FI81081C - Large size ceramic tile with mounting elements on the back - Google Patents

Abstract

1. A large-format ceramic tile with holding elements provided on its side facing away from the visible side, characterized by the attachment of the holding elements (4, 24) to joining points determined according to static requirements by means of a ceramic glaze (3) whose thermal expansion coefficient is at least approximately equal to that of the ceramic tile (1).

Description

1 81081

Large ceramic plate with full members attached to the back

The invention relates to a large-size ceramic tile with 5 with the given side opposite to the side clamps.

It is known to fasten the fastening parts to the back of ceramic tiles with an organic adhesive or a cement adhesive with organic binders. Such LH-10 mat expire, however, relatively fast, and in particular vanhenemistila is optically not admissible, because the holders are arranged on the opposite side to the visible side.

When using such panels, for example in the external cladding of public buildings, therefore, only a maximum size of 0.1 m2, e.g. 30 x 30 cm, is allowed.

The state of the art also includes fixing ceramic tiles used for cladding facades or the like by means of hook-like parts adhering to the edge. The edge-20 support only allows for relatively small sizes, e.g. 60 x 60 cm, because the load support can only take place at equilibly unfavorably fastening points at the edge, i.e. very large voltage peaks occur during point-to-point installation.

25 The mere plastering of such tiles is, of course, practically useful, but it cannot be used to provide façade cladding with air-conditioning ducts and / or thermal insulation. Also, the replacement of potentially damaged tiles 30 is only possible at the highest cost.

Thus, no large panels could be placed with the known fasteners which could be used to obtain a more beautiful and appropriate façade or cladding shape, even if relatively thin large ceramic tiles 2 81 081 made by Applicant 35 with dimensions up to 125 x 180 cm and 8 mm thick were used. still relatively light due to their low thickness.

The object of the invention is to manufacture tiles, the fastening parts of which ensure that the requirements for a balanced stable fastening of the tile are met, regardless of how the tiles are to be arranged on the basis of the structural space.

According to the invention, the solution to this problem is to fasten the fastening parts 10 to the joints determined by the balance requirements by means of a ceramic glaze whose coefficient of thermal expansion is at least almost the same as the coefficient of thermal expansion of the ceramic tile.

With such tiles, the fastening problem of the rat-15 lane can be very simple. The same coefficient of thermal expansion in the glazing and the tile material making the joint prevents the formation of tears during temperature fluctuations. Such tears are particularly dangerous in exterior cladding under weather conditions, as rain penetrating the cracks can damage the joint or even fragment it due to freezing.

Suitable fastening parts are the fired ceramic parts, which act as such immediately for fastening the plate or also for taking up the metal fastening means 25. In the latter case, the material for the fastening means can then be chosen completely freely.

However, it is already known from DE-A-22 666 to coat tiles made of good porous clay on one side with a glaze after drying and then to place them in pairs on top of each other with a flat glazed surface so as to form a double tile. The double tiles are fired, in which case the individual tiles are joined together with glaze. However, the individual tiles are not fired tiles, but fresh l; 3 81 081 of tiles which, after drying, are covered on one side with glaze and then placed on top of each other, whereby the tiles and glaze are placed under the firing stage.

It is further known from DE-A-461 224 to connect ceramic objects, in particular insulating parts or the like, in such a way that, when both parts are fused together, the fusible joint surfaces are provided with breaks. But the purpose of this type of melting is only 10 to provide flexibility against mechanical stress despite the joint brought by the melting. As is known, the fusing material is applied to fresh pieces before firing.

In the further development of the invention, using glass-15 having a melting point below the quartz transformation point (573 ° C), whereby the fired ceramic tile placed with the corresponding fired fasteners is once again heated to a temperature below the quartz transformation point, the principle of the invention can also be applied to this does not suffer from the re-burning of tiles with fasteners because its melting point is not reached.

In order to avoid heating the entire tile to the melting point of the glaze, it is proposed in a further embodiment of the invention to immerse in the ceramic glaze a perforated power supply surface element of metallic than ceramic glaze. In this way, it is possible to heat only the device and the fastening part and the tile in the area of the locally applied glaze and thus to reach the desired melting connection between the tile and the holder. The surface element is considered to be both 4 81 081 film-like elements and also a network or meander, provided that there are sufficient holes through which the glaze can enter.

