CZ291016B6 - Ceramic tile with shaped intermediate layer and use thereof - Google Patents

Abstract

In the present invention there is disclosed a ceramic tile with shaped intermediate layer, being formed by a fundamental layer of ceramic material, on which there is disposed a glaze layer, wherein an electrically conducting intermediate layer in the form of a grating (3) is disposed between the fundamental layer (1) and the glaze layer. The grating (3) is preferably made as a system of concentric annular rings (4) decreasing successively and regularly toward the center, or as a system of polygons also decreasing successively and regularly toward the center. Claimed is also the use of the invented tile in a pavement for shielding-off negative effect of geopathogenic zones on live organisms, particularly on a human being.

Description

Ceramic tile with a shaped intermediate layer and its use

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a tile having a shaped interlayer in the form of an electrically conductive grid and its use for shielding geopathogenic zones.

BACKGROUND OF THE INVENTION

Living organisms develop under the influence of the surrounding environment. At first, man intuitively, later increasingly ingeniously revealed the individual factors that had and have the strongest influence on his own development. Among the many factors that determine the quality of human relationships with the environment and whose influence has recently been extensively investigated are physical, especially electromagnetic fields. The relation between the intensity or structure of the electromagnetic field and the quality of life processes of the living organism is already evident due to the bioelectric nature of the nerve signals. Neurons, the basic building blocks of nerve tissue, create their own weak electromagnetic fields, which are used in the process of processing and storing information in brain tissue as a second signaling system that complements the synaptic system. Indeed, it has been experimentally verified many times that the central nervous system is the most sensitive to the action of electromagnetic field.

Geopathogenic zones (GPZ) can also be considered a naturally modified form of electromagnetic field. These are areas of smaller or larger extent, under which are most often groundwater, or are places of former riverbeds or marshes, as well as sites with radioactive bedrock or sites where various rocks come together and where geological faults occur. In general, the significant inhomogeneity of the terrain surface or subsoil causes a different physical situation above the terrain than in places where this inhomogeneity is not found. Inhomogeneity may be of a natural character, but may also be caused by artificial human intervention. People living within the reach of GPZ react individually to its presence, so its effect on humans can be determined objectively by statistical evaluation of cumulation and frequency of selected symptoms in a sufficiently large population compared to the population living in other places.

Man once localized GPZ by observing living organisms, whether plants or animals, and based on changes in their typical properties, set out their permanent habitats so that they were free from the influence of GPZ. While this method of bioindication encompasses all biologically active aspects of GPZ, it is variable and subjective and therefore unsuitable for the objective localization of GPZ. Therefore, changes in the geomagnetic field (geophysical method) or the concentration of the atomic or molecular form of metallic elements such as magnesium, potassium, radium, copper, zinc, and halogens such as fluorine and chlorine in soil or atmospheric air (atmogeochemical) method). The resonance method of GPZ localization is the subject of AO 238 554. The method consists in comparing the mechanical resonance of the object material or air column inside the object with the resonance outside the object. Given the complex nature of the GPZ phenomenon, it is recommended to correlate at least two localization methods.

Protecting people from the effects of GPZ was initially largely passive, one avoided such places when establishing their settlements. Over time, with population growth and scientific and technological advances, man has been forced to build housing estates regardless of the presence or absence of GPZ; . The way in which the negative impact of such harmful fields on humans so far can be at least partially reduced is always a combination of at least two steps. In the first step the GPZ is located, in the second step the equipment of the apartment is transferred, where its inhabitants spend most of their time (most often a bed) in the part of the apartment where

-1 CZ 291016 B6

I is the least harmful field effect. If the transfer of the device cannot be realized, the second step consists in placing a suitably shaped object in a suitable way near the device where the inhabitants spend most of their time (most often under the bed) so that it is oriented in some way towards GPZ.

This object then more or less shields the effect of GPZ in the required limited space.

To significantly reduce the influence of GPZ, it is possible to combine both the transfer of the bed to the zone with the weakest influence of the zone and the oriented placement of a suitably shaped shielding object underneath it.

