EA046830B1 - BUILDING PLATE - Google Patents

Abstract

The present invention concerns a building board having a first multilayer element with a supporting and reinforcing layer, between which at least one heat-insulating layer is located, connected to them, wherein the supporting layer has at least one separating layer of laminated basalt fabric impregnated with glue, in which, when exposed to high temperatures, an endothermic reaction occurs, i.e. cooling occurs, wherein the building board has a second multilayer element, which is essentially identical to the first multilayer element and is connected to it in a mirror image by creating a gap between the internal reinforcing layers, the reinforcing layers of the multilayer elements have a basalt mesh impregnated with glue with an endothermic effect, and the multilayer elements are connected to each other by at least two connecting profiles located in the heat-insulating layer.

Description

The present invention relates to the field of construction and mechanical engineering, in particular to the structures of multilayer building boards according to claim 1 of the formula, and can be used as part of a lightweight barrier for sound insulation, noise insulation, thermal insulation of premises and for fire protection of buildings, as well as in various fields of mechanical engineering such as protection of devices, and as a material for walls, partitions and ceilings in vehicles for various purposes.

Multilayer boards used in construction and mechanical engineering must have good sound and heat insulation properties, be light, durable, and fire-resistant.

In modern technology, multilayer slabs are known, consisting of various combinations of materials used for load-bearing, sound-proofing and heat-insulating layers, in a variety of shapes. This variety of solutions arose from the requirements for multilayer boards in construction and mechanical engineering: on the one hand, they must have good sound insulation from airborne, structure-borne and impact noise, on the other hand, they must be fire-resistant, and at the same time remain light and durable.

A frequently used solution is to manufacture soundproofing, fire-resistant slabs from individual sheet materials directly on the construction site, which requires high labor costs and comprehensive quality control. Also, these slabs, as a rule, are not vapor permeable.

Producing ready-to-install multilayer boards with the best performance for all specified properties is a pressing challenge for manufacturers today. The difficulty in solving this problem stems from the fact that materials that are best suited for sound insulation and at the same time are lightweight, do not cope well with exposure to fire and high temperatures. It is necessary that soundproofing slabs separating different rooms be fire-resistant and not only effectively prevent the spread of sounds from one room to another, but also not transmit structure-borne (impact) noise emanating from the load-bearing or structural elements of a building or ship. It is also important that the construction of a partition from such slabs is characterized by low labor intensity and high speed.

The next stage in the development of technology is a multilayer building board, presented in the registered industrial design of Germany No. 202018106673 (publication dated December 19, 2018), consisting of a load-bearing and reinforcing layer, between which there is at least one thermal insulation layer, glued to each of the layers, with In this case, the supporting layer has at least one separating layer of laminated basalt fabric impregnated with glue.

The disadvantages of the above solution include the relatively low quality of sound insulation and low mechanical strength.

The claimed invention solves the problem of creating a slab with high sound insulation for interior decoration, which, with increased mechanical strength, is light, vapor-permeable and fire-resistant.

The problem was solved by the inventor in the form of a plate according to claim 1 of the formula.

The building slab contains a load-bearing and reinforcing layer, between which there is at least one thermal insulation layer glued to them, while the load-bearing layer has at least one separating layer of laminated basalt fabric impregnated with glue, while in the glue, when exposed to high temperatures, an endothermic reaction occurs, causing cooling. The building slab has a second multi-layer element, which is essentially identical to the first multi-layer element and is mirror-connected to it by creating a gap between the internal reinforcing layers. In this case, the reinforcing layers of multilayer elements have a basalt mesh impregnated with glue with an endothermic effect; the multilayer elements are connected to each other by at least two connecting profiles located in the heat-insulating layer.

Preferred forms of execution are indicated in the attached formula.

In the thermal insulation layer can, according to the present invention, in particular mean that the connecting profile does not touch the load-bearing layer 2 and/or the reinforcing layer 3, which prevents the transmission of sound waves from one side of the building board to the other.

The connecting profiles may preferably be rigid, which reliably provides a defined gap between the two multilayer elements.

It can be noted that the invention is implemented at least only if two multilayer elements are located in the building slab with a gap between them, and each multilayer element has at least one external sound-reflecting load-bearing layer and one internal, porous sound-absorbing layer, connection (connecting profile) of both multilayer elements holds both elements and is acoustically decoupled at a certain distance. Preferably, a porous, sound-absorbing layer can be placed between two layers, namely, load-bearing and reinforcing.