There are materials on the market with the required properties 5 and also a temperature coefficient of electrical resistance between 20 ° C and 600eC greater than 2, e.g. under the trademark VACON, and they are offered as melting alloys for electronic tubes. The holders may be provided with recesses or holes for receiving a metal fastening means, which substantially facilitates the introduction of the tile according to the invention thus formed into, for example, frames, etc. These metal fastening means are of course inserted during post-firing to connect ceramic holders and ceramic tiles through ceramic glaze. they cannot be damaged because this post-combustion temperature is relatively low. The resulting shape connection between the ceramic holder and the metal fastening means reliably centralizes the load machining.

20 Of course, afterburning can also take place without such a metal fastening means, if the recess or hole is formed in such a way that it is possible to insert the metal fastening means into the holder afterwards. Such fastening means then come into question, for example, spacers, reinforcing needles, spacers and the like.

The invention can also be implemented in such a way that the holder itself forms a fastening part and can be connected to the power supply as such. It then consists of a metallic material having a high electrical resistivity and a melting point well above the melting point of the ceramic glaze and having a coefficient of thermal expansion almost equal to that of the ceramic glaze.

The same applies to the ingredient used as stated above in connection with the surface element.

5,881,081

In a further development of the invention, the plate is lightly lowered at the joints of the holders on a surface corresponding to the floor plan of these elements, for example by grinding. Thus, an additional attachment of the ceramic holders in the direction of the surface of the plate-5 is obtained in the manufacture of the ceramic tile according to the invention.

Instead of being provided with a plate to be visible from the opposite side of the side of the recess may alternatively be provided with clamps to the plate side surface 10 of the recess. Then there is a stepped residual surface, which does not specifically settle on the slab, but is at a minimum distance from it. This gap is sealed with an aging-resistant adhesive applied after the joint firing, which consists of a material that prevents the effects of the atmosphere and is removed from the road.

The invention thus provides tiles which can be immediately attached to walls, ceilings, support racks or the like, in which the joints can be freely chosen according to balance considerations. In one embodiment 20, the plates and holders are formed as well as possibly also the fastening part from the same raw material; thus a coherent part is created. It provides the same coefficient of thermal expansion and the same strength properties in the area of fastening of the brackets. Even when the fastening means is metal, it does not change anything in the formation of a unitary piece formed of the plate and the holder. In another embodiment, there is the advantage that the ceramic holder can be dispensed with.

Since the connection of the holder or fastening means and the plate takes place with the glaze in a temperature range below 30 quartz change points, both the holder or fastening means as well as the ceramic tile and also the glaze applied to the visible side of the ceramic tile remain completely unchanged. Brackets or means for fixation device, not at the side, but the parts that are visible on the other side of the plate 35, the side that give June 81 081 balanced closed best assignments. The fastening to the edge areas is not affected at all, so that the disadvantages associated with edge fastening are in principle avoided. Thus, in the sense of balance, the transition from a two-point installation used in edge mounting to a multi-point installation is made possible. The size and shape of the base surface of the ceramic holder or fastening means can be selected so that the voltage peaks present at the mounting points do not exceed the stresses in the central region of the field, i.

10 in the middle of the field bounded by the anchor points.

Since it is not always possible to exclude it from the outside in the facade tiles are coming from outside effects, such as flying stones or the like. Subject, may be necessary to provide the slab exposed to the side on opposite side 15 Kaine fracture resistant layer. This fracture-resistant layer must cover the entire length of the sub-areas of at least one slab, so that in the event of damage, the slab parts do not come off their joints and fall to the ground.

It may be advantageous to allow the cover layer to extend into the area of the holders as well and to cover these, as the durability of the ceramic joint in the event of atmospheric corrosion may be questionable.

This fracture-resistant layer consists of a mineral, preferably fiberglass, fabric or mat impregnated with epoxy resin.

When using such a fracture-resistant layer, it is particularly expedient that in the further development of the invention, the holders are not formed as a sharp-edged rectangle or a cylinder, but as a dome-shaped one.

