RU2372454C1 - Wall multi-layer heat-insulation panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: wall multi-layer heat-insulation panel is related to construction, in particular to manufacturing of multi-layer wall structures of sandwich panels with improved physical-technical characteristics, used in carcass construction. Wall multi-layer heat-insulation panel comprises two surface layers, between which there are heat insulation layers installed, being assembled from blocks of foam glass laid as layerwise in rows with bonding of seams, preferably in neighboring layers, at the same time all components of panel structure are attached to each other by means of adhesive composition. Surface layers are made of metal sheets. Medium heat-insulation layers, number of which is at least two, are arranged as relative to each other so that at least one heat insulation layer is displaced relative to each other, preferably adjacent to it, by distance of at least block thickness, but not more than 1/2 of horizontal size of single assembly block of foam glass. Produced displacements of end surfaces of border blocks of panel are mirrorlike to each other and create a lock view of "thorn-groove" type, which helps to connect single-type panels to each other.

EFFECT: creation of reliable wall structure with high gas and heat protective properties without application of structural additional elements, and also high operational characteristics, in part of higher reliability and product service life.

3 cl, 5 dwg

Description

The invention relates to the construction, in particular the manufacture of multilayer wall structures (sandwich panels) with improved physical and technical characteristics used in frame construction. The invention also relates to a method of manufacturing such structures.

Multilayer sandwich panels are known in the art in which polystyrene foam is the central heat-insulating layer. Using it allows you to improve such characteristics of a sandwich panel as strength, durability and thermal insulation properties, while having a lower cost (in comparison with mineral wool filler). However, a sandwich panel with polystyrene boards has a significant drawback, such as a low degree of fire resistance, which limits their use in construction.

In the patent of the Russian Federation No. 2280132, published on July 20, 2006, class IPC E04C 2/24, E04C 2/292, a building sandwich panel for building envelopes of buildings and structures, roofing is described. This sandwich panel includes two surface layers of metal and a central part composed of pieces of mineral wool constituting longitudinal strips parallel to the longitudinal axis of the panel, and the orientation of the fibers in the pieces is perpendicular to the plane of the surface layers. Between the strips of pieces of mineral wool, longitudinal strips of pouring polystyrene are additionally introduced. The number of bands of mineral wool in the group is from 1 to 4, while the extreme stripes of the panel are composed of mineral wool. The width of the strip of the filling foam is 1-4 of the width of the piece of mineral wool, and the length of the strips is the length of the panel. The claimed technical result is an increase in the strength of the panel while maintaining sound insulation and fire resistance, as well as an increase in thermal insulation properties and service life.

This panel design has disadvantages associated with the complexity of its manufacture due to the use of two different heat-insulating materials, and also does not solve the problem of obtaining a non-combustible sandwich panel.

In the patent of the Russian Federation No. 62411, published on November 30, 2006 according to the class IPC E04C 2/00, the utility model “Three-layer metal sandwich panel” is declared, which is a three-layer structure with metal sheet cladding and a middle insulation layer, characterized in that it is used as an insulating layer layers use a combined layer consisting of expanded polystyrene and mineral wool based on basalt rocks. Heat-insulating layers located in layers parallel to the outer metal sheets are interconnected by means of glue. The disadvantage of this design is also the complexity of the process, due to the use of two different heat-insulating materials, as well as limited fire and chemical resistance (is destroyed under the influence of ultraviolet radiation, oxygen, flame).

A known design of a multilayer panel made according to the method described in the patent of the Russian Federation No. 2173752, published on 09/20/2001 according to classes IPC Е04С 2/26, С04В 28/24, С04В 28/26. The multilayer panel is assembled from sheathing metal sheets with a groove-to-protrusion shape of a predetermined triangular profile, which are placed in a restrictive form, into the cavity of which a foam silicate composition based on hollow ash microspheres is used as a refractory filler and liquid glass as a binder. The sandwich elements thus obtained are assembled into a multilayer panel, and the joints are filled with a foam silicate composition. As external limiting elements use the profile of the aluminum brand AMG-6. The edge sections of the external restrictive elements are rigidly fixed with contour fittings in the form of fixation elements. This technical solution claims a technical result related to the lightness of the panel, ensuring the tightness and continuity of the finished structure, which contributes to low smoke and flame permeability. The disadvantages of such designs include the high cost of the product, due to the duration and complexity of the process.

