RU2797483C2 - Construction wall panel (variants) - Google Patents

Abstract

FIELD: construction industry.

SUBSTANCE: invention relates to the field of construction, in particular to the construction of single-storey and multi-storey bearing-wall buildings. The construction wall panel is used in the field of bearing-wall housing construction. The construction wall panel contains the first and second concrete-containing layers, a thermal insulation element and connecting elements. The thermal insulation element is limited to two side surfaces, the upper surface and the lower surface. The side surfaces are located on opposite sides of the thermal insulation element, the upper surface and the lower surface are located on opposite sides of the thermal insulation element. The thermal insulation element is located between the first concrete-containing layer and the second concrete-containing layer and is connected to them, while the first and second outer surfaces are facing in opposite directions from the thermal insulation element, and the second concrete-containing layer on the side of one second side surface forms one side protrusion with respect to the thermal insulation element and the first concrete-containing layer, and on the side of the other second lateral surface forms another lateral projection in relation to the thermal insulation element and the first concrete-containing layer, with the formation of one first side surface, one third side surface and the adjacent surface of the side projection of one side docking surface, and with the formation of another first mating face, another third side surface and the adjacent surface of the side projection of the other side mating face. Both side mating faces are L-shaped in cross-section, the second concrete-containing layer on the side of the second upper surface forms an upper protrusion with respect to the thermal insulation element and the first concrete-containing layer, with the first upper surface, the third upper surface and the adjacent surface of the upper protrusion forming an upper mating face, made L-shaped in cross-section, each connecting element is located with one end in the first concrete-containing layer, and with the other end in the second concrete-containing layer. The variants of the wall panel are also described.

EFFECT: reducing the heat losses of the finished building structure as a whole.

5 cl, 8 dwg

Description

Technical field

The invention relates to the field of construction, in particular to the construction of single-storey and multi-storey panel buildings. The building wall panel is used in the field of panel housing construction.

State of the art

A device is known - wall (RF patent No. 2616311, publication date 04/14/2017). The wall panel contains a concrete slab, an upper crossbar, a lower crossbar, large ribs, first heat-insulating plates, second heat-insulating plates, two third heat-insulating plates, U-shaped elements. The concrete slab is provided with an outer surface, an inner surface, two side surfaces, an upper surface and a lower surface. The outer surface and the inner surface are made in the form of rectangles and have a large area compared to other surfaces of the concrete slab. The side surfaces are located opposite each other. The top surface is opposite the bottom surface. The upper cross member is located on the outer surface along its upper edge. The lower cross member is located on the outer surface along its lower edge. Large ribs are placed on the outer surface parallel to the side surfaces from the top crossbar to the bottom crossbar. In this case, the extreme large ribs are located indented from the side surface corresponding to each of them. The surfaces of the large ribs, opposite the outer surface, are indented from the surface of the upper crossbar and the lower crossbar, opposite the outer surface. The first thermal insulation boards are located between the large ribs flush with the surfaces of the large ribs opposite the outer surface. The second heat-insulating plates are located along the large rib corresponding to each of them and with an overlap on the first heat-insulating boards located on opposite sides of this large rib. Each U-shaped element is placed vertically in such a way that it covers the second heat-insulating plate corresponding to it from the side opposite to the outer surface. The third insulating boards are located on the sides of the extreme large ribs facing the corresponding side surface, between the upper and lower crossbars, from the outer surface to the surface of the large rib.

The disadvantage of the known technical solution is the high heat loss of the finished structure, due to the gradual destruction of the connecting seams under the influence of environmental factors.

The closest technical solution (prototype) is a wall panel (RF patent No. 186417, publication date 01/21/2019). The wall panel contains a slab, ribs, two crossbars, a filler. Crossbars are located on opposite edges of the plate parallel to each other. One cross member is provided with a first surface, and the other cross member is provided with a second surface. In this case, the first surface and the second surface are located on opposite sides of the crossbars. The ribs are located from one crossbar to the other crossbar, perpendicular to them with the formation of an intercostal space between them, filled with filler. The slab, cross-beams and ribs are made of material containing concrete and are integral with each other. When wall panels are installed in a single structure, connecting seams are formed between said wall panels, which are filled with appropriate building materials. These seams have a negative impact on the aesthetic appearance of the object as a whole. At the same time, over time, due to temperature changes and other environmental factors, a violation of the tightness of the connection along the specified seams occurs, which negatively affects both the appearance of the structure and the preservation of the originally declared physical characteristics of the structure as a whole, for example, heat, moisture and breathability.