Obviously, the industrial use of this process is considerably limited. Even assuming an objective 10 localization of GPZ, the success of the above-mentioned method depends on an individual evaluation of the situation for a particular dwelling, especially the orientation of the GPZ with respect to the ground plan of the dwelling and to the cardinal points. The material used, the season, etc. may also have an impact on the construction of the object. Moreover, the GPZ may move gradually, so the effectiveness of the measures taken must be checked from time to time.

It has now been found that the tiles of the present invention overcome these drawbacks.

SUMMARY OF THE INVENTION

The tile according to the invention consists of a base layer of ceramic material on which a layer of glaze is located, between which the interlayer of an electrically conductive material in the form of a grid is integrated between the two layers.

Advantageously, the lattice may be formed as a system of concentric, progressively decreasing annulus to the center, each annulus being connected to the nearest inner annulus by a coupling.

Preferably, the coupling lies in a radial direction, each successive coupling being positioned 30 opposite to the preceding coupling.

Preferably, a partition is formed between the inner annular ring and the center of the concentric annular ring assembly, preferably in the opposite configuration to the preceding clutch.

In another embodiment, the grid may be formed as a system of annulus, in which an annulus with the center Si and a subsequent inner annulus with center S ₂ alternates away from the tile edge, the centers being offset relative to each other such that conductive electrical connection.

In another embodiment, the grid may be formed as a system of progressively decreasing polygons, each polygon being connected to the nearest inner polygon by a connector. The polygons may be aligned or rotated relative to each other. Preferably, the polygons are regular.

The intermediate layer of electrically conductive material may advantageously be made of metallic silver or another metal, also may be made of graphite.

The width of the annulus or polygons is limited by the requirement of electrical conductivity. Thus, if the material of the conductive interlayer is, for example, silver, the minimum width of the annulus is of the order of micro50 meters. The maximum width is then limited by the requirement that the distance between the individual rings or polygons be such that they do not allow their electrical connection. Only the couplings or contact areas provide an electrically conductive connection.

-2GB 291016 B6

For example, the tile may have a plan view of a square, rectangular, hexagonal or other, and preferably the interlayer of an electrically conductive grid-like material is positioned substantially symmetrically in the tile seen from above.

The electrically conductive grid in the form of a grid is preferably an ellipse array for rectangular tiles.

The glaze layer can be decorated by methods known in the art, such as by coloring, embossing, etc. This layer can also be translucent or even transparent, and the interlayer then shines through the glaze to create a characteristic decor.

The grid of electrically conductive material in the form of a grid has the properties of a shielding antenna that shields the influence of the electromagnetic field on living organisms. The paving formed from the tiles according to the invention eliminates the negative influence of the electromagnetic field, in particular GPZ, on the living organisms located in the space above the paving. The shielding effect of this paving is not dependent on the orientation of the paving as a whole with respect to the electromagnetic field or GPZ and also does not depend on the mutual orientation of the individual tiles in the paving. Thus, it is not necessary to locate the GPZ to eliminate the harmful effects, nor does it require the individual placement of shielding objects or periodically checking the functionality of the tiles. The shielding of the effects of harmful effects is permanent regardless of the possible migration of GPZ.

The tile manufacturing process according to the invention consists in applying an electrically conductive layer in the form of said grid in a suitable manner to the molded tile blank, optionally after the first firing, whereupon the tiles are glazed and baked.

The thickness of the conductive interlayer does not affect the function of the tile while maintaining the electrical conductivity. Due to the requirement of good electrical conductivity, its minimum thickness depends on the properties of the material used and the type of technological operations in the order of pm, the maximum thickness then around 1 mm.

BRIEF DESCRIPTION OF THE DRAWINGS

In Figure 1, the tile according to the invention is in plan view, with a conductive interlayer in the form of a grid in one of the preferred shapes.

Figure 2 shows the same tile of Figure 1 in section A-A.

Figure 3 shows a tile in plan view, with a conductive interlayer in the form of a grid in another preferred arrangement.

Figure 4 shows a tile in plan view, with a conductive interlayer in the form of a grid in another preferred embodiment.