The sound-absorbing layer can also be considered heat-insulating. It is preferable to use ceramic glue for this. Placing a porous sound-absorbing layer between

- 1 046830 with reinforcing and load-bearing layers improves, in relation to placement without a reinforcing layer, the flexural strength of the multilayer element and, thus, the strength of the building slab as a whole.

It is desirable that the outer load-bearing layers of the finished building slab have a smooth, closed structure that reflects sound. The reinforcing layer, in contrast, may have an open-cell structure that facilitates the passage of sound into and through the gap within the slab, where residual sound transmitted through the first porous sound-absorbing layer is absorbed by the second, porous sound-absorbing layer.

The gap, according to this invention, is made, preferably through. Thus, there are no construction bridges, in particular sound transmission bridges, in the gap.

The reinforcing layer may consist of a basalt mesh, which is preferably impregnated with an endothermic adhesive.

According to the preferred form of execution of this invention, the building slab can be made as follows: a first multilayer element is made with load-bearing and reinforcing layers, between which there is at least one heat-insulating, porous sound-absorbing layer connected to them, and the load-bearing layer has at least one separating layer a layer of laminated basalt fabric impregnated with glue with an endothermic effect.

In this case, the slab has a second multilayer element, which is basically identical to the first multilayer element and is connected to it by creating a gap between the internal reinforcing layers of the multilayer elements. The reinforcing layers of multilayer elements have a basalt mesh impregnated with an adhesive with an endothermic effect.

In this case, the building slab, according to the invention, can consist of two generally identical multilayer elements, which are connected in such a way that a gap is formed between the reinforcing layers of the multilayer elements, i.e. sound waves from one multilayer element cannot be transmitted to a second element through the connection. Due to the increased requirements for sound insulation, the reinforcing layers contain a basalt mesh impregnated with glue with an endothermic effect and performing two functions - reinforcement and, at the same time, acoustic - for the unhindered passage of penetrating sound waves into the thermal insulating, porous layer of the multilayer element located opposite. While maintaining the porous structure of the layer, open for sound absorption, the slab simultaneously gains mechanical strength, which prevents bending of the multilayer elements of the slab. If two multilayer elements are connected into one slab, and the reinforcing layers of the multilayer elements have a basalt mesh, which is preferably impregnated with an endothermic adhesive and they are located on the inside of the building slab, i.e. turned towards the gap, relatively high sound insulation is achieved throughout the entire slab. In this case, the supporting layers have a separating layer of laminated basalt fabric, which is preferably impregnated with an adhesive with an endothermic effect. The separating layers can be compacted and located on the outside of the slab, which is advantageous for sound insulation properties and, in particular, for sound reflection.

The absence of rigid structural connections of the load-bearing and reinforcing layers of both multilayer elements also helps to improve the sound insulation properties of the building slab. It should be taken into account that the slab, both in terms of density and structure, consists of various materials and is, at the same time, vapor permeable. Parts of multilayer elements are impregnated with fire-resistant, water-repellent adhesive with an endothermic effect.

It is preferable to impregnate the load-bearing and reinforcing layers with the same glue.

After the adhesive has cured with an endothermic effect and the water has evaporated, the adhesive layer becomes similar in properties to ceramics and is vapor-permeable. Laminated basalt fabric and mesh, which are part of the load-bearing or reinforcing layer, are fire-resistant, lightweight and durable, and also have a high heat capacity. Of course, the support layer may have one or more spacer layers of laminated basalt fabric impregnated with an endothermic adhesive, in other words, it is possible to use a laminated basalt fabric impregnated with an endothermic adhesive to create a support layer or spacer layers forming a support layer or a load-bearing layer. the layer itself may be a laminated basalt fabric impregnated with an endothermic adhesive.

It should be taken into account that the heat-insulating layer/porous sound-absorbing layer is glued, using adhesive with an endothermic effect, to the load-bearing and reinforcing layers, preferably over the entire surface. This prevents the transfer of thermal energy to the connecting profiles when using an endothermic adhesive. The thermal insulation layer can, however, be glued to the load-bearing and/or reinforcing layer pointwise and/or along lines. In this case, the endothermic adhesive can be applied with a certain distance between dots and/or lines around the perimeter of the thermal insulation layer or can be applied in another way suitable for applying the adhesive. Of course, adhesive can be applied over the entire surface of the load-bearing and/or reinforcing layer in order to adhere them to the thermal insulation layer. To enhance the endothermic effect, glue in the construction of multilayer boards can be used, according to the invention, not only for

- 2 046830 connections, but also be part of the load-bearing and reinforcing layers. Impregnation of a separating layer of laminated basalt fabric and/or basalt mesh with an endothermic adhesive increases the fire resistance of the building slab. The glued parts of the multilayer elements, the heat-insulating/sound-absorbing porous layer - basalt fabric and basalt mesh, are vapor-permeable. Thus, the multilayer elements and the slab as a whole are vapor permeable.