If there is no fracture-resistant layer, but the clips area is desired to protect a sustainable possible against corrosion caused by the atmosphere, it may also be preferred that lisämuodostuksessa plate sight-35 opposite to the side of the VISSA side is provided with means of the invention July 81 081 least clamps the area of the covering ilmaa- and water -with an impermeable layer, e.g. a layer of silicone or a part intended to take up the metal fastening means of the holder, is filled with a sealing, water-repellent, non-meltable material after firing connecting the holder, the fastening means and the 5 plates.

An additional solution to this problem is to ensure that acid rain or moisture can immediately drain out of the area of the ceramic joint. This is preferably done by means of channel-like recesses extending from the edge of the holder in the part intended to receive the metallic fastening means, in at least one direction, preferably in four mutually vertical directions.

15 The drawing shows four exemplary embodiments in four figures.

Figure 1 is a ceramic plate denoted 1, which is visible from the opposite side to the side of number 2, in plan view, for example, a circular recess 20, wherein the binder is a ceramic glaze in the form of three. On top of this glaze there is a ceramic holder 4, which in a repeated embodiment has, for example, a hole 5 in which a metal fastening means, here 25 a screw 6, is inserted before inserting the ceramic holder 4, by means of which the ceramic tile can be fastened to a substructure. It can be seen very clearly from the drawing that the ceramic tile 1 can also be placed on the ceiling. The attachment of the slab to the support, e.g. the substructure, leaves the viewer completely silicon-30, i.e. the top of the upholstery is completely intact.

In Figure 2, the same parts are denoted by the same reference numerals. Numeral 7 shows a sectional surface structure, e.g. a meander-shaped metallic raw material with a large electrical resistor 35 embedded in the glaze 3 and connected to the electric current by means 8 and 8 and thus can be heated to the melting temperature of the glaze. Numerals 13 and 14 denote channels, grooves or other recesses connecting the space around the end 15 of the metal fastening means with the area outside the ceramic holder 4 so that the penetrated moisture can again flow out without interference. Preferably, four channels or the like are arranged perpendicular to each other.

Also in Fig. 3, the number 1 denotes a ceramic tile 10, the number 2, for example, a recess with a circular plan, and the number 3 a ceramic glaze. In this case, the fixing means, denoted herein by the number 10, has a holder-forming widening 11 which fits into the recess 2. The fixing means 10 is formed of a material having a high electrical resistance and cannot be connected to a power supply and thus heated to a temperature above the glaze melting temperature.

Figure 4 shows a slightly modified embodiment, 20 according to Figure 1. Of course, this alternative is also possible in the corresponding embodiments according to the embodiments according to Figures 2 and 3.

Reference numeral 1 refers to, in turn, the ceramic plate having a visible side 21 opposite surface 22, 25 in this case is flat, i.e., it has no recess. A ceramic holder 24 is placed on this surface 22, the essential shape of which corresponds to e.g. the holder 4 according to Fig. 1. However, in contrast to this holder 4, the holder 24 has a recess 25 surrounded by a step-like edge 26. As in the embodiment according to Fig. 1, a fastening means in the form of a screw 6 is placed in the central hole 5. The space obtained in the recess 25 is filled with a ceramic glaze as a binder. The connection of the holder 24 and the plate 1 with this binder takes place 35 as described above by a second firing. Recess 25

II

9 81 081 in the surrounding residual surface, i. the stepped edge 26 has a small distance from the surface 22 of the slab 1 so as to leave a gap 27. This edge 27 has a stepped edge 26 connected to the slab surface 22 by an aging-resistant stick 5 of atmospheric and sealing material placed in place of another slab. 1 and the holder 24 and thus ensures a particularly good protection against climatic influences by means of a joint made of glaze in the recess 25.

It will be obvious to a person skilled in the art that this principle and how this principle can also be applied in the embodiments according to Figures 2 and 3.

As mentioned, the glaze 3 preferably has a melting point below 15 quartz change point, whereby the fired ceramic tile placed with the corresponding holders is once again heated to a temperature below the quartz change point.