Figure 1 shows a tile according to the invention which comprises a base layer 1 on which a glaze layer 2 is located. Between the base layer 1 and the glaze layer 2 an electrically conductive interlayer in the form of a grid 3 is integrated. , successively decreasing annulus 4, each annulus being connected to the nearest inner annulus by a radially oriented connector 5. Each successive connector is located opposite to the preceding connector. Between the inner annular ring and the center of the concentric annular ring system, a crossbar 6 is located opposite the preceding coupling 5.

-3 CZ 291016 B6

Figure 2 is a cross-sectional view of the tile having a shaped interlayer in the A-A direction as shown in Figure 1.

Figure 3 shows a tile according to the invention in which the electrically conductive grid in the form of a grid is formed as an annulus system in which an annulus with a center S1 and a subsequent inner annulus with a center S2 alternates from the edge of the tile. r such that a conductive connection of the annulus is provided in the contact area P of the two annulus.

Figure 4 shows a tile according to the invention in which the electrically conductive grid in the form of a grid is formed as a system of gradually decreasing 5 quadrilaterals 7, each quadrilateral being connected to the nearest inner quadrilateral by a connector 5.

DETAILED DESCRIPTION OF THE INVENTION

Example 1

The finely ground mixture of feldspars and clays is dried to granulate and pressed into molds to form tiles, which are fired at 1170 ° C. The electrically conductive interlayer in the form of a grid according to FIG. 1 is applied to the semi-finished product by screen printing; of silver. Overlay with glaze and make a second firing at 850 ° C.

Example 2

From the ground feldspar / clay slurry, particles larger than 100 µm are removed on a sieve, the suspension is dried in a granulate spray drier, and the granulate is compressed to form square tiles. The semi-product is connected through a negative grid template consisting of a system of 7 concentric annulus, each annulus being connected to the nearest inner annulus by a radially oriented connector which is offset by 120 ° relative to the previous connector and the rung between the inner annulus and the center direction of the diagonal of the tile, sprayed with a platinum lister containing 3 wt. platinum. After drying of the leaf, the tile is glazed and subsequently fired in a tunnel furnace at a temperature of 1220 ° C.

Example 3

The mixture of ground stoneware clay, feldspar and crushed quartz is dried to a residual moisture content of 15% by weight. and pressed onto the stoneware blanks. The conductive grid in the form of a grid according to FIG. 4 is applied by screen printing using a graphite screen printing paste containing 35% by weight. graphite carbon. The tiles are fired in a tunnel oven at 1270 ° C. Before the end of firing, a glaze is formed on the tile surface by spraying sodium chloride into the firing space of the furnace.

Example 4

From the granulate obtained in Example 2, rectangular tile blanks are made by compression. A conductive intermediate layer in the form of a grid is applied to the semi-finished products produced in this way by means of screen printing, which is formed by alternating ellipses with inscribed rectangles from the edge of the tile, where

From the corners of the rectangle, but not at the other corners, the conductive connection between the rectangle and the subsequent ellipse inscribed therein is provided in all four contact areas, the entire system consisting of four ellipses and three rectangles. The same screen printing paste as in Example 1 was used for screen printing. The tiles were glazed and baked at 1150 ° C.

The properties of the tile according to the invention in terms of GPZ shielding effect were verified by the following use.

Since 1995, an elderly couple has been living in a small house in the Příbram region, which was built in the field, according to a detailed geological survey consisting of crystalline, heavily metamorphosed shales that are permeated with fissures filled with hydrothermally formed vein minerals. After a three-year stay in the house, the general health condition gradually deteriorated with concomitant practically unrelenting pain leading to temporary immobilization. Their origin, according to medical diagnosis, was arthritis in combination with chronic neuritis and partial atrophy of adjacent muscle groups. The therapy consisted of administration of anti-inflammatory pharmaceuticals and analgesics to alleviate pain, but subjectively, their application provided little relief. Bioindication revealed that the residential rooms of the house lie in the area of action of relatively significant GPZ. Based on the GPZ detected in this way, a shielding antenna was placed under the occupant's bed in the appropriate orientation. After three weeks from the placement of the shielding antenna, the pain in movement was subjectively reduced, after two months the mobility improved objectively, and her mental condition was also partially improved. In the course of the next year, however, her unfavorable state of health gradually recovered. Bioindication revealed that the original orientation of the GPZ changed by almost 90 °, so that the shielding antenna placed under the bed was not able to shield the GPZ. At that time there were already tile samples made according to the first embodiment of the invention. To test their shading effect, the tiles were made into tiles in the bedroom of the house, the tiles were laid loose on the existing floor with full-area carpet without the use of mastic. Bioindication as well as geophysical measurements showed that GPZ was practically perfectly shielded by this created pavement. Already after two weeks, the health of the resident improved, after two weeks she was able to move without support despite the fact that she stopped using analgesics regularly.