It is advisable to connect multilayer elements to each other with at least two rigid connecting profiles, preferably with an end and a flange, which can be placed in the thermal insulation layer. Multilayer elements of a building slab are connected by rigid connecting profiles that do not have direct contact with the load-bearing and reinforcing layers, but are simply embedded in a thermal insulation layer. It is recommended to make such profiles from metal to ensure rigidity and reliability of the connection of the multilayer elements that form the building slab. Placing connecting profiles in the thermal insulation layer prevents the transmission of sound waves and thermal energy through the connecting profiles (metal profiles) of the slab and provides increased sound insulation, thermal insulation and fire resistance.

In another preferred embodiment of the present invention, the flanges are solid. This implies that there are no cutouts in the flanges. This ensures maximum contact between the flange and the heat-insulating layer in which it is placed, and a more reliable connection of the multilayer elements to each other. It is desirable, but not necessary, that the length of the flange be equal to the length of the heat-insulating layer in which it is located. A channel (channel) can be considered as a possible design option for connecting profiles. In another preferred embodiment of the present invention, the flanges have cutouts. Since the connecting profile is made of metal, this type of flange design reduces the amount of metal in the structure of the connecting profile and, thus, the weight of the slab, but reliable connection of the multilayer elements to each other remains guaranteed.

It is also desirable that one of the connecting profiles has a tenon, and the second connecting profile has a groove.

In one of the preferred designs of the prototype, one of the connecting profiles has two tenons, and the second connecting profile has two grooves. Both the tenon and the groove are made at the end of the connecting profile.

The connection of building slabs can, preferably, be made using the tongue-and-groove type, which is implemented when installed in a wall system on the sides of the connection, while the tenons and grooves can be made in the form of homogeneous convex-concave longitudinal elements in the adjacent connecting profiles. The connection sides of a building slab are those sides on which the connection profiles are located. It is obvious that the connecting profile of one plate, which has a groove, is connected to the connecting profile of another plate, which has a tenon.

It is desirable that the supporting layer has a decorative coating of reinforced ceramic glaze. Such a decorative layer gives the multilayer slab an aesthetic appearance and further improves the strength characteristics of the slab.

It is advisable to make the thermal insulation layer from mineral wool mats.

The open-pore structure of the thermal insulation layer of the multilayer element ensures, in combination with the load-bearing and reinforcing layers, high sound absorption.

In fig. Figure 1 shows a cross-section of a multilayer element according to the preferred form of execution of the prototype under consideration.

In fig. Figure 2 shows a cross-section of a building slab in accordance with the chosen form of execution of the prototype under consideration.

In fig. Figure 3 shows a side view of the building slab according to the preferred form of execution of the prototype under consideration.

In fig. Figure 4 shows two building slabs in cross-section, connected to each other according to the shippaz type according to the preferred form of execution of the prototype in question.

In fig. 1 shows a cross-section of a multilayer element 1 according to the preferred embodiment of the present invention, where a load-bearing layer 2 and a reinforcing layer 3 are presented, between them there is a heat-insulating layer 4, which has sound-absorbing properties. The thermal insulation layer 4 is glued over the entire surface to each of layers 2 and 3 with glue 5 with an endothermic effect. A decorative coating 6 of reinforced ceramic glaze can be applied to the supporting layer 2, and adhesive 5 with an endothermic effect can also be applied between the supporting layer 2 and the decorative coating 6.

In fig. 2, the building slab 7 is presented in cross-section according to the preferred form of execution of the present invention, consisting of two multi-layer elements 1, which are connected to each other at least preferably by two rigid connecting profiles 8, having an end 9 and a flange 10, which are placed in the heat-insulating layers 4 of the multi-layer elements With

- 3 046830 by creating a gap 11. One of the connecting profiles 8 preferably has a tenon 12, and the second connecting profile has a groove 13.

Elements that are identical to those in FIG. 1 have similar item numbers.

