RU76042U1 - FRONT BLOCK - Google Patents

Abstract

The utility model relates to the field of construction and can be used for external decoration of walls of buildings.

The technical result from the use of the utility model is that the developed facade block provides high load-bearing capacity for wind load, effective thermal resistance, high structural rigidity, accuracy of geometric parameters, providing simplicity and cost-effectiveness of installing the facade block on load-bearing wall structures, as well as when connecting such blocks among themselves.

The facade block 1 is a self-supporting enclosing structure protecting the structure from wind and precipitation.

The facade block 1 contains the base layer 2 and the insulation layer 3. The insulation layer 3 is located at a distance from the base layer 2 with the formation of an air gap 4. The facade block 1 is provided with a decorative coating 5, which can be applied directly to the insulation layer 3. Decorative coating 5 can be installed at a distance from the insulation layer 3 with the formation of an additional air gap 4-1. The air gap 4, together with the air gap 4-1, if it is formed, increases the thermal resistance and provides ventilation of the insulation.

Rigid vertical elements 6 are located in the base layer 2. Rigid vertical elements 6 are made in the form of load-bearing frames installed in the base layer 2 of the block as embedded reinforcement. Rigid vertical elements 6 are provided with upper 7 and lower 8 landing sites. Each landing site 7, 8 is made with a mating surface 7-1 and 8-1.

Description

The utility model relates to the field of construction and can be used for external decoration of walls of buildings.

Known panel for decorative interior decoration, made of rectangular shape, on the opposite ends of which there are pairwise mating connections (RF patent No. 45150 IPC 7 E04F 13/08, 2005)

The disadvantage of this design is poor performance.

Sandwich type building panels are known, consisting of several layers. For example, a building panel configured to be attached to building structures or a similar panel by means of fixing elements and fasteners, or by means for connecting said panel to a similar one. The construction panel includes the outer and / or inner sheathing of the polystyrene-based foam insulation layer, the density of which is in the range of 10-50 kg / m ³ , elastic closed cell foam material is used as the sheathing - polyethylene-based isolon, the density of which is within 20 -70 kg / m ³ . The insulation layer is connected to the casing using phenol-containing glue. The end walls of the insulation layer are enclosed in a fringing profile of aluminum or steel sheets, and the isolon layer at the edges is glued over the sides of the fringing profile, (see RF patent No. 2258118, IPC 7 Е04С 2/292, 2005)

The disadvantage of this solution is the low strength of the panel, the increased complexity of installing the panel on the facade, which requires the preliminary installation of many hinged elements for attaching the panel.

Known building panel designed for the construction of the roof or walls of the structure. The panel includes external and internal cladding made of aluminum or steel profiled sheets, and a layer of insulation made of polystyrene foam or mineral wool placed between them. The panel may be adapted to be attached to building structures such as it, floor or foundation

structures, roof eaves with a gutter or similar panel, by means of fixing elements and fasteners or means for connecting said panel to a similar panel located at its ends (see RF patent No. 2156340, IPC 7 Е04С 2/292, 2000)

These multilayer panels are designed for the construction of panel and frame buildings of low floors, because with their dimensions, they can not withstand large vertical loads, since all the loads are perceived by the panel as a whole and each of its layers.

Known decorative panel, facing, made of plastic opaque sheet material in the form of a quadrangle with walls around the perimeter, on the back surface of which is located and rigidly fixed in the middle of the rack in the form of a L-shaped profile. One pair of opposite walls is made with shelves that are parallel to the plane of the quadrangle and directed upward, and one of the shelves has a wave-like protrusion that is bent down to the front surface of the shelf. The rack is oriented parallel to the walls with shelves, mounted on the rear surface of the quadrangle with a wide side and is made with a height not exceeding the width of the walls. The walls are one size in width. Holes are made on a shelf with a wavy protrusion. The panel can be made with one or more racks (see RF patent No. 55818, IPC 2006.01 Е04С 2/26, 2006).

A disadvantage of the solution of the known decorative panel is the low heat-insulating properties of the panel, the high complexity of panel installation, which requires the preliminary installation of a plurality of hinged panel mounting elements.

