DE202021105205U1 - Building board - Google Patents

Abstract

A building panel comprising a first multilayer element with a carrier layer and a reinforcement layer, between which at least one heat-insulating layer bonded to each of the layers is arranged, the carrier layer containing at least one separating layer made of laminated basalt fabric impregnated with an adhesive with an endothermic effect, characterized in that it comprises a second multilayer element which is generally identical to the first multilayer element and is bonded to it with the formation of an air gap between the reinforcement layers of the multilayer elements, the reinforcement layers of the multilayer elements consisting of a basalt grid which is connected to is impregnated with an adhesive with an endothermic effect.

Description

The utility model relates to the field of construction and mechanical engineering, in particular the construction of multi-layer building panels, and it can be used as part of light barriers for sound insulation, noise insulation, thermal insulation of premises and fire protection of buildings as well as in various areas of mechanical engineering both for Protection of devices as well as material for walls, partitions and ceilings in vehicles with different objectives.

Multi-layer panels that are used in construction and mechanical engineering must have high soundproofing properties, lightness, strength, but also fire resistance and high thermal insulation properties.

The multi-layer panels, which comprise various combinations of the materials used for the load-bearing, sound-absorbing and heat-insulating layers, with their different designs are known from the prior art. This variety of solutions results from the requirements with regard to multilayer panels in construction and mechanical engineering: on the one hand, they must have a high level of air and body (footfall) sound insulation, on the other hand, they must be fire-resistant and remain light and at the same time durable. A frequently used solution is the production of sound-absorbing fire-resistant panels from individual sheet materials directly on the construction site, which causes a lot of labor and complex quality control. Such panels are also often not permeable to vapor.

The production of ready-to-install multilayer panels with the best performance for all specified properties is an urgent task for manufacturers today. The difficulties in solving this problem are related to the fact that the materials that are best suited for soundproofing and at the same time light, as such, poorly tolerate the effects of fire and high temperatures. It is necessary that the sound-insulating panels that separate different rooms are fire-resistant and not only effectively prevent the transmission of sound from one room to another room, but also that no structure-borne sound (impact sound) that is transmitted through the load-bearing and structural components of a building or Ship spreads, transferred. It is also important that the erection of a partition wall from such panels is characterized by low labor costs and high speed.

The closest prior art is a multilayer building board, which is described in the German utility model no. 202018106673 (publ. 19.12.2018), comprising a carrier layer and a reinforcing layer, between which at least one heat-insulating layer bonded to each of the layers is arranged, the carrier layer containing at least one separating layer made of laminated basalt fabric that is impregnated with an adhesive.

The disadvantages of the solution described above can be associated with relatively poor performance in terms of sound insulation and mechanical strength.

The task of the claimed utility model is the development of such a building board, the design of which ensures the achievement of the technical result, which consists in increasing the performance of sound insulation, noise insulation and giving the board mechanical strength, such a board being characterized by lightness, vapor permeability and fire resistance.

The object is achieved in that a building board has been developed which comprises a first multilayer element with a carrier layer and a reinforcement layer, between which at least one heat-insulating layer bonded to each of the layers is arranged, the carrier layer containing at least one separating layer made of laminated basalt fabric, impregnated with an adhesive with an endothermic effect. The plate contains a second multilayer element, which is generally identical to the first multilayer element and is connected to it by forming an air gap between the reinforcement layers of the multilayer elements, the reinforcement layers of the multilayer elements consisting of a basalt lattice that is bonded with an adhesive is impregnated with an endothermic effect.

Indeed, the claimed building panel consists of two generally identical multilayer elements joined together to form an air gap between the reinforcement layers of the multilayer elements so that sound waves cannot be transmitted from one multilayer element to the second. Due to the increased requirements for sound insulation, the reinforcement layers consist of a basalt grid that is impregnated with an adhesive with an endothermic effect and has two functions - reinforcing function and at the same time acoustic function - for the unhindered transmission of penetrating sound waves into the heat-insulating porous layer. While maintaining the porous structure of the layer, which is open to sound absorption properties, the plate is preserved at the same time a mechanical strength that prevents bending of the multilayer plate elements. If two multilayer elements are connected to form a panel, with the reinforcement layers of the multilayer elements consisting of a basalt lattice impregnated with an adhesive with an endothermic effect and located inside the panel, a relatively high level of sound insulation is achieved by the panel. The carrier layers, which contain at least one separating layer made of laminated basalt fabric impregnated with an adhesive with an endothermic effect, are compacted and located on the outside of the panel, which is important for the sound insulation properties. The complete absence of rigid structural connections between the load-bearing and reinforcing layers of the elements also significantly improves the soundproofing properties of the panel. It should be noted that the plate is made of different materials in terms of both density and structure and at the same time is vapor-permeable. The fire-resistant, water-based adhesive with an endothermic effect, which connects the parts of the multilayered elements, consists of natural components of rock flour. The carrier and reinforcement layers are impregnated with the same adhesive. After the adhesive has hardened with an endothermic effect and the water has evaporated, the properties of the adhesive layer are similar to those of the ceramic and are vapor-permeable. Laminated basalt mesh and basalt mesh, which are included in the composition of the support layer and the reinforcement layer, respectively, are fire-resistant, light and durable, and also have a high heat capacity. Of course, the carrier layer can contain one or more separating layers of laminated basalt fabric impregnated with an adhesive with an endothermic effect, in other words, the laminated basalt fabric impregnated with an adhesive having an endothermic effect can be used to create a carrier layer or separating layers that support the The carrier layer or the carrier layer itself can be a laminated basalt fabric which is impregnated with an adhesive with an endothermic effect.

