DE20307231U1 - Ceramic plate for the production of an electrically conductive coating especially for a floor or wall comprises fired ceramic pieces having some electrically conductive material - Google Patents

Abstract

ceramic Plate (1) for producing an electrically conductive plate covering (10), the plate (1) consisting of a fired ceramic body (15) there is, the plate (1) a top-side usable surface (11), one in a laying mortar or laying adhesive bed (2) insertable rear surface (12) and on the edge between usable surface (11) and back surface (12) peripheral edges (3) of the panel covering (10) delimiting edges (13), characterized in that the plate (1) at least contains electrically conductive material (16) in a partial area (14).

Description

The The invention relates to a ceramic plate for producing a electrically conductive Panel covering, in particular a floor or wall covering, wherein the plate consists of a fired clay-ceramic body, wherein the plate has a top surface, one in a mortar or Laying adhesive bed insertable back surface and on the edge between usable area and rear surface surrounding, Joints of the board covering has bounding edges.

Ceramic tile coverings Plates are common used as industrial floors, because such slabs are both mechanically resilient and chemically resistant. Electrically, they are common ceramic plates from a fired clay-ceramic body an insulator that has practically no electrical conductivity having. In some applications, however, one is required electrically conductive To use plate covering to prevent electrostatic charges prevent the dangers caused by sparking.

Out ceramic plates of the type mentioned at the outset are known in practice, with the creation of an electrical conductivity on their usable area an electrically conductive Glaze are covered. Together with an electrically conductive joint compound and an electrically conductive Verlegemörtel- or laying adhesive bed is the desired derivation of electrical Charges reached.

adversely is with this known ceramic plate that during the Use of the flooring by walking and driving on the electric conductive Glaze wears out, causing surface areas of the slab over time arise that are no longer electrically conductive. This allows the desired Protective effect against the generation of electrical charges in a dangerous one Dimensions lost go.

Farther is it from the relevant Practice known, conventional ceramic plates that are electrically insulating together with an electrically conductive grout and an electrically conductive laying mortar or Use laying adhesive bed. The usable area of the tile covering thus produced is then only electrically conductive in the area of the joints. This is for some applications are still sufficient for other applications this solution however, insufficient protection against the development of electrical charges and the resulting dangerous ones Spark. Next is the real one Derivation value of the finished covering from the mixing and processing quality of the mostly manually prepared laying mortar or laying adhesive and depending on the grout. This can disadvantageously spread the electrical Derivation value of the finished covering over its area.

For the present The invention therefore has the task of a ceramic plate of the type mentioned to create the disadvantages listed avoids and with which an electrically conductive plate covering can be produced is a reliable one and permanent protection against the emergence of dangerous offers electric charges.

The solution This object is achieved according to the invention with a ceramic plate of the type mentioned, which is characterized in that it at least contains electrically conductive material in a partial area.

With the invention advantageously creates a ceramic plate, which is electrically conductive in at least one area, to discharge electrostatic charges and thus explosion risks prevent by sparking. Because the electrically conductive material is contained in the plate itself, it can not be caused by abrasion a decrease in the electrical conductivity of the plate. Moreover is the plate according to the invention even electrically conductive, So that the electrical conductivity is not on the surface area an electrically conductive Grout limited is.

According to the invention is preferred provided that the electrically conductive Material made from one or more metal-carbon compounds or from one or more metal oxide-carbon compounds consists. Such materials are sufficient on the one hand electrically conductive and on the other hand sufficiently mechanically and thermally stable, so that you for the Production of a ceramic plate in a firing process are suitable.

Especially the electrically conductive material preferably consists of or several iron ore-carbon compounds. This material meets in especially cheaper as the required properties with regard to its electrical Conductivity on the one hand and its mechanical, chemical and thermal properties, the most possible close to the corresponding properties of the ceramic plate material should lie, on the other hand. Such an electrically conductive material is more expensive than a normal one ceramic base material for Panels, but the additional costs remain within a reasonable range, So that the plate according to the invention can be produced without additional uneconomical costs arise.

