for IR radiation as for that visible light transparent. The view into the interior of the cooking appliance, z. B. on the heaters, the printed circuit boards, etc., but is undesirable for aesthetic reasons. Around in plan view to prevent the view of the hob inside is typically the glass from which the precursor glass plate to be ceramized, also green glass plate is prepared, dyed in the melt, d. H. volume-colored. It thus appears dark in the plan view to black, d. H. guaranteed so the necessary opacity. The identification of the cooking zones the hobs are indicated by a corresponding mark the top of the hob, z. B. by printing with circles or similar.

It has been increasing for several years Efforts to use glass ceramic plates as cooking surfaces, in contrast to the aforementioned classic transparent, volume-colored glass ceramic plate formed as a transparent, not volume-colored glass ceramic plate For example, to enable the integration of high-resolution displays in the cooking surface. To achieve the necessary opacity here, get the for the visible light transparent glass ceramic plates in a known manner an opaque underside coating that is in the display area is omitted.

The classic, volume-colored dark to black seeming glass ceramic cooking surfaces have in a known manner top and bottom decorative coatings on. At the not volume-colored Glass-ceramic cooktops The opaque underside coating can be decorative at the same time be educated. But it is also conceivable on the operational level Top in addition to provide a decorative layer.

At the coatings on the aforementioned glass ceramic cooking surfaces are made special demands by the high thermal load. You need to the temperatures to which they are exposed and the operational can be several hundred degrees as well as the permanent ones Temperature changes for long time, d. H. For withstand the entire service life.

The aforementioned coatings on glass ceramic surfaces have become known in various embodiments and compositions, for. B. a Glasflussbasierte coating BE 1008882 A , Due to the peculiarities of the glass ceramic, in particular its zero thermal expansion, it is very difficult to apply to the underside a coating based on a glasflußbasierenden, pigmented ceramic paint, in which at the same time an opaque layer is obtained and the strength of the glass ceramic is maintained.

In the DE 102 43 500 A1 Such a glass flow-based, provided with inorganic pigments underside coating is described, in which both the opacity of the layer is ensured and the strength of the glass ceramic is maintained. This is achieved in the known case in that the glass flux content of the ceramic paint in the range of 1-30% and the pigment content is correspondingly in the range of 70-99%. Due to the high pigment content, the layers obtained in this way have a high opacity and, because of the low glass flux content, a good temperature resistance and a very good adhesive strength. However, it has been found that other requirements that must be placed on such a bottom coating, such as the scratch and abrasion resistance during transport and installation of such glass ceramic plates are not met.

Other bottom coatings are z. B. in the DE 100 14 373 A1 described. Here are as possible underside coatings, inter alia, precious metal preparations, chandelier colors and sol-gel colors genant. While with chandelier colors and precious metal preparations actually very high quality layers with excellent performance characteristics are obtained in the hot area, the sol-gel colors show the increased requirements for a bottom coating in the hot area, especially the preservation of the glass strength at high thermal stress above 500 ° C. grown. However, the appearance of layers of luster colors and precious metal preparations is limited to the range of smooth, homogeneous and partly metallic reflecting layers, the optically more attractive Metallicanmutungen can not be realized in this way.

Pigmented sol-gel layers are also from the DE 103 13 630 A1 known.

In the DE 101 33 478 C1 a coating on a glass-ceramic plate is described, in which fine particles of hard material are randomly distributed over the surface of the glass-ceramic plate in the surface thereof or embedded in an intermediate layer. These hard material particles are preferably applied by plasma spraying. An admixture of certain coloring oxides in order to give the resulting layer a slight color cast is possible to a limited extent. However, such a layer is typically suitable for coating the upper side of a glass ceramic plate, in particular a glass ceramic cooking surface. This has two reasons. When applying the hard material particles by means of plasma spraying, there is generally a violation of the substrate by the partial melting of the surface of the glass ceramic and thereby a lowering of the glass strength. Also, the application of a thin intermediate layer of a Borosilikatglasfluß into which the hard particles can be embedded particularly well, leads to the bottom of a cooking surface to a significant reduction in strength, so that this approach is applicable only for a top coating of the glass ceramic plate. On the other hand, the abovementioned coatings can not be used as opaque underside coatings of a transparent, non-volume-colored glass ceramic plate, since, on the one hand, only slight shades of color can be realized and, on the other hand, only non-opaque, ie, non-opaque layers, can be realized.

Of the Invention is based on the object for the above-mentioned glass ceramic plates to provide a bottom coating that is also in the hot area of thermally highly stressed glass ceramic cooking surfaces, d. H. especially for the widely used radiant-heated glass ceramic cooktops used can be, and which thereby the plate strength is not negative influenced, and in the case of the underside coating, a transparent, not volume-colored Glass ceramic plate also allows the realization of a metallic look and while having a high scratch and abrasion resistance.