It should be noted here that the heat-insulating layer is glued over the entire surface with an adhesive with an endothermic effect to the carrier layer and / or to the reinforcement layer. Thus, when using an adhesive with an endothermic effect, the passage of thermal energy to the connecting profiles is prevented. The heat-insulating layer can, however, also be glued to the carrier layer and / or to the reinforcing layer in point and / or linear fashion. In such a case, the endothermic effect adhesive may be applied with a certain spacing between points and / or lines around the periphery of the heat insulating layer, or it may be applied by any other manner suitable for applying the adhesive. Of course, the adhesive can be applied over the entire surface of the carrier layer and / or the reinforcement layer in order to bond them to the heat-insulating layer. In order to increase the endothermic effect, the adhesive with an endothermic effect is used in the construction of the multilayer panels according to the claimed utility model not only to connect the carrier and reinforcement layers to the heat-insulating layer, but also as part of the carrier and reinforcement layer. The impregnation of a separating layer made of laminated basalt fabric and basalt mesh with an adhesive with an endothermic effect increases the fire resistance of the building board. Bonded parts of the multi-layer elements such as the heat-insulating porous layer, the basalt fabric and the basalt lattice are vapor-permeable. Thus, the multilayer elements and a plate are overall vapor permeable.

The multilayer elements are preferably connected to one another by at least two rigid connecting profiles which contain an end face and flanges which can be arranged in the heat-insulating layer. The multi-layer elements of the plate are connected by rigid connecting profiles that have no direct contact with the carrier and reinforcement layers, but are instead inserted into the heat-insulating layer. It is advisable to make such profiles from metal in order to ensure the rigidity and reliability of the connection of the multilayer elements that make up the building panel. The arrangement of the connection profiles in the heat-insulating layer prevents the transmission of sound waves and thermal energy through the connection profiles (metal profiles) of the panel and ensures increased sound insulation, thermal insulation and fire resistance.

In another preferred embodiment of the utility model, the flanges are solid. This means that the flanges do not contain any cutouts. This ensures maximum contact between the flanges and the heat-insulating layer in which they are located and guarantees an even more secure connection between the multilayered elements. It is also preferred, but not necessary, that the length of the flanges be equal to the length of the heat insulating layer in which they are located. A U-shaped profile (channel) can be cited as one of the possible design variants of connecting profiles.

In another embodiment of the utility model, the flanges are designed with cutouts. Since the connecting profile is preferably made of metal, such a variant of the flange makes the metal portion of the The connecting profile structure and the weight of the plate are reduced, but a reliable connection between the multilayer elements is also guaranteed.

Also preferably one of the connection profiles contains a pin and the second connection profile contains a slot.

In one of the preferred embodiments of the utility model, one of the connecting profiles contains two pins and the second connecting profile contains two slots. Both the pin and the slot are made in the face of the connecting profile.

The connection of building panels with each other can preferably be done in the manner of "slot and tenon" that is implemented on their connecting sides when they are installed in the wall system, the tenons and slots being designed in the form of homogeneous convex-concave longitudinal elements in adjacent connecting profiles. The connection sides of a building board are understood to mean the sides on which the connection profiles are located. It is obvious that the connection profile of one plate, which has a slot, is connected to the connection profile of the other plate, which has a pin.

The carrier layer preferably contains a decorative coating made of reinforced ceramic glaze. Such a decorative layer gives a multilayer board an aesthetic appearance and additionally improves the strength properties of the board.