The closest in technical essence and the achieved result is a wall panel for cladding and insulation of building structures according to the patent of the Russian Federation No. 2275480, published on 04/27/2006 in class IPC E04F 13/14. The wall panel consists of a structural layer, to the back of which, by means of an adhesive composition, heat-insulating material is attached, in the form of blocks arranged in rows, which are laid with ligation of the seams. As a heat-insulating layer according to the invention, layers of foamed heat-insulating material with closed pores (foamglass, polyurethane foam, polystyrene foam) are used. However, this heat-insulating panel is facing, but not enclosing, which leads to the use of one structural layer (a sheet of silicate glass or porcelain tile). The second structural layer in the wall panel is absent; it is replaced by the facade surface of the building on which the panel is mounted. As a result of this, additional structural elements (layers of reinforcing mesh, anchor bolts, longitudinal and / or transverse grooves, glued joints between the ends, etc.) appear on the wall panel. This complicates not only production technology, but also installation directly at the construction site. In addition, during the operation of such panels, gas-tight joints (“cold bridges”) arise due to the absence of a heat-insulating layer at the joints and a lock joint. In addition, the use of layers of organic heat-insulating materials (polyurethane foam, expanded polystyrene) reduces the design life.

The objective of the invention is to create a wall panel design that eliminates heat loss and gas tightness at the joints of the panels, while simplifying the technology of its production and use, as well as the possibility of creating various docking forms with minimal machining.

A positive result of the invention is the creation of a reliable wall structure with high gas and heat-shielding properties without the use of structural additional elements, as well as high performance characteristics, in particular, increased reliability and service life of the product.

The technical result is achieved in the design of the wall multilayer heat-insulating panel, including two surface layers, between which are the heat-insulating layers, assembled from foam glass blocks, laid in layers in rows with ligation of the seams, preferably in adjacent layers, while all the constituent structural elements of the panel are bonded to each other by means of an adhesive composition, in which, unlike the prototype, the surface layers are made of metal sheets, and the middle heat-insulating layers, the amount of which x is not less than two, are arranged relative to each other so that a heat-insulating layer is biased relative to the other, preferably adjacent thereto, for a distance of at least thickness of the block but not more than _^1/2 of the horizontal dimension of the assembly block of foam glass, thus obtained offset end the surfaces of the boundary blocks of the panel are mirrored with respect to each other and form a spike-groove castle view, which facilitates the connection of the same type of panels to each other.

The number of heat-insulating layers is determined by calculation, based on the technical requirements for the wall panel, and is preferably from two to five layers.

With an increase in the number of heat-insulating layers, they can be displaced relative to each other in various ways of alternating displacement through a row or in each row. In this case, the ends of the panel with the horizontal arrangement of all layers will have the form of a broken line of various shapes, with the depth of the groove and the protrusion-spike of the tongue-and-groove joint lock corresponding to the dimensions of the locks of the surface layers.

The combination of the foregoing features provides the claimed technical result due to the original design of the panel with the possibility of using various manufacturing options in shape and dimensions. The use of foam glass blocks contributes to obtaining all the necessary modern qualities required for wall panels, with the possibility of widespread use in construction: high strength, acceptable weight of structures, high fire resistance, thermal insulation, the possibility of sealed assembly of many panels.

The possibility of carrying out the invention, characterized by the above set of features, as well as the possibility of realizing the purpose of the invention can be confirmed by the description of embodiments of the design of the device made in accordance with the present invention, which is illustrated in graphic materials, which depict the following:

Figure 1 shows a panel with two layers of foamglass blocks, where 1 and 2 are the outer metal layers with a standard Z-LOCK lock, between which two layers 3 and 4 of foamglass blocks are laid, with ligation of the joints and the displacement of one layer 3 relative to the other 4 so that the end surfaces 5 and 6 of the panel form a L-shaped broken line in section along the horizontal arrangement of the panel. In this case, the ends 5 and 6 of the panel are mirrored relative to each other. Blocks of foam glass have the same dimensions. The protrusion-spike of the thorn-groove lock of the lock corresponds to the dimensions of the lock 7 of the surface layer.

For the manufacture of a specific embodiment of the panel, industrial foamglass blocks of the same shape and size, for example, are used. 600 × 400 × 60 mm, 400 × 475 × 60 mm, etc. The most convenient displacement of blocks in layers, i.e. A seam dressing device is the displacement of blocks at a distance of not less than the thickness of the block, but not more than ^1/2 _of its size in width or length.