The solution This object is achieved in a glass ceramic plate whose operational Bottom is provided with a baked coating according to the invention in that the coating as a sintered layer, based on a glass ceramic Engobe, is formed.

at a classic engobe is a clay mud that applied to unfired ceramic cullet and after drying in the so-called Endbrand is firmly connected to this. As a sintering gobe one designates an embodiment Engobetechnik, in which the clay sludge additionally color body in Form of high-temperature-stable pigments and glazing elements be added. In this case, the resulting coating also fulfills the function of a glaze and has a slightly shiny surface.

in the Case of the present invention is under a glass ceramic Engobe understood a coating material made of finely ground green glass and comparable to the glass flow of a conventional one ceramic color as a binder of the coating, d. H. as a color basis acts, and optionally with one or more high temperature stable Color and / or effect pigments is offset. Under green glass understands you have a glass that is going on of the baking process into glass ceramic.

at When the engobe is burnt in, the green glass is transformed into glass ceramic that the finished product of a glass ceramic plate with a Coating consists of a sintered glass ceramic engobe.

Substrates coated with an engobe containing effect pigments are by themselves DE 695 26 050 T2 known. The use of classical ceramic engobes for the production of decorative and functional coatings on bricks, clay and ceramic goods is also out DE 198 59 420 A1 known, another ceramic, made by polysiloxanes suitable for the electrostatic powder application engobe is made EP 0 442 109 A1 known. However, in the known cases, there is neither a glass-ceramic engobe nor a glass-ceramic substrate.

Since both the coating and the glass ceramic plate both have very similar expansion coefficients, it comes with a thermal stress of the glass ceramic plate, as z. B. is typical for use of the glass ceramic plate as a cooking surface, ie up to 750 ° C in peak loads, unlike conventional glass flow-based colors or sol-gel colors not to break the layer by the large difference in the thermal expansion coefficient of layer and glass ceramic plate. As a result, in particular the reduction of the glass strength is prevented by the underside coating, since no cracks from the bottom coating in the bottom of the glass ceramic plate can continue into it. Rather, by a clever choice of the glass ceramic material in the coating rather still a compressive stress on the glass ceramic plate to be coated are constructed, so that Overall, even an increase in glass strength can result. However, it is preferred if the coefficients of thermal expansion of glass ceramic and engobe layer are approximately equal, ie differ by a maximum of 1.2 · 10 ^-6 K ^-1 .

A bottom coating based on a glass-ceramic engobe may be used as necessary, strength-increasing coating on both a colorless transparent glass ceramic as well as a colored glass-ceramic, such as ceramic or ceramic Suprema Hightrans ^{® ®.} In an uncolored transparent glass ceramic plate, it serves primarily as opaque and highly scratch and abrasion resistant coating. In addition, it may also be formed as a decorative layer.

Farther can be achieved by the glass ceramic Engobe a reduction in IR transmission. Some glass-ceramics have a very high permeability for IR light which is radiated by the radiant heaters. In these cases, the directly to the cooking surface adjoining kitchen environment Danger of overheating. A corresponding test is in the standard EN 60335-2-1 (black corner) described. An underside applied, particle-containing layer can emit the light emitted by the radiant heater to all sides to scatter. Part of the light becomes after repeated distraction absorbed by the layer and no longer enters the adjacent Kitchen environment. This heats up in the episode not so strong. specified allowed Maximum temperatures are thus not exceeded.

If the glass-ceramic engobe is pigmented with an effect pigment, in particular with a pearlescent pigment or a metallic effect pigment, a metallic appearance of the glass-ceramic cooking surface can be achieved. Such pearlescent pigments or metallic effect pigments are known per se and are marketed by many manufacturers. They usually consist of platelets of mica, SiO ₂ or Al ₂ O ₃ , which are coated with thin layers of titanium dioxide or iron oxide. The interplay of refraction, reflection and interference results in the effects of gloss and color, ranging from silver-white and colored pearlescent effects to interference pigments in silver, gold, red, blue and green. The coating with Fe ₂ O ₃ leads to copper and red effect pigments. Such effect pigments are sold, for example on the basis of Al ₂ O ₃ in the range Xirallic ^® by the company Merck KGaA. However, due to the light-scattering effect of the engobe, the metallic effect is only weaker.

