RU77890U1 - SET OF ELEMENTS AND PLATE FOR DOUBLE FLOORING - Google Patents

Abstract

The proposed utility model relates to construction, in particular, to a set of elements for double flooring and a height-adjustable double floor support, in which the plate is mounted on the base through the support. In this case, the sides of the plate are coated with an electrically conductive film and beveled towards the lower surface of the plate, as a result of which a gap is formed between the lower surfaces of adjacent plates, and a gasket 6 made of electrically conductive plastic having protrusions included in the gap is placed between the plates 1 and the upper supporting surface of the metal support 2 the gap between adjacent plates. The technical result of the proposed utility model is to simplify the manufacturing process while maintaining reliable removal of electrostatic charge from the stove. The technical result is achieved due to the fact that the protrusions of the gasket made of an electrically conductive material and entering into the gap between adjacent plates coated with an electrically conductive film provide electrical contact between the electrically conductive side surfaces and the metal support, which ensures reliable removal of electrostatic charge.

Description

The invention relates to a set of elements and a panel for double flooring, in which a plate is mounted on a base through a support.

From the patent EP 0 391 628 (Int K1 E04F 15/024) 1990, a double floor construction is known having a gap on the sides that includes a guide element made of electrically conductive plastic. In the region of the edge located above, a flat element of an electrically conductive material with a side strip is inserted into the wood material, the shoulder of this strip entering the electrically conductive guide element. The flat elements of adjacent slabs are adjacent to each other. On the underside of the carrier layer of the board made of wood material, there is a sheet metal coating included in the gap on the sides of the board. This design, on the one hand, due to the presence of a gap on the side surfaces of the plate is time-consuming and costly, as well as adversely affecting the stability of the plates in the region of the upper edge, and on the other hand, assembly and installation

are expensive because the flat element must have a special shape and inserted into the groove of the wood material.

The technical result of the proposed utility model is to simplify the manufacturing process while maintaining reliable removal of electrostatic charge from the stove.

The technical result is achieved due to the fact that the sides of the plate are coated with an electrically conductive film and have a bevel towards the bottom surface of the plate, as a result of which a gap is formed between the plates on the bottom side, and a gasket of electrically conductive plastic having protrusions inlet is placed between the plates and the metal support into the gap between adjacent plates, which provides electrical contact between the electrically conductive side surfaces and the metal support.

The invention is explained below on the basis of the drawings, which show:

figure 1 - floor design with a plate on the supports,

figure 2 is a cross section of a plate,

figure 3 is a perspective view of a plate on a support to improve the process of removal of electrostatic charge.

1, the number 1 denotes a rectangular or square plate supported by corners on a metal support 2, by which the plate 1 is mounted on the base R. The support 2 has an upper metal support plate 2a, on which the corners of the plate 1 are attached, and a lower metal support plate 2b , with which the support is attached to the base. Preferably, the support 2 is made adjustable in height, for example, by means of a threaded rod 2c fixed to the lower support plate. The threaded rod 2c is inserted into the tube 2d provided with a nut. Figure 1 schematically shows a textile coating 7 located on the upper surface of the plate 1.

Figure 2 shows a plate 1 having a carrier layer 1A of chipboard with a thickness of 30-38 mm The density of the carrier layer of the plate varies in cross-section of the plate and lies in the range of 400-800 kg / m ³ , in particular, approximately 680 kg / m ³ . Due to this density, a sufficiently light plate is obtained, which allows it to absorb sufficiently large loads. Ultimate (destructive) load

plate is 1.2-8 kN with the size of the test sample 25 × 25 mm Such plates are suitable for use in offices at fairly high loads.

The side surfaces of the plate have bevels made at an angle equal to or less than 4.4 °, as a result of which the lower surface of the plate is smaller than the upper surface of the plate, as shown in FIG. This allows for high stability of the plate and higher insensitivity of the upper edge of the plate to impact during installation and, accordingly, to reduce damage, since the angle at the upper edge is almost obtuse. Due to this, it is possible to provide a large contact surface of adjacent plates, which, in turn, improves the stability of the floor structure.

A film 3 is applied to the side surfaces of the plate, overlapping the side of the plate from the top surface of the plate to the bottom surface. This ensures the protection of the side surfaces of the panel made of wood chip material and having a sufficiently porous surface.

