RU171923U1 - Thermopanel front high-strength - Google Patents

Abstract

The utility model relates to the field of construction, namely to a high-strength facade thermal panel, which can be used for cladding with insulation of wall structures of newly constructed buildings, as well as reconstruction of dilapidated buildings and structures in housing, civil, industrial, agricultural, transport and other types of construction . The technical result of the utility model is to increase its strength for reliable docking of thermal panels during their installation, reducing scrap during manufacture and transportation. The high-strength facade thermopanel contains a heat-insulating plate 2 connected to a decorative protective layer 1 made of fiber-reinforced concrete and equipped with mounting holes 8 for mounting on a wall structure. Elements for connection at the joint type stud 3 and groove 4 are made to the entire thickness of the thermal panel. The thermopanel is reinforced with fiberglass reinforcement, prefabricated in the form of a lattice, consisting of 5 rods 6 connected by transverse connections, arranged parallel to the entire width of the thermopanel with the ends of the rods in each spike 3 and groove 4. The front side of the decorative protective layer 1 is made with imitating seams of brick masonry with grooves 4 up to 1/3 of the thickness of the decorative protective layer 1, mounting holes 8 for fastening are located in the grooves 4 and are made in two stages, repeating the diameters of Knitted fasteners. Grooves are made on two adjacent sides of the outer contour of the thermal panel. 1 s.p. f-ly, 4 ill.

Description

The proposed utility model relates to the field of construction, namely to a high-strength facade thermal panel, which can be used for cladding with insulation of wall structures of newly constructed buildings, as well as reconstruction of dilapidated buildings and structures in housing, civil, industrial, agricultural, transport and other types construction.

All well-known wall cladding panels have a number of common disadvantages, these are:

- docking of the panels is carried out on the front surface, as a result of which the joints of the panels are noticeable, which significantly degrades the decorative qualities of the facing panels;

- a visible way of fixing, the result of which is either a deep gap between the tiles due to the presence of fasteners, or the presence on the surface of the facade material of screws, or decorative elements masking them;

- the installation of such panels requires long lead times and professional skills;

- Countless component parts complicate the configuration.

When tightening the screws, during the installation of the panels, you must be careful with the application of the tightening torque, or use a torque tool so that the decorative-protective layer does not chip, which later, acting as a stress concentrator, will certainly lead to cracking of the material.

A known decorative facing insulation plate containing a heat-insulating base connected to a decorative protective layer, and holes for fastening (see the description of the patent for a utility model of the Russian Federation No. 109771, IPC Е04С 2/288, published on October 27, 2011).

Known plate facing decorative insulation made in the form of a square with holes on the plate for the installation of fasteners. Ready-made plates are installed on the outer surfaces of the wall structure (facade) of buildings and structures end-to-end, in rows and fastened to the facade with fasteners using facade dowels or other fasteners. Docking seams and heads of fasteners are sealed, the surface of the plates is painted with facade paints, which leads to complication, an increase in the time and cost of installation work, and also requires favorable weather conditions. This method of installation work with sealing the joints and fastening places on the front surface and painting the facade requires periodic cosmetic repairs during operation, namely, sealing the joints, painting, which requires significant financial costs, both for carrying out these works with the installation of scaffolding, and on materials.

Joints and places of fastening of slabs located on the front surface of the decorative-facing layer are sealed with special sealants, the structure of which is different from the concrete surface of the slabs, as a result of which, over time, colored places will be highlighted on the facade surface with a different color shade, which is a drawback .

A known decorative facing insulation plate, adopted as a prototype, comprising a heat-insulating plate connected to a decorative protective layer provided with mounting holes for fastening, and elements for connecting the plates when joined on opposite walls of the plates (see the description of the patent for the invention of the Russian Federation No. 2117742, IPC E04F 13/00, published on 08.20.1998).

The decorative protective layer (reinforced polymer) is made with holes in which the fixing elements are monolithic. Sealing plugs are installed in the fixing elements. The bottoms of the fixing elements are made with a hole for installing a screw or screw when fixing the plate to the wall. Sealing plugs are made with a head filled with the material of the decorative protective layer, and are installed in the holes after fixing the plate to the wall.

The spike-groove elements for connecting the plates during docking are made in the middle part of the end surface and are located over the entire length of the end walls, which makes it difficult to join the plates. If the walls do not have an ideal plane, then it will not be possible to get a spike into the groove or a break in the elements is possible for connection when they are joined. The disadvantages include the complexity and complexity of manufacturing products with such a configuration of the connecting elements in the middle part of the end surface, since special expensive molds are needed to enable the extraction of the finished product from the mold. In addition, when removed from the mold, during transportation, during installation, chips may occur, which leads to a violation of the sealing during installation.

When using these panels, the disadvantage is also the insufficient sealing of the fastening points with the stopper, since there must be a technological gap between the monolithic fixing element and the stopper for its installation. With this method of sealing the mounting holes on the surface of the decorative plate there are gaps through which moisture can enter, which can lead to corrosion of the fasteners and their further failure. The multicomponent elements of the connection of plates to the wall complicates their manufacture and use, which leads to a rise in the cost of panel installation work.

The technical task of the proposed utility model is to increase its strength for reliable docking of thermal panels during their installation, reducing scrap during manufacture and transportation.