• 1 ist ein Querschnitt eines mehrschichtigen Elements gemäß einer bevorzugten Ausführungsform des beanspruchten Gebrauchsmusters.
• 2 ist ein Querschnitt einer Bauplatte gemäß einer bevorzugten Ausführungsform des beanspruchten Gebrauchsmusters.
• 3 ist eine Seitenansicht einer Bauplatte gemäß einer bevorzugten Ausführungsform des beanspruchten Gebrauchsmusters.
• 4 ist ein Querschnitt von zwei Bauplatten, die in Schlitz- und Zapfenverbindung miteinander stehen, gemäß einer bevorzugten Ausführungsform des beanspruchten Gebrauchsmusters.

Preferably the heat insulating layer is made of mineral wool material. The open-pore structure of the heat-insulating layer of the multi-layer elements, in combination with the carrier and reinforcement layers, ensures a high level of sound absorption.

• 1 Figure 3 is a cross-section of a multilayer element according to a preferred embodiment of the claimed utility model.
• 2 Figure 3 is a cross-section of a building board according to a preferred embodiment of the claimed utility model.
• 3 Figure 3 is a side view of a building panel according to a preferred embodiment of the claimed utility model.
• 4th Fig. 3 is a cross-section of two building panels which are in mortise and tenon connection with one another, according to a preferred embodiment of the claimed utility model.

1 Figure 3 shows a cross-sectional view of a multilayer element 1 according to a preferred embodiment of the claimed utility model, which has a carrier layer 2 and a reinforcement layer 3 includes, between which a heat insulating layer 4th is arranged. The heat insulating layer 4th is with each of the layers 2 and 3 over the entire surface with an adhesive 5 glued with an endothermic effect. On the carrier layer 2 is a decorative coating 6th Applied from reinforced ceramic glaze, with between the carrier layer 2 and the decorative coating 6th also an adhesive 5 is applied with an endothermic effect.

2 Figure 3 is a cross section of a building board 7th according to a preferred embodiment of the claimed utility model, the two multilayer elements 1 Contains that by two rigid connecting profiles 8th are connected to one another, one end face 9 and flanges 10 included in the insulating layer 4th forming an air gap 11th are arranged. One of the connection profiles 8th contains a peg 12th , and the second connection profile contains a slot 13th . The elements that match the elements in the 1 are identical are provided with the same reference numerals.

3 is a side view of a building panel according to a preferred embodiment of the claimed utility model, and 4th Figure 3 is a cross-section of two building panels which are mortise-and-tenonly connected to one another, according to a preferred embodiment of the claimed utility model, wherein the elements that correspond to the elements in FIG 1-2 are identical, are provided with the same reference numerals. The layers are shown with different shades to illustrate different materials of the layers.

The connection of the building panels 7th to a wall system is done by applying an adhesive for metal to the surface of the end faces 9 of the neighboring connecting profiles 8th and then joining the building panels together, one tenon 12th and a slot 13th be connected to each other. The presence of an air gap and the complete absence of the rigid structural connections between the load-bearing basalt ceramic layers of the panels significantly improves the soundproofing properties of the building panel and of the wall system made from such panels. When installed, the wall system is soundproofed from the floor and ceiling with 12 mm sound-absorbing seals made of basalt fiber material. This ensures protection against structural noise that is transmitted through false ceilings.

So a building board was developed, the construction of which is the achievement of the technical The result is to increase the performance of soundproofing, soundproofing and to give the panel mechanical strength, such panel being characterized by lightness, vapor permeability and fire resistance.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 202018106673 [0005]

Claims (8)

A building panel comprising a first multilayer element with a carrier layer and a reinforcement layer, between which at least one heat-insulating layer bonded to each of the layers is arranged, the carrier layer containing at least one separating layer made of laminated basalt fabric impregnated with an adhesive with an endothermic effect, characterized in that it comprises a second multilayer element which is generally identical to the first multilayer element and is bonded to it with the formation of an air gap between the reinforcement layers of the multilayer elements, the reinforcement layers of the multilayer elements consisting of a basalt grid which is connected to is impregnated with an adhesive with an endothermic effect. The building board after Claim 1 , characterized in that the multilayer elements are connected to one another by at least two rigid connecting profiles which contain an end face and flanges which can be arranged in the heat-insulating layer. The building board after Claim 2 , characterized in that the flanges are solid. The building board after Claim 2 , characterized in that the flanges are made with cutouts. The building board after Claim 2 , characterized in that one of the connection profiles contains a pin and the second connection profile contains a slot. The building board after Claim 2 , characterized in that one of the connecting profiles contains two pins and the second connecting profile contains two slots. The building board after Claim 1 , characterized in that the carrier layer contains a decorative coating made of reinforced ceramic glaze. The building board after Claim 1 , characterized in that the heat insulating layer is made of mineral wool material.

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