The disadvantage of the prototype is the high heat loss of the building structure.

The technical result of the invention is to reduce the heat loss of the finished building structure as a whole.

The set technical result is achieved due to the fact that in the building wall panel according to the first embodiment, containing the first concrete-containing layer and the second concrete-containing layer, the first concrete-containing layer is limited by the first outer surface, the first two side surfaces, the first upper surface and the first lower surface, the first side surfaces are located on opposite sides of the first concrete-containing layer, the first upper surface and the first lower surface are located on opposite sides of the first concrete-containing layer, the second concrete-containing layer is bounded by the second outer surface, two second side surfaces, the second upper surface and the second lower surface, the second side surfaces are located with opposite sides of the second concrete-containing layer, the second upper surface and the second lower surface are located on opposite sides of the second concrete-containing layer, the first outer surface and the second outer surface are made of a larger area than the other surfaces, while the first concrete-containing layer and the second concrete-containing layer are made integrally from the concrete-containing material, so that the first outer surface and the second outer surface are located on opposite sides, while the second concrete-containing layer on the side of one second side surface forms one lateral projection with respect to the first concrete-containing layer, and on the other second side surface forms another lateral projection with respect to to the first concrete-containing layer, with the formation of one first side surface and the side protrusion adjacent to it of one side docking surface, and with the formation of the other first side surface and the side protrusion adjacent to it of the other side docking surface, both side docking surfaces being L-shaped in cross section, the second concrete-containing layer from the side of the second upper surface forms an upper protrusion with respect to the first concrete-containing layer, and the first upper surface and the adjacent surface of the upper protrusion form an upper mating surface made L-shaped in cross section; according to the second embodiment, in a building wall panel containing a first concrete-containing layer, a second concrete-containing layer, a heat-insulating element and connecting elements, the first concrete-containing layer is limited by the first outer surface, the first two side surfaces, the first upper surface and the first lower surface, the first side surfaces are located with opposite sides of the first concrete-containing layer, the first upper surface and the first lower surface are located on opposite sides of the first concrete-containing layer, the second concrete-containing layer is bounded by the second outer surface, two second side surfaces, the second upper surface and the second lower surface, the second side surfaces are located on opposite sides of the second of the concrete-containing layer, the second upper surface and the second lower surface are located on opposite sides of the second concrete-containing layer, the first outer surface and the second outer surface are made larger than the other surfaces, the heat-insulating element is limited by two third side surfaces, the third upper surface and the third lower surface, the third side surfaces are located on opposite sides of the heat-insulating element, the third upper surface and the third lower surface are located on opposite sides of the heat-insulating element, the heat-insulating element is located between the first concrete-containing layer and the second concrete-containing layer and is connected to them, while the first outer surface and the second outer surface are turned into opposite side of the heat-insulating element, and the second concrete-containing layer on the side of one second side surface forms one lateral protrusion with respect to the heat-insulating element and the first concrete-containing layer, and on the side of the other second side surface forms another side protrusion with respect to the heat-insulating element and the first concrete-containing layer, with the formation of one first side surface, one third side surface and the surface of the side protrusion of one side docking surface adjacent to it, and with the formation of the other first side surface, the other third side surface and the surface of the side protrusion of the other side docking surface adjacent to it, and both side the mating surfaces are L-shaped in cross section, the second concrete-containing layer from the side of the second upper surface forms an upper protrusion with respect to the heat-insulating element and the first concrete-containing layer, and the upper mating surface is formed by the first upper surface, the third upper surface and the surface of the upper protrusion adjacent to it , made L-shaped in cross section, each connecting element is located with one of its ends in the first concrete-containing layer, and with its other end in the second concrete-containing layer; according to the third embodiment, in a building wall panel containing a first concrete-containing layer, a second concrete-containing layer, first heat-insulating plates, a second heat-insulating plate, ribs, an upper crossbar, a lower crossbar, and connecting elements, the first concrete-containing layer is limited by the first outer surface, the first inner surface, by two first side surfaces, the first upper surface and the first lower surface, the first outer surface and the first inner surface are made larger than the other surfaces of the first concrete-containing layer and are generally parallel to each other, the first side surfaces are located on opposite sides of the first concrete-containing layer, the first upper the surface and the first lower surface are located on opposite sides of the first concrete-containing layer, the upper crossbar is located on the first inner surface near the first upper surface, the lower crossbar is located on the first inner surface near the first lower surface, the ribs are located on the first inner surface generally parallel to each other and the first side surfaces from the upper crossbar to the lower crossbar, the first concrete-containing layer, the ribs and crossbars are made integrally from the concrete-containing material, the first heat-insulating plates are located between the ribs flush with the surfaces of the ribs opposite the first inner surface, the second heat-insulating plate adjoins one of its largest surfaces to the first heat-insulating slabs and ribs, the second concrete-containing layer is bounded by the second outer surface, the second inner surface, the two second side surfaces, the second upper surface and the second lower surface, the second outer surface and the second inner surface have larger areas than the other surfaces of the second concrete-containing layer, the second outer surface and the second inner surface are located generally parallel to each other, the second side surfaces are located on opposite sides of the second concrete-containing layer, the second upper surface and the second lower surface are located on opposite sides of the second concrete-containing layer, the second concrete-containing layer is adjacent by the second inner surface to the second heat-insulating slab, when in this case, the second concrete-containing layer on the side of the second side surfaces forms lateral protrusions with respect to the second heat-insulating plate, the second concrete-containing layer on the side of the second upper surface forms an upper ledge with respect to the second heat-insulating plate, the connecting elements are made in the form of rods with fasteners at the ends, each the connecting element is located with one of its ends in the first concrete-containing layer, and with its other end in the second concrete-containing layer, in a particular case, the fasteners are made in the form of thickenings, in another particular case, the fasteners are made in the form of protrusions.