In order to simplify them, the following drawings do not show the castle structures of surface layers that can be made of various types, including the most common at present (INTALOCK, thermal, secret, etc.), but as stated in the proposed set of essential features of the panel device, the dimensions of these elements are located within the end surfaces of the panel.

Figure 2 shows a panel with three inner layers 8, 9 and 10 of foam glass blocks, where the middle layer 9 is offset from the layers 8 and 10 and forms a protrusion in the middle of the panel from its end surface 11, and forms a depression on the opposite end surface 12.

Figure 3 shows a panel with four inner layers of foam glass blocks, indicated by the numbers 13, 14, 15 and 16, which shows the alternate displacement of adjacent layers, which form two L-shaped broken lines on the end surfaces 17 and 18.

Figure 4 shows a panel with four layers of foam glass blocks, wherein two relatively outer layers 19 and 20 are two inner layers of foam glass blocks 21 and 22 are offset, between which seams dressings foamed glass blocks is less than _^half the size of one horizontal block, and on the end surfaces 23 and 24, the depression and protrusion have broken lines, respectively, mirror each other.

Figure 5 presents a panel having five inner layers of foam glass blocks, indicated by the numbers 25, 26, 27, 28 and 29. Here, alternating symmetrical mixing of the layers between each other is shown, which forms “comb” views on the end surfaces 30 and 31 of the panel, in which there are three “teeth” from side 30, and two “teeth” and three depressions from side 31.

All structural elements of the panel are fastened with an adhesive composition, which for the foam-glass-foam glass contact is an inorganic binder on a cement base (plastonite, etc.), and for the glass-metal contact - for example, in the form of polyurethane foam two-component systems such as isocyanate-polyol (leading Huntsmen firms , Bayer et al.). When the panels are connected to each other, respectively, of the same shape of the selected option according to the number of inner layers and their relative positioning, the assembly proceeds according to the “tongue-and-groove” principle, which forms a labyrinth seal in these places, eliminating the blowing of walls and the formation of cold bridges at joints. It does not require the use of additional fastening devices.

To arrange the locks 7 of the surface layers 1 and 2 made of metal sheets, it is necessary to carry out a small milling at the places of their placement on the ends of the extreme layers of the foam glass blocks, as a result of which the necessary depressions corresponding to the dimensions of these locks 7 will be formed, as shown in FIG. one.

The use of foam glass blocks provides good thermal insulation, fire resistance, and the proposed options for laying the inner layers of panels eliminate the need for additional mechanical processing for the formation of docking forms.

The proposed options for laying the inner layers contribute to the possibility of choosing various structures in shape and size, depending on the tasks of use in a particular building structure. Typically, the dimensions of such building panels are in mm 1200 × (3000-12000) × (125-315).

The service life of these wall panels and installation structures of them is practically unlimited, which significantly distinguishes them from other known structures (for sandwich panels made of mineral fiber, the service life in practice is 10-15 years).

Claims (3)

1. Wall multilayer heat-insulating panel, including two surface layers, between which are heat-insulating layers, assembled from foam glass blocks, laid in layers in rows with ligation of joints, preferably in adjacent layers, while all the constituent elements of the panel structure are bonded to each other by means of an adhesive composition, characterized in that the surface layers are made of metal sheets, and the middle heat-insulating layers, the number of which is at least two, are located relative to each other so that at least one heat-insulating layer is offset relative to another, preferably adjacent to it, by a distance of not less than the thickness of the block, but not more than 1/2 of the horizontal size of one foam glass assembly block, while the resulting displacements of the end surfaces of the boundary blocks of the panel are mirrored in relation to each other, they form a spike-groove type of castle, which facilitates the connection of the same type of panels to each other. 2. Wall multilayer heat-insulating panel according to claim 1, characterized in that the number of heat-insulating layers is determined by calculation, based on the technical requirements for the wall panel, and is preferably from two to five layers. 3. Wall multilayer heat-insulating panel according to claim 1 or 2, characterized in that when the number of heat-insulating layers increases, they can be displaced relative to each other in different ways of alternating mixing through a row or in each row, while the ends of the panel will look like a broken line various shapes, and the depth of the groove and the protrusion of the spike-lock connection "spike-groove" correspond to the dimensions of the locks of the surface layers.

Images