The technical problem is solved in that a high-strength facade thermal panel containing a heat-insulating plate connected to a decorative protective layer equipped with mounting holes for mounting on a wall structure and elements for connecting thermal panels at the spike-groove joint located on opposite ends of the thermal panel , there are differences, namely decorative and protective layer is made of fibropeskobetona and further reinforced with fiberglass reinforcement in the form of a lattice with a prefabricated from rods parallel to the entire width of the thermal panel with the ends of the rods in each spike and groove and connected by transverse connections, elements for connecting thermal panels are made to the entire thickness of the thermal panel, while the front side of the decorative protective layer is made with grooves that simulate brick masonry seams up to 1/3 of the thickness of the decorative protective layer, mounting holes for fastening are located in the grooves and are made in two stages, with diameters corresponding to the diameters of the core and poles used when mounting the thermal panel of fasteners. Grooves are made on two adjacent sides of the outer contour of the thermal panel.

The implementation of the decorative protective layer of the thermopanel made of fiber-reinforced concrete and its reinforcement with fiberglass reinforcement increases the strength of the decorative protective layer of the thermopanel, especially at the joints of the mating panels corresponding to the elements of the “tongue-groove” type, preventing the formation of chips on them, which contributes to reliable joining. The implementation of the thermal panel with elements for the connection of the "thorn-groove" type over the entire thickness of the thermal panel also works for this result.

In addition, increasing the strength reduces the percentage of rejected products in the manufacture of the panel during its unforming, transportation and loading and unloading, simplifies the docking of thermal panels, which reduces the cost of manufacture and installation cost.

The proposed thermal panel facade high strength is illustrated by drawings, where: in FIG. 1 - thermopanel facade high strength in cross section; in FIG. 2 - thermopanel front high-strength, general view; in FIG. 3 - docking of two thermal panels on the wall structure; in FIG. 4 - the location of the fiberglass rods in the form of a lattice in the thermal panels of the facade high strength.

The proposed thermal panel contains a decorative protective layer 1 made of fiber-reinforced concrete, while pigments introduced into the initial mixture and heat-insulating layer 2 in the form of a rigid sheet of heat-insulating material, for example, polystyrene foam or in the form of a mineral wool plate, etc., can be used to stain fiber-reinforced concrete, 1. different thicknesses depending on climatic conditions of operation of the facade of wall structures.

Elements for connecting thermal panels such as spike 3 and groove 4 are made to the entire thickness "s" of the thermal panel. The thermopanel is reinforced with fiberglass reinforcement prefabricated in the form of a lattice consisting of 5 rods 6 interconnected by transverse ties, arranged parallel to the entire width of the thermopanel along the entire length of the thermopanel with tabs of the ends of the rods 6 in each spike 3 and groove 4. Fiberglass reinforcement (diameter may be used 4 mm) gives the thermopanel additional bending strength and minimizes the possibility of damage to the thermopanel during early unforming, subsequent transportation and installation work.

The front side of the decorative protective layer 1 is made with grooves 7 that simulate the seams of the brickwork of the front brick. To hide the joints when they are mounted on the wall structure, grooves 7, imitating the seams of the masonry brick, are located on two adjacent sides of the outer contour of the thermal panel. The depth of the groove is up to 1/3 of the thickness of the decorative protective layer.

To prevent chips when mounting thermal panels on the wall structure, mounting holes 8 are located in the grooves 7 in the middle part of the thermal panel and are made in two stages, with diameters corresponding to the diameters of the fasteners used in the installation of the thermal panel, for example, a rod and a dowel cap for the facade.

The proposed thermal panel is made by vibrocasting in a mold with elements for making mounting holes 8 in the decorative protective layer 1. First, mix the mixture to form a decorative protective layer 1, then during the vibration process a fiberglass reinforcement grid is placed along the length of the thermal panel with the ends of the rods being laid 6, in each spike 3 and groove 4 and from above, a heat-insulating layer 2 is laid, with pre-cut spikes and grooves similar to the decorative protective layer 1. Then the vibration is turned off, and the heat lation layer 2 is pressed into the decorative and protective layer 1 using the fading vibration energy while prigruzami above.

Installation of the proposed thermal panels during the work on the insulation of facades is as follows.

Ready-made thermal panels are installed on the outer surfaces of the wall structure of buildings and structures end-to-end in rows, combining the spikes 3 with the grooves 4 of the joined thermal panels, and through mounting holes 8 they are mounted on the wall structure using facade dowels. The abutting end surfaces of the heat-insulating layer 2 are pre-treated with mounting foam or special adhesive mass for thermal insulation, the abutting end surfaces of the decorative protective layer 1 are treated with sealant or a composition similar to the composition of the decorative protective layer and the color of the thermal panel 1, and the metal heads of the wall dowels are coated with heat-insulating paint for exclusion of cold bridges.

Claims (2)

1. The thermal panel is high-strength facade, containing a heat-insulating plate connected to a decorative protective layer provided with mounting holes for mounting on a wall structure, and elements for connecting thermal panels at the spike-groove joint located on opposite ends of the thermal panel, characterized in that it is decorative the protective layer is made of fiber-reinforced concrete and additionally reinforced with fiberglass reinforcement in the form of a lattice pre-made of rods arranged parallel to the width not thermal panels for its entire length with the tabs of the ends of the rods in each spike and groove and interconnected by transverse connections, the elements for connecting the thermal panels are made to the entire thickness of the thermal panel, while the front side of the decorative protective layer is made with grooves that simulate brick masonry seams, depth up to 1/3 of the thickness of the decorative protective layer, mounting holes for mounting are located in the grooves and are made in two stages, with diameters corresponding to the diameters of the core and the cap used in the installation of thermal panels and fasteners. 2. Thermopanel facade high-strength according to claim 1, characterized in that the grooves are made on two adjacent sides of the outer contour of the thermopanel.

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