A patent search showed that none of the known cladding panels can be selected as a prototype. Moreover, well-known panel solutions either cannot be used for decorative decoration of constructed buildings, or when using them, it is necessary to install vertical and horizontal rails on the walls of the buildings, fixed to the wall brackets, followed by hanging the panels on these rails. This technology is associated with high complexity, and increased danger when working on the upper floors of high-rise buildings.

The problem solved by the utility model is the creation of a structure with a high bearing capacity for wind load, effective thermal resistance, and high structural rigidity. The problem solved by the utility model is also the creation of a structure with precise geometric parameters, which ensures low installation complexity, simplicity and cost-effectiveness of installing the facade block on the supporting brackets installed on or in the walls, as well as when connecting such blocks to each other.

The problem is solved due to the fact that a facade block has been developed that contains the base and insulation layers, located at a distance from each other with the formation of an air gap inside the block, a decorative fence, and rigid vertical elements located in the base layer, equipped with upper and lower landing sites, made with mating surfaces and fixing elements.

The base layer and rigid vertical elements form a monolithic block.

Rigid vertical elements are made in the form of supporting frames.

The counter surfaces of the landing pads of the vertical elements form during assembly of the connection type "mom-dad."

A through slot is made in the upper landing pad for accepting the mounting bracket.

A slot may be made in the lower landing pad to receive the mounting bracket.

The facade block contains at least two rigid vertical elements.

The facade block additionally contains at least two rigid transverse elements connected to rigid vertical elements.

The technical result from the use of the utility model is that the creation of the facade block containing the base and insulation layers located at a distance from each other with the formation of an air gap inside the block, a decorative fence, and rigid vertical elements located in the base layer, equipped with upper and lower landing platforms made with mating surfaces and fixing elements, provides high load-bearing ability to wind load, effective thermal resistance, high rigidity, accuracy of geometric parameters, providing simplicity and

the cost-effectiveness of installing the facade block on the supporting wall brackets, as well as when connecting such blocks to each other.

The technical result also consists in the fact that the presence of rigid vertical elements serving as block frames allows to unload the facade block from vertical loads arising directly from the weight of the block and subsequent rows of blocks located above. This is achieved due to the fact that the vertical load through rigid vertical elements - frames and landing sites of these elements perceive brackets located on or in the wall of the structure. Thus, the vertical elements - the frame of the block together with the base layer perceive mainly only frontal wind loads.

The presence on the rigid vertical elements of the panel of the upper and lower landing pads provides the convenience and ease of mounting the panels on brackets mounted on or in the wall, as well as the ease of connecting the panels to each other during installation and their fixation on brackets mounted on or in the wall.

In addition, the presence of rigid vertical frame elements ensures the exact geometry of the block, a high degree of automation of production, simplifies both the manufacturing technology of the block and the technology of mounting the block when it is used during the facing of building facades.

Fig 1 is a facade block, a General view of the installation of blocks on the wall;

Figure 2 - frame facade block with additional transverse elements;

Figure 3 is a view A of figure 1;

Figure 4 is a view B of figure 3 with an attachment element;

5 is an installation option of a decorative fence by means of a dovetail type connection;

6 is a variant of the installation of a decorative fence by means of a landing washer.

The facade block 1 is a self-supporting enclosing structure protecting the structure from wind and precipitation. In addition, the facade unit 1 also performs the function of decorating buildings and structures.

The facade block 1 contains the base layer 2 and the insulation layer 3. The insulation layer 3 is located at a distance from the base layer 2 with the formation of an air gap 4. The facade block 1 is equipped with a decorative fence 5, which can be applied directly to the insulation layer 3. Decorative fence 5 can be installed at a distance from the insulation layer 3 with the formation of an additional air gap 4-1. The air gap 4, together with the air gap 4-1, if it is formed, increases the thermal resistance and provides ventilation of the insulation layer 3.

Rigid vertical elements 6 are located in the base layer 2. Rigid vertical elements 6 are made in the form of load-bearing frames installed in the base layer 2 of the block as embedded reinforcement. The facade block contains at least two rigid vertical elements 6. Provided that a sufficiently wide facade block 1 is implemented, and if it is necessary to strengthen the wind resistance of block 1, the number of vertical elements 6 is selected from the conditions for creating a rigid structure.