A side view of a building board according to a preferred embodiment of the present invention is shown in FIG. 3, and in FIG. 4 shows a cross-section of two building boards connected to each other in a tongue-and-groove manner by means of connecting profiles 8 according to a preferred form of use of the present invention, elements which are identical to those in FIG. 1-2 have similar item numbers. Layers have different shading to make different materials and/or layer thicknesses easier to see.

The connection of building boards 7 into a wall system can be done by applying metal adhesive to the surface of the ends 9 of adjacent connecting profiles 8 and then joining the building boards. In this case, the tenon 12 and groove 13 will be connected to each other. The presence of a gap and the complete absence of rigid structural connections between the load-bearing basalt-ceramic layers of multilayer elements located opposite each other significantly improves the soundproofing properties of the building slab and wall system made from such slabs. During installation, it is desirable to soundproof the wall system from the floor and ceiling with soundproof seals 12 mm thick made of basalt fabric. This guarantees protection against structural noise that is transmitted through the ceilings.

According to this invention, a building slab has been developed, the design of which ensures the achievement of a technical result, which is to improve the quality of sound and heat insulation and give the slab mechanical strength. Such a plate, at the same time, is lightweight and vapor permeable, and is also fire resistant.

Each multilayer element can consist of two load-bearing layers (load-bearing layer 2 and reinforcing layer 3), which are respectively glued with ceramic adhesive 5 to both surfaces of the porous thermal insulation layer 4 and thereby form a sandwich structure. The load-bearing layer 2 and the reinforcing layer 3 can functionally eliminate deflection of both the elements of the multilayer slab and the building slab as a whole.

There is no direct contact between the load-bearing layer 2 and the reinforcing layer 3, there is no rigid structural connection, which also significantly improves the soundproofing properties of the slab.

Structurally, the building board can consist of two composite sandwich panels connected to each other, between which there is a gap 11. The composite sandwich panels are smooth and durable on the outside, and the inside side facing the gap has an open-pore structure. Each of the two layers performs its own specific function of rigidity, sound insulation and non-flammability, while the slab remains light and vapor permeable at the same time. For example, steel connecting profiles in the form of channels 8 connect two multilayer composite panels into one panel (building slab) and prevent the transfer of thermal energy and sound waves through them, while the convex-concave elements 12 and 13 of the panels are located exactly in same level.

The functions and structural features of the other components of the building board will be described below.

The load-bearing layers 2 of both multi-layer building board elements have at least one layer of laminated basalt fabric, which is impregnated on both sides with endothermic ceramic adhesive 5.

The load-bearing layers 2 are located on the outer side of the slab and take on, in particular, possible mechanical stress.

The supporting layer 2 may have one or more layers of laminated basalt fabric impregnated with an endothermic adhesive.

If the support layer has several layers, they can consist of several laminated basalt fabrics, which can be firmly connected to each other with endothermic ceramic adhesive 5. In other words, basalt fabric impregnated with endothermic adhesive can be used to create a lining layer or separating layers. layers forming the lining layer, or the lining layer itself, can be laminated basalt fabric impregnated with ceramic adhesive with an endothermic effect 5.

The supporting layer 2 is preferably a multilayer, non-flammable laminate of basalt and ceramics, on the outer side of which during its manufacture a smooth decorative layer 6 of ceramic adhesive and fibers can be applied by pressing.

Structurally, the surface load-bearing layer is a multilayer ceramic reinforced with basalt textiles. After the adhesive has cured with an endothermic effect and the water has evaporated, the adhesive layer 5 has properties similar to ceramics and is vapor permeable.

After the glue 5 hardens, it becomes similar in its physical properties to stone, which is reinforced inside with high-strength fibers and protected from cracking. The proportion of basalt fibers in load-bearing layer 2 can range from 8 to 29%, depending on the fire resistance class of the slab and the desired level of sound insulation.

- 4 046830

The load-bearing layer 2 can simultaneously perform three functions - rigidity, decoration and acoustics. In terms of strength, the basalt and ceramic composite laminate is superior to steel and yet four times lighter. The decorative coating 6 can be applied simultaneously with the production of multilayer building board elements. The acoustic properties of multilayer basalt and ceramic laminate remain high due, first of all, to its high density and smooth surface of the decorative layer, which leads to good reflection of sound waves.

The thermal insulation porous layer 4 of the multi-layer building board element may consist of a non-combustible mineral wool body, which has excellent sound-absorbing properties.