Brief description of the drawings

The invention is illustrated by drawings (Fig. 1-8), where Fig.1 shows a building wall panel according to the third embodiment, connected to two adjacent panels in a section across the ribs, Fig.2 shows a section of a building wall panel according to the third embodiment along the ribs between them, figure 3 shows a section of the construction wall panel according to the third embodiment along the rib, figure 4 shows the corner connection of the construction wall panel according to the third embodiment with an adjacent panel, figure 5 shows the construction wall panel according to the first embodiment, connected on one side with an adjacent panel, in section, figure 6 shows a building wall panel according to the first embodiment, side view, figure 7 shows a top view of a building wall panel according to the second embodiment in section, figure 8 shows a side view construction wall panel according to the second embodiment in section.

Disclosure of invention

The figures indicate: the first concrete-containing layer 1, the first heat-insulating plate 2, the rib 3, the second heat-insulating plate 4, the second concrete-containing layer 5, the side protrusion 6, the first inner surface 7, the first outer surface 8, the second outer surface 9, the second inner surface 10 , first side surface 11, second side surface 12, second top surface 13, top ledge 14, top cross member 15, first top surface 16, second bottom surface 17, bottom cross member 18, first bottom surface 19, connector 20, fire seal 21 , mounting foam 22, adjacent panel 23, sealant 24, side joint surface 25, upper joint surface 26, heat-insulating element 27.

According to the first embodiment of the invention, the main elements of the building wall panel are the first concrete-containing layer 1 and the second concrete-containing layer 5.

Hereinafter, the words top, bottom, and the like are related taking into account the direction of the gravity vector at the usual location for this device during use. The terms horizontal and vertical and their derivatives are understood in the sense of being perpendicular to or parallel to the gravity vector, respectively.

The first concrete-containing layer 1 is made in the form of a rectangular parallelepiped and has two large surfaces - the first outer surface 8 and the first inner surface 7. The first outer surface 8 faces outside the building wall panel, the first inner surface 7 faces inside the building wall panel. The first side surfaces 11 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7. The first upper surface 16 and the first bottom surface 19 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7 .

The second concrete-containing layer 5 is made in the form of a rectangular parallelepiped and has two large surface areas - the second outer surface 9 and the second inner surface 10. The second outer surface 9 faces the outside of the building wall panel. The second inner surface 10 faces the interior of the building wall panel. The second side surfaces 12 are located opposite each other between the second outer surface 9 and the second inner surface 10. The second upper surface 13 and the second lower surface 17 are located opposite each other between the second outer surface 9 and the second inner surface 10.