It is preferably further proposed that the electrically conductive material is mixed with the ceramic clay body before the fire. The additional effort in the production of the plate according to the invention thus comprises at most one mixing process which is inserted between the production of the ceramic clay body and the fire. If the electrically conductive material is used instead of an optically different ceramic material mixed in for aesthetic reasons in a known manner, there is no additional effort at all.

The electrically conductive Material preferably has the shape of a heat-resistant granulate. In In this form, the electrically conductive material is easy to handle and easy to mix into the material of the ceramic plate. Besides, is the electrically conductive The material can then be pressed well into molds together with the cullet.

In An embodiment of the plate is provided that the electrical conductive Material is present throughout the plate. This version of the plate has the advantage that the Forming the plate by pressing in a mold in the usual way Way without additional operations can be done. In addition, this plate has a uniform and over its entire volume directional electric conductivity, so for a special safe discharge of electrostatic charges is ensured.

A alternative execution the record provides that the electrically conductive Material only in an upper area starting from the usable area the plate is present. This plate offers the specific advantage that less from the electrically conductive Material for the manufacture of the plate needed so that a such plate is less expensive in terms of materials. It stands up somewhat greater effort opposite in the manufacture of the plate since the plate is molded must be done in two steps from two different materials, whereby first the pure clay ceramic body filled in a shape and pressed and subsequently one with the electrically conductive Mixed shards material to form the top of the Plate is placed in the mold and then pressed in this. The filling a form for a ceramic plate in two steps is already known per se, So far, however, has only been used to achieve different visual appearances the visible usable area the plate used. In the plate according to the invention, which is only in its upper area electrically conductive is for the discharge of electrostatic charges on everyone Case an electrically conductive Grout in the joints of the paving required to the electrical conductive Areas of the plates forming the plate covering are electrically connected to one another connect conductively.

For a safe Dissipation of electrostatic charges, it is sufficient that the electrically conductive material containing upper plate area between about 10 and 25% of the total thickness of the plate. At the same time it is achieved that only a relatively small Amount of electrically conductive material in relation to must be used for the total amount of plate material.

On the ceramic according to the invention Platte made the demand, on the one hand an adequate one high electrical conductivity to show and on the other hand the known good properties of a ceramic plate in terms of mechanical and chemical stability to keep. A good compromise between These plate requirements are achieved in that preferred the proportion of the electrically conductive Material in the areas of the plate where it is present is between about 40 and 60 vol .-% of the plate material. The electrically conductive Material is then in such a quantity and distribution within of the material of the plate before that electrical conductivity in the desired one Size sure guaranteed is. Retains at the same time the plate but at least largely the usual good mechanical and chemical properties, such as those of a purely ceramic plate without electrically conductive material are known. Particularly good properties of the plate are achieved if what is appropriate as an electrically conductive Material a material is used, its mechanical and chemical Properties if possible close to the corresponding properties of a ceramic material. That is part of it for example, if possible good agreement of thermal expansion coefficient of the materials to damage within the plate by heating it to 1,000 ° C or more when fired and by the subsequent cooling avoid. Suitable electrically conductive materials are, for example the compounds mentioned above.

In order to give the plate a uniform electrical conductivity in its spatial directions, it is preferably provided that the electrically conductive material forms a spatial lattice within the clay-ceramic body from contacting material parts. In such a plate, the electrical conductivity is independent of the direction, which offers a particularly high level of security for the discharge of electrostatic charges from the top surface of a floor covering made from such plates. A sufficiently conductive contact between the material parts of the electrically conductive material is achieved, in particular, by the presses customary in the production of the plates after the shards mixed with the electrically conductive material have been introduced into the plate shape. For the derivation of electro Static charges due to the plate covering formed from the plates according to the invention, it is necessary that the plates have a sufficiently high electrical conductivity. At the same time, however, the electrical conductivity must not become too high, since in this case undesirable tuft discharges can occur, which in turn lead to sparks and thus to explosion risks. For the plate according to the invention it is therefore preferably provided that the plate has an electrical surface leakage _resistance R _OA or an electrical volume resistance R _D between approximately 10 ³ and 10 ⁹ Ω. These resistances can be achieved with the materials mentioned above and can also be set during the plate production within the limits mentioned.