Pigs for fattening in the Ostrava region were divided into 14 boxes, where weaned piglets were placed after twelve. Around 1998, in one of the boxes located in the corner of the building, piglets often suffered from colic, hoof inflammation and parasitic diseases, so there was more than twice the mortality rate despite increased veterinary care. Weight gains were significantly below average compared to other boxes. Bioindication and later also geophysical measurements showed that two less pronounced GPZs cross at the corner box. The formation of these zones can probably be related to the decline of mining in the nearby coal mine, during which the mine water was drained and drained intensively. The limitation of mine water pumping led to the emergence of groundwater and muds near the fattening farm.

In the corner feed box under observation, the plank floor was removed and a stoneware tile floor was laid in its place in the cement bed according to the third embodiment of the invention. Bioindication and geophysical measurements confirmed GPZ shielding. Also the results from the last piglet fattening cycle confirm that the negative effect of GPZ has been shielded. In this last cycle, there has been no death or care of the veterinarian (with the exception of regular preventive check-ups) and weight gain is still slightly higher than in other boxes. It is interesting to note that the piglets in the adjacent box prefer to rest close to the wall that separates their box from the corner box.

-5GB 291016 B6

Industrial applicability

The tiles according to the invention find use in residential, office and other buildings in which people are present and in farm buildings to shield the negative impact of GPZ on 5 humans and farm animals.

Claims (13)

10 PATENT CLAIMS 1. Ceramic tile with a shaped intermediate layer consisting of a base layer of ceramic material on which a layer of glaze is located, characterized in that: The electrically conductive interlayer in the form of a grid (3) is integrated with the 15 layer (1) and the glaze layer (2) · Ceramic tile according to claim 1, characterized in that the grid (3) is formed as a system of concentric, progressively decreasing annulus (4), decreasing towards the center, 20, wherein each annular ring is connected to the nearest inner annular ring by a coupling (5). Ceramic tile according to claim 2, characterized in that a partition (6) is arranged between the smallest inner annulus and the center of the assembly. 25 Ceramic tile according to claims 2 to 3, characterized in that each connector is located opposite the preceding connector. Ceramic tile according to claims 3 and 4, characterized in that the crossbar (6) is arranged opposite to the preceding connector (5). Ceramic tile according to claim 1, characterized in that the grid (3) is designed as a system of annulus in which an annulus with a center (Si) and a subsequent annulus with a center (S ₂ ) alternates from the edge of the tile. of contact areas (P) of the two outer ring is provided an electrically conductive connection, and the center (S |) and (S ₂₎ are mutually shifted by distances 35 (r). Ceramic tile according to claim 1, characterized in that the grid (3) is constructed as a system of gradually decreasing polygons, each polygon being connected to the nearest inner polygon by a connector (5). Ceramic tile according to claim 7, characterized in that the shrinking polygons are regular. Ceramic tile according to claims 1 to 8, characterized in that the grid (3) is symmetrically positioned within the tile within the technological tolerances when viewed from above. Ceramic tile according to claims 1 to 9, characterized in that the electrically conductive intermediate layer is made of metal. 50 Ceramic tile according to claim 10, characterized in that the electrically conductive intermediate layer is made of silver. -6GB 291016 B6 Ceramic tile according to claims 1 to 9, characterized in that the electrically conductive intermediate layer is made of graphitic carbon. Use of a ceramic tile according to claims 1 to 12 in paving to shield the negative impact of 5 geopathogenic zones on living organisms, in particular humans.