Rigid vertical elements 6 are provided with upper 7 and lower 8 landing sites. Each landing site 7, 8 is made with a mating surface 7-1 and 8-1.

The facade unit 1 is provided with fixing elements 9 made on rigid vertical elements 6 and intended in particular to reinforce the vertical elements and the unit as a whole. In the landing sites 7, 8 of the rigid vertical elements 6, there are places for receiving the fastening means 10. Using the fastening means 10, the facade blocks are fixed relative to each other during installation.

The insulation layer 3 is installed and fixed on the fixing elements 9, which allows not only to increase the insulating properties, but also to increase the rigidity of the block as a whole.

The base layer 2 and rigid vertical elements 6 in the manufacture of form a monolithic block due to the fact that the vertical elements 6 are filled with a base layer 2. When using the material of the base layer 2, which has the necessary rigidity, it is possible to perform a monolithic block by landing the finished base layer 2 on the fixing elements 9 rigid vertical elements 6 followed by rigid fastening by means of rivets and adhesive (or other rigid one-piece) joints.

The counter surfaces 7-1 and 8-1 of the landing pads 7, 8 of the vertical elements 6 are formed during assembly of the “mom-dad” connection. To fix the facade blocks 1 relative to each other during assembly, the landing pads 7, 8 of the rigid vertical elements 6 of the corresponding block are fixed relative to each other using fastening means 10 (see Fig. 4). Landing sites 7, 8 by connecting mating surfaces 7-1 and 8-1 provide reliable fixation of the facade blocks 1 with each other during their installation, as well as the perception of the frontal wind load panels.

In the upper landing area 7, a through slot 11 is made (see Fig. 4). The slot 11 may have a slotted, L-shaped or T-shaped profile. The slot 11 is designed to accept the bracket 12 and adjust the position of the block relative to the wall when installing the panel on the wall.

In the manufacture of facade blocks located during installation in the lower row, a similar slot 11 can be made in the lower landing area 8 (not shown conditionally).

In the landing pads 7, holes 13 are provided for receiving fasteners fixing the position of the facade block 1 on the bracket 12.

The facade block can be equipped with transverse elements 14 located in the upper and lower parts of the facade block and connecting the rigid vertical elements 6 to each other. In this case, the transverse elements 14 will provide additional rigidity to the facade block

The facade block can be made in two ways:

1. Pre-manufactured by molding or stamping, rigid vertical elements 3 are laid in a mold. Then the mold is poured with a base layer 2 with the formation of a monolithic block. The base layer is covered with a decorative fence 11, for example, plaster. If necessary, an insulation layer 12 can be attached to the base layer 2. In this case, a decorative fence 11 is installed on the insulation layer.

2. Hard vertical elements are preliminarily made by injection or stamping. 3. A base layer 2 is made of high strength material according to the template. Set the vertical elements 3 into the mold and then lay the base layer 2 on the fixing elements 6, rigidly

integrally connecting them together. Due to this, a monolithic block is also formed. Further operations repeat step 1.

The manufacturing technique of the facade block provides a clear geometry and high strength of the block. Due to the presence of rigid vertical elements 3, it is possible to install the unit directly on the wall brackets, excluding the use of additional guides.

The facade block is used as follows:

The manufactured facade block is installed on the brackets 3, freely moving in the horizontal direction and providing adjustment of the position of the block relative to the wall to level the surface of the wall. Since the dimensions of the block are strictly observed during its manufacture, the marking brackets are installed on the walls and the blocks are fixed on the brackets row by row.

When installing the facade block on the walls of the structure, the connection above the located block with the lower block is ensured by joining the upper 7 and lower 8 landing sites on the return surfaces 7-1 and 8-1 and fixing them together using fastening means 10. Thus, they provide reliable fixation of facade blocks 1 to each other during their installation, as well as the perception of frontal wind load by panels.

The frontal wind load is perceived by rigid vertical elements 6. The horizontal lateral load is carried by the base layer 2 together with the vertical elements 6 (monolithic block) embedded in it.