The first outer surface and the second outer surface are larger than the other surfaces of the building wall panel according to the first embodiment. At that, the first concrete-containing layer and the second concrete-containing layer are made integrally from the concrete-containing material, so that the first outer surface and the second outer surface are located on opposite sides of the building wall panel. In this case, the second inner surface 10 partially adjoins the first inner surface 7. The second concrete-containing layer 5 near the second side surfaces 12 partially protrudes beyond the first side surfaces 11 with the formation of side protrusions 6. At the same time, a part of the second inner surface 12 near each second side surface 12, protruding beyond the first concrete-containing layer 1, and the first side surface 11 adjacent to it, a side docking surface 25 is formed. The configuration of the side docking surface 25 of the building wall panel in cross section is L-shaped. The second concrete-containing layer 5 near the second upper surface 13 partially protrudes beyond the first upper surface 16 with the formation of the upper protrusion 14. At the same time, part of the second inner surface 12 near the second upper surface 13, protruding beyond the first concrete-containing layer 1, and the first upper surface adjacent to it 16, an upper joint surface 26 is formed. At the same time, the configuration of the upper joint surface 26 of the building wall panel is L-shaped in cross section.

According to the second embodiment of the invention, the main elements of the building wall panel are the first concrete-containing layer 1, the second concrete-containing layer 5, the heat-insulating element 27 and the connecting elements 20.

The first concrete-containing layer 1 is made in the form of a rectangular parallelepiped and has two large surfaces - the first outer surface 8 and the first inner surface 7. The first outer surface 8 faces outside the building wall panel, the first inner surface 7 faces inside the building wall panel. The first side surfaces 11 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7. The first upper surface 16 and the first bottom surface 19 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7 .

The first concrete-containing layer 1 on the side of the first inner surface 7 can be made in relief, with the formation of various protrusions and depressions in the body of the first concrete-containing layer 1. In a particular case, the first concrete-containing layer 1 on the side of the first inner surface 7 is made with protrusions, which are elongated elements in the form of ribs 3 and crossbars.

The second concrete-containing layer 5 is made in the form of a rectangular parallelepiped and has two large surface areas - the second outer surface 9 and the second inner surface 10. The second outer surface 9 faces the outside of the building wall panel. The second inner surface 10 faces the interior of the building wall panel. The second side surfaces 12 are located opposite each other between the second outer surface 9 and the second inner surface 10. The second upper surface 13 and the second lower surface 17 are located opposite each other between the second outer surface 9 and the second inner surface 10.

Heat-insulating element 27 is made in the form of a rectangular parallelepiped. The heat-insulating element 27 is made of a material that reduces the heat transfer process and increases the thermal resistance of the building wall panel as a whole. In a particular case, expanded polystyrene with a density of at least 16 kg/m3 can be used as the material of the heat-insulating element 27. The heat-insulating element 27 can be made as a single piece or consisting of several separate elements. The heat insulating element 27 has two large surfaces located on opposite sides of the heat insulating element 27, and is also limited by two third side surfaces, a third top surface and a third bottom surface. The third side surfaces are located on opposite sides of the heat-insulating element 27. The third upper surface and the third lower surface are located on opposite sides of the heat-insulating element 27. The heat-insulating element 27 is located between the first concrete-containing layer 1 and the second concrete-containing layer 5 and is connected to them. In this case, the first outer surface 8 and the second outer surface 9 are facing in opposite directions from the heat-insulating element 27. Moreover, one of these large surfaces of the heat-insulating element 27 is adjacent to the first inner surface 7 of the first concrete-containing layer 1. In this case, in the case of the first inner surface 7 being embossed , the specified large surface of the heat-insulating element 27 is made responsive in shape to the shape of the first inner surface 7. Another large surface of the heat-insulating element is adjacent to the second inner surface 10 of the second concrete-containing layer 5. The corresponding edges of the heat-insulating element 27 are generally located in the same plane with the first side surfaces 11 , the first top surface 16 and the first bottom surface 19.