Around a mechanically highly resilient and at the same time chemically very resistant, thereby electrically conductive To achieve a slab, the ceramic clay fragments are preferred made of porcelain stoneware. At the same time, porcelain stoneware has the advantage that the Plate by pressing the raw material, i.e. of the shard with the mixed in electrically conductive material, can be produced in a form that is practically non-porous. This succeeds also advantageous if the electrically conductive material has a grain size within of the raw material of the plate, which is significantly larger than the grain size of the porcelain stoneware, if the electrically conductive Material is a compound of the type mentioned above, which favorable compression properties Has. The porcelain stoneware and the electrically conductive material fill up after one or several pressing operations Plate shape without gaps out so that too in their electrically conductive execution the plate can be produced practically non-porous or at least very low in pores is. This results in high mechanical strength and is advantageous low water absorption the plate.

in the following are two embodiments the plate of the invention explained using a drawing. The figures in the drawing show:

1 a section of a plate covering made of ceramic plates in a first embodiment in cross section,

2 the plate covering in a second embodiment also in cross section and

3 an enlarged detail section of a plate partly in side view, partly in cross section.

1 shows in cross section a section of a slab 10 made of several ceramic plates 1 is formed. The plates 1 have a usable surface on the top 11 , which forms, for example, a walkable and drivable floor area in a company building.

The plates have underside 1 a back surface 12 with which the plate 1 in a laying mortar or laying adhesive bed 2 is inserted. Below the bed 2 can be further layers, for example a sealing layer, an adhesion promoter layer or other layers which are known per se.

The panels are on their side edges 1 through edges 13 bounded with neighboring edges 13 Put 3 between the individual plates 1 form. The outline of the plates 1 can be square, rectangular or hexagonal in plan view, as is known per se. Also special forms of the plate, for example with spacers or toothing on the edges 13 , can be manufactured. The boards have a typical thickness of between approximately 20 and 30 mm for floor coverings, and a thickness of less than 10 mm is sufficient for wall coverings.

The joint 3 are with a grout 30 filled, the upper side approximately flush with the usable area 11 of the plates 1 and the underside with the laying mortar or laying adhesive bed 2 is in contact.

The plates 1 according to 1 consist of a ceramic material, here a pressed and fired clay ceramic fragments in a form. This shard is previously over the entire volume of the plate 1 an electrically conductive material, for example a granulate of one or more iron ore-carbon compounds. This gives the plate 1 an electrical conductivity by means of which electrostatic charges can be dissipated without damage.

For further discharge of the electrical charges from the plates 1 serves according to the example 1 the laying mortar or laying adhesive bed 2 which, as is known per se, consists of an electrically conductive material or to which a suitable electrically conductive material is admixed in a sufficient amount. The plate covering is in a position not visible in the drawing 10 electrically connected to an earth to electrostatic charges over the usable area 11 into the plates 1 initiated and by these through the electrically conductive bed 2 to be forwarded without damage.

The grout 30 in the joints 3 in the example according to 1 not be electrically conductive. To improve the electrical conductivity of the entire board surface 10 but can be an electrically conductive grout here 30 be used.

Alternatively, with the slab covering 10 to 1 even the grout 30 be electrically conductive while the laying mortar or laying adhesive bed 2 is not electrically conductive. Electrostatic charges are then discharged from the plate 1 to plate 1 about the grout 30 and then at one or more points over a grout 30 and / or the plates 1 contacting grounding.

With the plate covering 10 according to 2 are the ceramic plates 1 in contrast to the example according to 1 only in their upper area 14 , which is different from the usable area 11 over part of the thickness of the panels 1 extends downward, electrically conductive. In the rest, under the upper area 14 lying area are the panels 1 free of electrically conductive material, so that there is no electrical conductivity in this lower area. With the plates 1 according to 2 So there is an electrical conductivity only in one direction parallel to the usable area 11 of the plates 1 ,

To with this slab surface 10 Discharging electrostatic charges is in the joints 3 between the neighboring plates 1 horizontal jointing compound 30 electrically conductive. This will make the individual panels 1 , here their electrically conductive upper areas 14 electrically connected together.