The proposed ceramic joint may not always be 20 to be against corrosion caused by the atmosphere of mutatis resistance, and therefore is provided with, as shown by Figure 1, conveniently the plate exposed side opposite the side at least stoppers 4 region in Figures 1 and 2, or clamps 11, the region in Figure 25 3 cover the fracture-resistant layer. This fracture-resistant layer consists of a mineral, preferably glass-nonwoven fabric or mat impregnated with an epoxy resin. Not only does it increase the resistance of the slab to break, but it also protects the entire junction box 30 against climatic effects.

If, instead of the fracture-resistant layer, there is a layer of air- and water-permeable and / or water-repellent material, the formation of the structure does not change, so that the repetition of an additional pattern is waived here.

Figure 1 shows the formation of the holder 4, which makes it very easy to apply such a fracture-resistant layer. A dome or vault formation of the holder is known.

Claims (18)

1X 81081 1. Large-size ceramic tile with a visible from the opposite side of the side Installation 5-tulle clips (4,11,24), the balance of the requirements imposed by the attachment points of the ceramic glaze (3) by means of attachment wherein the clips (4, 11, 24) having a coefficient of thermal expansion is at least about the same than in ceramic tile (1). Slab according to Claim 1, characterized in that the holders (4, 24) are fired ceramic parts for receiving a metal fastening means (6). Tile according to Claim 1 or 2, characterized in that the glaze (3) has a melting point below the quartz transition point (573 ° C), the fired ceramic tile (1) provided with corresponding holders (4, 24) being heated once more. to a temperature below the quartz transformation point. Slab according to one of Claims 1, 2 or 3, characterized in that a ceramic, glazed, perforated element (7), which is made of metal and is connected to the power supply (connections 8, 9), is embedded in the ceramic glaze (3). 25 having a substance having a melting point well above the melting point of the ceramic glaze (3) and having a coefficient of thermal expansion almost equal to that of the ceramic glaze (3). Slab according to Claim 4, characterized in that the temperature coefficient of the electrical resistance of the material selected for the surface element (7) is between 2 and 600 ° C greater than 2. Slab according to Claim 2, characterized in that the holders (4, 24) are provided with a recess or a hole (5) for receiving a metal fastening means (6). 12 81 081 Slab according to Claim 6, characterized in that the fastening means (6) are in each case integrated into the ceramic holders (4) to suit the shape. Slab according to claim 1, characterized in that the fastening means (10, 11) itself can be connected to a power supply and consists of a metallic material with a high electrical resistivity, a melting point well above the melting point of the ceramic glaze and a coefficient of thermal expansion almost equal to that of the ceramic glaze. . Slab according to Claim 8, characterized in that the selected material has a temperature coefficient of electrical resistance between 20 and 600 ° C greater than 2. Slab according to one of the preceding claims, characterized in that it can be easily lowered at the joints of the fastening parts (4; 10; 11) on a surface approximately corresponding to the floor plan of this part. 11. The plate of claims 1-9, characterized in that the clamps (24) is a plate (1) visible from the opposite side to the side (22) coming into contact with the surface of the recess (25). Slab according to Claim 11, characterized in that the residual surface (edge 26) surrounding the recess (25) is joined by an aging-resistant adhesive formed after incineration to join the slab (1) and the holder (24), which consists of a weather-resistant adhesive. and a sealing material 30, sustainably the plate (1) visible side (21) with the opposite side (22). 13. A plate according to any one of the preceding claims, characterized in that the plate (1) visible from the opposite side to the side is provided with at least the largest dimension of the plate 35 comprise areas of the fracture-resistant layer (12). Il 13 81 081 Slab according to Claim 13, characterized in that the fracture-resistant layer is introduced into the area of the holders (4, 10, 11, 24) and covers them. Slab according to Claim 13 or 14, characterized in that the fracture-resistant layer consists of a mineral, preferably fiberglass, fabric or mat impregnated with epoxy resin. Slab according to one of the preceding claims, characterized in that the holders (4, 24) are dome-shaped. 17 in any one of claims 1-12 tile, characterized in that the slab exposed to the opposite side of the side area is provided with at least pidik-projects, covering them, water-repellent, ilmaaläpäi- 15 unselected layer. Slab according to one of Claims 1 to 17, characterized in that the ceramic holders (4) are provided in at least one direction, preferably in four mutually vertical directions from the edge of the holder, in the part intended to receive the metal fastening means (6). on outgoing channels (13, 14). 14 81 081