The second inner surface 10 partially adjoins the heat-insulating element 27. The second concrete-containing layer 5 near the second side surfaces 12 forms side protrusions 6 in relation to the heat-insulating element 27 and the first concrete-containing layer 1. At the same time, a part of the second inner surface 12 near each second side surface 12, protruding beyond the heat-insulating element 27 and the first concrete-containing layer 1, and the surface of the heat-insulating element 27 adjacent to it, as well as the corresponding first side surface 11, a side docking surface 25 is formed. The configuration of the side docking surface 25 of the building wall panel in cross section is L-shaped.

The second concrete-containing layer 5 near the second upper surface 13 partially protrudes beyond the heat-insulating element 27 and the first upper surface 16 with the formation of the upper protrusion 14. At the same time, part of the second inner surface 12 near the second upper surface 13 protruding beyond the heat-insulating element 27 and the first concrete-containing layer 1, and the surface of the heat-insulating element 27 adjacent to it, as well as the first upper surface 16, an upper joint surface 26 is formed. At the same time, the configuration of the upper joint surface 26 of the building wall panel in cross section is L-shaped.

The connecting elements 20 are made to fix the relative position of the first concrete-containing layer 1, the heat-insulating element 27 and the second concrete-containing layer 5. There are several connecting elements 20 in the building wall panel. Each connecting element 20 is located with its middle part in the heat-insulating element 27. At the same time, one end of each connecting element 20 is located in the first concrete-containing layer 1, and the opposite end of this connecting element 20 is located in the second concrete-containing layer 5. The connecting elements 20 are made of sufficient strength and wear resistance for the perception of operational loads (including bending). The connecting elements 20 can be provided with fasteners at the ends. Fasteners can be made in the form of attached parts, for example, by means of a welded joint or a threaded joint. In a particular case, fasteners can be made as thickenings, i.e. increase in cross-sectional dimensions near the ends of the connecting element 20. Steel reinforcement or fiberglass reinforcing rods can be used as a connecting element.

According to the third embodiment of the invention, the main elements of the building wall panel are the first concrete-containing layer 1, the second concrete-containing layer 5, the first heat-insulating plates 2, the second heat-insulating plate 4, the connecting elements 20, the ribs 3, the upper cross member 15 and the lower cross member 18 (hereinafter sometimes referred to collectively crossbars).

The first concrete-containing layer 1 is made in the form of a rectangular parallelepiped and has two large surfaces - the first outer surface 8 and the first inner surface 7. The first outer surface 8 faces outside the building wall panel, the first inner surface 7 faces inside the building wall panel. The first side surfaces 11 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7. The first upper surface 16 and the first bottom surface 19 are located on opposite sides of the building wall panel, each between the first outer surface 8 and the first inner surface 7 .

The first concrete-containing layer 1 is embossed on the side of the first inner surface 7, i. e. made integral with ribs 3 and crossbars.

The ribs 3 are made in the form of a bar with a rectangular cross section or a trapezoidal cross section. The dimensions of the rib 3 in cross section are smaller than the rest of its dimensions. The ribs 3 bear against the first inner surface 7 of the first concrete-containing layer 1. The ribs 3 are generally parallel to each other and perpendicular to the crossbars described later. In this case, two ribs 3 are located near the first two side surfaces 11. In this case, the ribs 3 are placed at a certain distance from each other, in particular, at the same distance.

The crossbars are made in the form of a bar with a rectangular cross section or a trapezoidal cross section. The dimensions of the cross-section in cross section are smaller than its length. The crossbars are adjacent to the first inner surface 7 of one of their sides. One cross member is located along the first upper surface 16 (upper bar 15), the other is located along the first lower surface 19 (lower bar 18). The size of the crossbars along the first top surface 16 and the first bottom surface 19 (in the horizontal direction) is usually the same as the corresponding size of the building wall panel (dimensions may also differ).

The heat-insulating element 27 is installed in the building wall panel between the first concrete-containing layer 1 and the second concrete-containing layer 5. The heat-insulating element 27 is made of a material that reduces the heat transfer process and increases the thermal resistance of the building wall panel as a whole. In a particular case, expanded polystyrene with a density of at least 16 kg/m ³ can be used as the material of the heat-insulating element 27. In a particular case, the heat-insulating element 27 is made up of the first heat-insulating boards 2 and the second heat-insulating boards 4.