The laying mortar or laying adhesive bed 2 must with the plate covering 10 according to 2 not be electrically conductive. To support the electrical conductivity of the entire board surface 10 but can also use the bed 2 be electrically conductive here.

The grounding of the slab 10 according to 2 takes place at one or, if necessary, at several points so that an electrically conductive area of the plate covering 10 , either the upper area 14 at least one of the plates 1 and / or the grout 30 or, if it is made electrically conductive, the laying mortar or laying adhesive bed 2 is in electrical contact with a grounding device.

3 Finally, the drawing shows in a greatly enlarged representation a preferred shape and distribution of the electrically conductive material 16 within the clay ceramic body 15 the plate 1 , How 3 illustrated, has the electrically conductive material 16 here the shape of a granulate, which consists of a large number of grains, in the fine-grained clay-ceramic shards in relation to the granulate 15 are mixed in as evenly as possible. At the same time, most of the grains of the electrically conductive material touch 16 with each other, creating an electrically conductive, spatial grid within the plate 1 is formed.

Part of the grains of the electrically conductive material 16 lies openly on the usable area 11 the plate 1 , so that from there electrostatic charges originating, for example, from people walking on the plate covering or from vehicles moving on the plate covering, into the interior of the plate 1 and can be derived from there to an earthing device. The occurrence of electrical discharge sparks, which could lead to explosions in potentially explosive areas, is thus reliably avoided.

Since the preferably used electrically conductive material generally has a relatively dark color, different color combinations of the usable area of the plate can be used in conjunction with differently colored cullets 11 achieve, so that the plate also in optical terms 1 high demands are met.

Claims (12)

Ceramic plate ( 1 ) for the production of an electrically conductive plate covering ( 10 ), the plate ( 1 ) from a fired clay-ceramic body ( 15 ), the plate ( 1 ) a top usable area ( 11 ), one in a laying mortar or laying adhesive bed ( 2 ) insertable back surface ( 12 ) and on the edge between usable area ( 11 ) and back surface ( 12 ) circumferential, joints ( 3 ) of the paving ( 10 ) bounding edges ( 13 ), characterized in that the plate ( 1 ) at least in one area ( 14 ) electrically conductive material ( 16 ) contains. Plate according to claim 1, characterized in that the electrically conductive material ( 16 ) consists of one or more metal-carbon compounds or one or more metal oxide-carbon compounds. Plate according to claim 2, characterized in that the electrically conductive material ( 16 ) consists of one or more iron ore-carbon compounds. Plate according to one of the preceding claims, characterized in that the electrically conductive material ( 16 ) is mixed with the ceramic clay before the fire. Plate according to one of the preceding claims, characterized in that the electrically conductive material ( 16 ) has the shape of a heat-resistant granulate. Plate according to one of the preceding an sayings, characterized in that the electrically conductive material ( 16 ) in the entire plate ( 1 ) is available. Plate according to one of claims 1 to 5, characterized in that the electrically conductive material ( 16 ) only in one of the usable area ( 11 ) outgoing upper area ( 14 ) the plate ( 1 ) is available. Plate according to claim 7, characterized in that the electrically conductive material ( 16 ) containing upper plate area ( 14 ) between about 10 and 25% of the total thickness of the plate ( 1 ) includes. Plate according to one of the preceding claims, characterized in that the proportion of the electrically conductive material ( 16 ) in the areas of the plate ( 1 ) in which it is present is between about 40 and 60 vol .-% of the plate material. Plate according to one of the preceding claims, characterized in that the electrically conductive material ( 16 ) forms a spatial lattice of mutually contacting material parts within the clay-ceramic body. Plate according to one of the preceding claims, characterized in that the plate ( 1 ) has an electrical surface leakage _resistance R _OA or an electrical volume resistance R _D between about 10 ³ and 10 ⁹ Ω. Panel according to one of the preceding claims, characterized in that the clay-ceramic body ( 15 ) is made of porcelain stoneware.