The film 3 can be made of ABS plastic (styrene rubber acrylonitrate-butadiene). This material does not contain polyvinyl chloride (PVC) and is easy to process.

It is preferable to make the film 3 from an electrically conductive polyvinyl chloride, which allows for the conductivity of the plate, respectively, the electrical resistance between the upper and lower surfaces of the plate is more than 100 ohms. Conductivity can also be ensured by the inclusion of additional substances in the film material 3. To create electrical conductivity between the upper and lower surfaces of the plate, an electrically conductive film can be provided on at least one of the four sides. It is also possible to place an electrically conductive film on two opposite sides of the plate or, respectively, on other sides to provide conductivity in the transverse direction of the plate.

The electrically conductive film 3 improves the removal of electrostatic charge from the upper surface of the plate to the lower surface compared to the known solution in which only the adhesive between the non-conductive film and the base layer of the plate made of wood material is electrically conductive, since

the electrically conductive film makes the outer, respectively lateral surface of the plate 1 electrically conductive, and in this case, the electrically conductive adhesive layer is not located under the non-conductive film.

Depending on the application of the floor structure, the electrical resistance of the film may vary from 10 ² to 10 ⁹ ohms, preferably from 10 ⁶ to 10 ⁹ ohms. The highest conductivity is used for floors in offices, laboratories and other similar premises.

Due to the conductivity of the plate from the upper surface to the lower, the electrostatic charge is discharged through the metal support 2 to the zero potential of the base. This prevents the transmission of electrostatic charge to personnel moving on the floor. This is of great importance, for example, in the rooms in which electrical appliances are located.

Due to the small slant angle of the side surfaces of the plate, not exceeding 4.4 °, the electrical contact between the conductive film 3 and the conductive coating on the surface of the plate 1 is also improved, since the relatively obtuse angle between the film and the upper surface of the plate makes it easier to provide contact than sharp angle.

As the material of the film 3, a preferably fireproof material is used. Fire resistance can be obtained by introducing appropriate additives into the film material. In case of fire, the film melts on adjacent plates, as a result of which the gap between adjacent plates is filled with melt, which prevents smoke from escaping.

The film thickness is selected in the range of 0.1-2 mm, which is quite enough to protect the sides of the plate and has a sufficient cross section to ensure electrical conductivity and fire resistance.

It is advisable to introduce into the film material a means to increase the sliding effect of the film, for example graphite, which prevents squeaking during mutual displacement of the side surfaces of adjacent plates,

The material of the film 3 in color can match the color of the coating to create a unified impression in the case of using plates 1 directly as floor plates, while the film 3 on the side surfaces should remain visible. The film material in its color scheme can correspond, for example, to the color of the parquet on the top surface of the slab, to a coating imitating stones, or to any other coating.

As the adhesive for applying the film 3 to the side surfaces of the plate, a hot-melt adhesive or hot melt adhesive, which melts at high temperature, is preferably used. Hot-melt adhesive has the advantage that after application it quickly cools and hardens, due to which the film is quickly glued while ensuring a sufficiently high elasticity of the joint. In this case, there is no need for additional impregnation of the side surface of the plate, necessary when using water-soluble glue, since hot-melt adhesive or hot-melt adhesive, melting at high temperatures, creates a high-quality connection without additional impregnation.

When hot melt adhesive is used, melting at high temperatures, obtained by mixing hot-melt adhesive and polyurethane, a hot-melt adhesive provides quick bonding due to its high binding properties, and polyurethane gives a high bond strength, since polyurethane can penetrate deeper into the plate material, t .to. it requires significantly longer hardening time compared to hot-melt adhesive.

The upper and / or lower surfaces of the plate 1 may have a coating 4 or 5 of different materials, as shown in figure 2. In this case, for coating 4 or 5, dispersion adhesive based on ethylene vinyl acetate (EVA dispersion adhesive) is mainly used, if we are talking about a carpet or other coating for which contact with moisture during operation is completely excluded. Dispersion glue is an inexpensive glue, which is better to use with the use of equipment, since the apparatus and machines used to obtain the adhesive can be washed with water. In addition, dispersion adhesives are environmentally friendly, because they do not contain isocyanates.

When using polyurethane adhesive for coating 4 or 5 as a result of hardening of the polyurethane, a sufficiently rigid joint is formed, which affects the statics of the plate. The hardened polyurethane adhesive acts as a reinforcement and as an element that gives the board rigidity.