The base layer 2 can be made of heat-insulating material (to impart thermal insulation properties to a facade block made of one layer). The base layer 2 can be made of any other material with sufficient strength and thermal insulation properties. For example, it can be made of molding materials based on foamed polystyrene, foam, as well as lightweight concrete (expanded clay concrete, chip concrete, foam concrete, aerated concrete, etc.). Other composite materials based on cement, wood, mineral wool such as ROKVEL, URSA can be used as the base layer material. These materials also have sufficient thermal insulation properties.

In the manufacture of the remaining elements of the facade block, the following materials can be used:

- rigid vertical elements 6 can be made of plastics, composite plastics, steel or aluminum, as well as cement fiber

particle-fibrous materials, plywood, wood or can be made in the form of a wire frame or any material with the necessary rigidity;

- the insulation layer 3 can be made of the same foamed polyurethane foam or of a non-combustible fireproof material, like the first base layer 2 (for example, mineral wool, Rockwool thermal insulation or the like materials);

- decorative fence 5 can be made using decorative facade plaster, or from a sheet of plastic, or in the form of a decorative sheet from sheet steel, or from aluminum, or from metal plastic.

The design of the facade block 1 provides a variety of ways to arrange decorative fencing 5:

- insulation layer 3 before or after installation is covered with reinforced plaster, and painted.

- the decorative fence is glued to the insulation layer 3.

- a decorative fence 5 (see figure 2.) is installed directly on the fixing elements 9 of the frame by means of a screw or riveted connection 15. The installation of a decorative fence can be made either directly at the manufacturer or at the construction site. The material of the decorative fence is selected based on operating conditions, or is regulated by the customer.

- a decorative fence 5 (see figure 3) is mounted on rigid vertical elements - frame 6 by means of a dovetail type connection. In this case, the frame 6 is equipped with one of the parts of the connection — a vertical bar 16 with holes made on it, and a decorative fence with a mating part 17 with hooks. This method allows you to hang a decorative fence on a mounted facade unit without additional fastening.

- a decorative fence 5 (see figure 4) is installed on the elements of the frame 6 by means of a landing washer 18. This method allows you to hang a decorative fence on a mounted facade unit without additional fastening.

The facade block can be manufactured using known technological equipment from these materials.

The facade block can be used for decorative and heat-insulating decoration of the walls of finished buildings and structures when it is hung on brackets fixed on a wall row by row. The facade block can also be used as the outer part of the formwork in the construction of monolithic structures. Or the facade block can be used as a finish in the process of building brick buildings and structures.

The inventive utility model provides:

- reducing the number of articulated joints, reducing the number of additional intermediate parts, which increases the reliability of the structure while reducing its weight.

- manufacture of the facade block of any size and shape.

- conducting installation of facade blocks simultaneously with the installation of walls.

- reduction in the use of heaters through the use of the effect of thermal resistance of the air gap between the building base and the facade block, which allows to increase thermal resistance by 10-15%.

- reduction of heat loss from the formation of cold bridges, due to the constructive possibility of using parts with low thermal conductivity in bulkheads.

- a multiple reduction in the complexity of mounting the structure.

- reduction of the risks of accidents, due to the reduction of the complexity of high-altitude work.

Claims (8)

1. A facade block containing a base layer and a warming layer located at a distance from the base layer with the formation of an air gap inside the block and provided with a decorative coating, with rigid vertical elements located in the base layer, provided with fixing elements and upper and lower landing pads made with mating surfaces. 2. The facade block according to claim 1, characterized in that the base layer and rigid vertical elements form a monolithic block. 3. The facade block according to claim 1, characterized in that the rigid vertical elements are made in the form of supporting frames 4. The facade block according to claim 1, characterized in that the mating surfaces of the landing sites of the vertical elements form a mum-dad connection during assembly. 5. The facade block according to claim 1, characterized in that in the upper landing area there is a through slot for accepting the mounting bracket. 6. The facade block according to claim 1, characterized in that a slot can be made in the lower landing for accepting the mounting bracket. 7. The facade block according to claim 1, characterized in that it contains at least two rigid vertical elements. 8. The facade block according to claim 1, characterized in that it further comprises at least two rigid transverse elements connected to rigid vertical elements.