In this case, the porous thermal insulation layer 4 can have density and mechanical strength for reliable adhesive fastening of the flanges 10 of steel channels 8, i.e. connecting profiles at the ends of the thermal insulation layers 4 in the body of their porous structure to connect both multilayer elements into one panel - a building slab.

This type of profile fastening offers reliable protection both from the transmission of sounds through these profiles and from the transfer of heat to the back side of the slab.

Sound waves that penetrate through the first multilayer panel (multilayer element) into the gap 11 between the panels are captured between two structures with up to 80% open pores of the thermal insulation layers and do not contact dense materials for energy transfer, i.e. they cannot be transmitted from one multilayer panel to another, which guarantees good insulation of sound waves.

This symmetrical construction of the building slab has a significant advantage over the asymmetrical elements known today.

Profiles connect both multilayer elements into one panel - a building board.

In this case, the channels 8 on the wall 9 between the flanges 10 can have concave-convex elements 12 and 13, which quickly and reliably provide a flat wall when installing building slabs.

The load-bearing reinforcing layer 3 performs two functions: reinforcing and acoustic at the same time, ensuring the strength of the sandwich panel and the unhindered transmission of penetrating sound waves into the heat-insulating porous layer 4.

The load-bearing reinforcing layers 3 are located inside the building slab, with a gap 11 between them, opposite each other.

The load-bearing reinforcing layers of 3 multilayer slabs can have a basalt-ceramic mesh with a perpendicular structure, i.e. basalt fibers impregnated with ceramic glue with an endothermic effect 5.

Structurally, the mesh rods of the load-bearing reinforcing layers are ceramics reinforced with basalt fibers. In terms of physical properties, once the adhesive has cured, it becomes like stone, reinforced with high-strength fibers and protected from cracking.

Thanks to the use of a reinforcing layer with a mesh structure, 80% of the surface of the porous structure of the thermal insulation layer remains open and only 20% of the surface is used for contact with the basalt mesh through ceramic adhesive. Thanks to this design solution, sound waves penetrating into the panel are very effectively damped on both sides by the porous structure of the thermal insulation core and converted into thermal energy.

The supporting layer 2 and the reinforcing layer 3 are laminated basalt fabric, which, after hardening, has the properties of ceramics. There may be a slight difference, however, in the structure of the fabric that is used to make the load-bearing layer 2 and the reinforcing layer 3. For lamination of the lining/load-bearing layer 2, it is preferable to use a strong, dense fabric. To laminate the reinforcing layer 3, it is preferable to use mesh textiles, in which the difference between the thickness of the mesh rod and the thickness of the side size of the square cell is a ratio of 1:5.

This means that the mesh fiber/rod thickness is, for example, 2 mm and the mesh size is 10x10 mm. This design of the load-bearing reinforcing layer ensures the absorption of mechanical loads and, at the same time, allows achieving sound permeability of 70%.

The carrier layer 2 should, if possible, have no pores or have a small number of pores in order to ensure particularly reliable sound reflection.

The preferred porosity of the mineral wool thermal insulation layer 4 is 60-98, preferably 93%. Assuming that the open cell area in the mesh reinforcing layer is 70%, then the minimum porosity of the reinforcing layer 3 should be 65%.

Claims (5)

1. A building slab consisting of a multilayer element (1) with a load-bearing layer (2) and a reinforcing layer (3), between which there is at least one heat-insulating layer (4), glued to each of the layers, while the load-bearing layer has at least one separating layer of laminated basalt fabric impregnated with ceramic glue (5), characterized by the fact that in the glue (5), when exposed to high temperatures, an endothermic reaction occurs with a cooling effect; the building slab has a second multilayer element (1) corresponding to the first multilayer element, which is connected to it by creating a gap between the internal reinforcing layers (3) in a mirror image, while the reinforcing layers (3) of the multilayer element (1) have a basalt mesh impregnated ceramic glue; and multilayer elements are connected to each other by at least two connecting profiles placed in the thermal insulation layer. 2. A building board according to claim 1, characterized in that the connecting profiles (8) are glued into the heat-insulating layer (4). 3. A building board according to claim 2, characterized in that one of the connecting profiles has one or two tenons, and the second connecting profile has one or two grooves. 4. A building board according to claim 1, characterized in that the load-bearing layer has a decorative coating of reinforced ceramic glaze. 5. Construction board according to claim 1, characterized in that the thermal insulation layer (4) is made of mineral wool.