In the colored so-called "black" glass-ceramics, such as. As the above-mentioned glass ceramics Ceran Hightrans ^® and Ceran Suprema ^® , such an opaque underside coating additionally has a further covering effect. It has been shown that when lighting the glass ceramic plate from above, z. B. with halogen lamps, which are arranged above the hob, partially components of the hob, which are mounted below the glass ceramic plate, are disturbingly visible. By such a bottom coating by means of a glass-ceramic engobe in addition to the strength-increasing effect so even a covering effect is possible. Through a particle-containing layer on the underside, the incident light is scattered on all sides. It can thus no longer be scattered by the components of the hob, so that they are no longer visible through a translucent glass ceramic even under unfavorable lighting conditions. At the same time the overall black color of the glass ceramic is deepened by such a deposit, so that a particularly beautiful, deep black appearance is obtained.

The Invention, as mentioned above, also a method for Production of a glass ceramic plate, whose operational underside is provided with a baked coating, which as on a glass-ceramic engobe-based sintered layer is formed is.

• • Bereitstellen einer keramisierbaren Grünglasplatte
• • Bereitstellen einer Engobe aus fein gemahlenem, mit Keimbildnern versehenem keramisierbaren Grünglas als Schichtbasis für die glaskeramische Engobe
• • Aufbringen der Grünglas-Engobe auf die betriebliche Unterseite der zu keramisierenden Grünglasplatte in einer vorgegebenen Schichtdicke
• • Keramisieren der Grünglasplatte mit der aufgebrachten Beschichtung aus der Grünglas-Engobe zu der Glaskeramikplatte mit einer als glaskeramische Engobe ausgebildeten Sinterschicht.

The associated object mentioned above is achieved according to the invention with the method steps:

• Providing a ceramizable green glass plate
• • Providing an engobe of finely ground, ceramizable green glass as a layer base for the glass-ceramic engobe
• Applying the green glass engobe to the operational underside of the green glass plate to be ceramized in a predetermined layer thickness
• Ceramifying the green glass plate with the applied coating from the green glass engobe to the glass ceramic plate with a sintered layer designed as a glass-ceramic engobe.

• • Bereitstellen einer zu beschichtenden Glaskeramikplatte
• • Bereitstellen einer Engobe aus fein gemahlenem, mit Keimbildnern versehenem keramisierbaren Grünglas als Schichtbasis für die glaskeramische Engobe
• • Aufbringen der Grünglas-Engobe auf die zu beschichtende betriebliche Unterseite der Glaskeramikplatte in einer vorgegebenen Schicht,
• • Aufsintern der aufgebrachten Grünglas-Engobe-Schicht unter Keramisieren der Grünglas-Engobe.

Alternatively, the object can also be achieved by a method comprising the steps:

• Providing a glass-ceramic plate to be coated
• • Providing an engobe of finely ground, ceramizable green glass as a layer base for the glass-ceramic engobe
• Application of the green glass engobe onto the operational underside of the glass-ceramic plate to be coated in a predetermined layer,
• • sintering the applied green glass engobe layer to ceramize the green glass en gobe.

The finely ground green glass the engobe and the green glass substrate to be coated glass ceramic plate or to be coated Glass ceramic plate can either have the same composition, so during the Firing of the coating when using a green glass substrate expediently during the Keramisierungsprozesses takes place, the same glass ceramic is formed, or have a different composition. The latter can especially advantageous if certain color effects achieved to be or the strength of the glass ceramic plate by targeted Differences in the expansion coefficient between different glass ceramics should be increased.

The finely ground green glass has a particle size of up to to 10 μm, preferably 1 μm up to 5 μm, in particular 1 to 3 microns.

Different as with conventional Glass-flow-based enamel paints occur in the coatings according to the invention based on a glass ceramic engobe not to melt the Binder, so the finely ground green glass. Although it does not belong to any Melting of the fine green glass particles comes in the engobe, but the particles merely sintered (the glass-ceramic particles of the engobe become in the surface of the Sintered glass ceramic plate or form with each other Together, a layer composite of), becomes this way obtained a very adherent, scratch-resistant coating.

The Layer thickness of the baked engobe can be up to 100 μm, usually amounts to they are 5 to 70 μm, in strongly covering engobes preferably find layer thicknesses of 20 up to 70 μm Use.

During the Ceramization process, the green glass engobe changes as well as the coated green glass plate into a glass ceramic. Particularly preferred is the ceramization so controlled that both the finely ground green glass and the substrate be converted into a high quartz mixed crystal glass ceramic. Indeed it is also possible to operate the transformation until the keatite phase. Will the ceramization special driven selectively, it is possible that z. B. the resulting from the finely ground green glass glass ceramic the Engobe already as Keatitglaskeramik, the former green glass plate, but still present as a high quartz mixed crystal glass ceramic or vice versa. Will both the green glass in the engobe as well as the green glass plate each converted into high quartz mixed crystal glass ceramic, it is surprising obtained a clear glass ceramic with an opaque coating, and even if the engobe does not have any coloring or scattering pigments have been added.