Coatings 4 or 5 can be made, for example, of aluminum foil with a thickness of 0.02-0.1 mm Also, on the lower side of the plate, a coating of sheet steel 0.2-1 mm thick can be placed, and the top surface of the plate can be covered with aluminum foil. This has a more favorable effect on the removal of electrostatic charge to metal supports 2.

As another material for coating the plates 1, a high-density laminate material can be used, consisting of several layers of kraft paper impregnated with resin, which in the pressed state can have a thickness of 0.4-0.8 mm.

As another coating material, paper with aluminum sprayed onto it can be used. Paper with sprayed aluminum has a higher tensile strength compared to aluminum foil, as well as a lower specific gravity per unit area.

The above coatings can be used in various combinations on the upper and lower surfaces of the plates, which allows you to coordinate the floor design with the requirements of the customer.

Figure 3 presents the gasket 6, made of electrically conductive plastic, mounted on the upper support plate 2a of the support 2 and provided with four upwardly projecting ridges 6a that enter the gap between two adjacent plates. These protrusions provide contact with the electrically conductive film 30 3, which ensures the removal of electrostatic charge from the upper surface

plate 1 on the supports 2 even in the case when a non-conductive coating 5 is placed on the lower side of the plate 1, and a conductive coating in the form of a film 3 is provided only on the sides of the plate.

Claims (15)

1. A set of elements for a double flooring, in which the plates are installed through supports on the base, and the flooring plate has a carrier layer of wood-particle material, coated on the lower and upper sides of the plate, characterized in that the sides of the plate 1 are coated with an electrically conductive film and beveled in the direction of the lower surface of the plate, as a result of which a gap is formed between the lower surfaces of adjacent plates, and between the plates 1 and the upper supporting surface of the metal support 2 there is a gasket 6 made of electrical odyaschego plastic having protrusions entering into the gap between adjacent plates that provides an electrical contact between the conductive film 3 and metal support 2. 2. A slab for flooring of a double floor, in which slabs are mounted through supports on a base, the slab of the flooring having a carrier layer of wood-particle material, coated on the lower and upper sides of the slab, characterized in that the sides of the slab 1 are coated with an electrically conductive film and beveled in direction of the lower surface of the plate, as a result of which a gap is formed between the lower surfaces of adjacent plates, and a gasket 6 of an electrically conductive plastic is placed between the plates 1 and the upper supporting surface of the metal support 2 ika having protrusions entering into the gap between adjacent plates that provides an electrical contact between the conductive film 3 and metal support 2. 3. The plate according to claim 2, characterized in that the conductivity, respectively, the electrical resistance between the upper and lower surfaces of the plate is more than 100 cm 4. The plate according to claim 2, characterized in that the film 3 is made of fire-resistant material. 5. The plate according to claim 2, characterized in that the film 3 has a thickness of 0.1-2 mm 6. The plate according to claim 2, characterized in that the film material contains means for increasing sliding, allowing adjacent films to easily slide against each other and prevent creaking of the plates. 7. The plate according to claim 2, characterized in that the film 3 is made of ABS plastic. 8. The plate according to claim 2, characterized in that the ultimate (destructive) strength of the plate is 1.2-8 KN with the dimensions of the test sample plate 25 × 25 mm 9. The plate according to claim 2, characterized in that the density of the plate is 400-800 kg / m ³ . 10. The plate according to claim 2, characterized in that hot-melt adhesive is used as the adhesive for applying the film. 11. The plate according to claim 2, characterized in that the film 3 in all its color corresponds to the color of the coating deposited on the upper surface of the plate. 12. The plate according to any one of paragraphs.2-11, characterized in that on the upper and / or lower surface of the plate is coated with aluminum foil with a thickness of 0.02-0.1. 13. A plate according to any one of claims 2 to 11, characterized in that a paper coating with aluminum sprayed onto it is applied to the upper and / or lower surfaces of the plate. 14. The plate according to any one of paragraphs.2-11, characterized in that on the upper and / or lower surfaces of the plate there is a coating of steel or metal sheet. 15. The plate according to claim 2, characterized in that a polyurethane or ethylene vinyl acetate dispersion adhesive is used as an adhesive for coating the upper and / or lower surface of the plate.