In a preferred embodiment the engobe is pasted with a standard screen printing medium and applied by the screen printing process.

The Ceramization of green glass takes place in decades known manner in a Termperaturbereich from about 750 to 1200 ° C (Crystallization temperature). The formation of crystal nuclei occurs also known for decades, at temperatures of about 700 ° C to 800 ° C. At very finely ground green glass, like this one for used the engobe, is a previous nucleation in that too grinding green glass usually not required because of this glass powder by the Grinding process has sufficient amounts of impurities in the particles, from which a spontaneous crystallization can emanate.

at the background printing of a transparent, not volume-colored green glass plate Fulfills the glass-ceramic engobe in particular the functions of a binding agent for coloring and / or effect pigments. In this way, over 750 ° C high temperature stable decorative Bottom coatings realized in attractive "metallic design" be without the thermal stress critical properties the resulting cooking surface as the strength or scratch and abrasion resistance of the coating in Would be affected.

A further application possibility the underside coating based on a glass ceramic engobe is in use as a transmission-reducing layer in the IR range. For especially IR-transparent glass ceramics Under certain conditions, it may cause excessive heating of the product Coming to the cooking zone. Here it is necessary by additional activities In critical areas, the IR transmission targeted by a few percent herabzusenken. Is on such a glass ceramic plate a glass ceramic Engobe applied, it comes to a significant reduction in the IR transmission, which can be adjusted according to layer thickness and occupancy level.

The coating with a glass-ceramic engobe is associated with various advantages. Thus, an increase in strength of the glass ceramic plate can be achieved, the visual impression of the glass ceramic plate can be adapted to changing needs and the coating can be burned during the ceramization of the glass ceramic plate simultaneously with the top coating because the engobe does not melt and thus does not stick to the transport pad and thus the green glass plate lying on the engobe side can be transported through the ceramizing furnace. This can be compared to a separate penetration a significant energy savings.

Claims (15)

Glass ceramic plate, the operational bottom is provided with a baked coating, characterized in that the coating consists of a sintered glass ceramic Engobe. Glass ceramic plate according to claim 1, characterized that the glass compositions and in particular the thermal Expansion coefficients of the glass ceramic plate and the glass-ceramic Engobe approximate are the same. Glass ceramic plate according to claim 1, characterized that the glass compositions of the glass ceramic plate and Engobe are different, in particular, that the thermal expansion coefficient the glass-ceramic engobe layer is smaller than that of the coated one Glass ceramic plate is. Glass ceramic plate according to one of claims 1 to 3, characterized in that the glass-ceramic engobe layer is pigmented. Glass-ceramic plate according to claim 4, characterized that the glass-ceramic engobe layer has high-temperature-stable pigments, in particular inorganic pigments. Glass ceramic plate according to claim 4 or 5, characterized characterized in that the pigments by effect pigments, preferably Metal effect pigments or pearlescent pigments are formed. Glass ceramic plate according to one of claims 1 to 6, characterized in that the engobe layer has a thickness of up to 100 μm has. Glass-ceramic plate according to claim 7, characterized the engobe layer has a thickness of from 5 to 70 μm. Method for underside coating a glass ceramic plate according to one of the claims 1 to 8 with the steps: • Provide a ceramizable green glass plate • Provide an engobe made of finely ground ceramizable ceramics green glass as a layer basis for the glass ceramic engobe • Apply the green glass engobe on the operational bottom of the green glass plate to be ceramized in a given layer thickness • Ceramicizing the green glass plate with the applied coating from the green glass engobe to the glass ceramic plate with a sintered layer designed as a glass-ceramic engobe. Method for underside coating a glass ceramic plate according to one of the claims 1 to 8 with the steps: • Provide a glass ceramic plate to be coated • Provide engobe made of finely ground, with nucleating ceramizable green glass as a layer basis for the glass ceramic engobe • Apply the green glass engobe on the operational underside of the glass-ceramic plate to be coated in a given layer, • Sintering the applied Green Glass Engobe Layer Under Ceramicizing the green glass engobe. Method according to claim 9 or 10, characterized that you have a ground green glass with a grain size of maximum 10 μm used. Method according to claim 11, characterized in that that you have a green glass with a grain size of 1-5 microns, in particular of 1-3 μm used. Method according to claim 9, 11 or 12, characterized that both the green glass engobe as well as the green glass plate converted into a glass ceramic with predominantly high quartz mixed crystals become. Method according to claim 9, 11 or 12, characterized that the green glass engobe and the green glass plate converted into a glass ceramic with different crystal phases become. Method according to one of claims 9 to 14, characterized that the green glass engobe pasted with a standard screen printing medium and by means of the screen printing process is applied.