The heat-insulating element 27 includes several first heat-insulating boards 2. Each first heat-insulating board 2 is shaped like an object, two sides of which have larger areas than the other sides, and these large sides are generally parallel to each other. Each first heat-insulating slab 2, on one of its large sides, is adjacent to a part of the first inner surface 7 of the first concrete-containing layer 1, limited by two adjacent ribs 3 and crossbars. The first heat-insulating plates 2 are flush with the surfaces of the ribs 3 opposite the first inner surface 7.

The second heat-insulating plate 4 corresponds in shape to a rectangular parallelepiped, one of the linear dimensions of which is much smaller than the other two. The second heat-insulating plate 4 adjoins with one of its large sides to the side of each rib 3, opposite to the first inner surface 7, and to the side of each first heat-insulating plate 2, opposite to the first inner surface 7. In this particular case, the corresponding edges of the second heat-insulating plate 4 are located generally in the same plane as the first side surfaces 11, the first top surface 16 and the first bottom surface 19.

The second concrete-containing layer 5 is made in the form of a rectangular parallelepiped and has two large surface areas - the second outer surface 9 and the second inner surface 10. The second outer surface 9 faces the outside of the building wall panel. The second inner surface 10 faces the interior of the building wall panel. The second side surfaces 12 are located opposite each other between the second outer surface 9 and the second inner surface 10. The second upper surface 13 and the second lower surface 17 are located opposite each other between the second outer surface 9 and the second inner surface 10.

The second inner surface 10 partially adjoins the surface of the second heat-insulating plate 4, opposite to the surface adjacent to the ribs 3 and the first heat-insulating plates 2. The second concrete-containing layer 5 from the side of the second side surfaces 12 forms side protrusions 6 in relation to the second heat-insulating plate 4 and the first side edges 11. At the same time, a part of the second inner surface 12 near each second side surface 12 protruding beyond the heat-insulating element 27 and the first concrete-containing layer 1, as well as the surface of the heat-insulating element 27 adjacent to it and the corresponding first side surface 11, form a side docking surface 25. The configuration of the side docking surface 25 of the building wall panel in cross section is L-shaped.

The second concrete-containing layer 5 from the side of the second upper surface 13 forms the upper protrusion 14 in relation to the second heat-insulating plate 4. At the same time, a part of the second inner surface 12 near the second upper surface 13, protruding beyond the heat-insulating element 27 and the first concrete-containing layer 1, and adjacent to its surface of the heat-insulating element 27, as well as the first upper surface 13 formed the upper docking surface 26. The configuration of the upper docking surface of the building wall panel in cross section is L-shaped.

The connecting elements 20 are made in the form of rods with fasteners at opposite ends. Fasteners can be made in the form of attached parts, for example, by means of a welded joint or a threaded joint. In a particular case, fasteners can be made as thickenings, i.e. increase in cross-sectional dimensions near the ends of the connecting element 20. The connecting elements 20 are made of sufficient strength and wear resistance to withstand operational loads (including bending). The connecting elements 20 are designed to maintain the relative position of the first concrete-containing layer 1 relative to the second concrete-containing layer 5. Each connecting element 20 is located with one of its fasteners in the first concrete-containing layer 1, and with its other fastener in the second concrete-containing layer 5. In this case, the middle part of the connecting element 20 is located inside the heat-insulating element 27 (inside the second heat-insulating plate 4 and ribs 3, or inside the first heat-insulating plate 2).

The construction wall panel according to the first version, according to the second version and according to the third version, in a particular case, can be equipped with lifting elements, and / or embedded parts for fastening, and / or adjusting elements, and / or embedded parts for panel screeding , and / or embedded parts for connection. The lifting elements are made with the possibility of capturing and transporting the building wall panel by means of a crane. Embedded parts for fastening are made for fastening the building wall panel to other elements of the building, in particular to building wall panels of the upper level or roof elements. The adjusting elements are made with the possibility of leveling the building wall panel with other elements of the building. Embedded parts for screeding of panels are made with the possibility of screeding adjacent panels at a minimum distance to each other. Embedded parts for connection are made with the possibility of connection of the building wall panel with other elements of the building, in particular with adjacent panels. The location of these elements is carried out taking into account the preservation of resistance to operational loads by the building wall panel.

Implementation of the utility model

In the case of using the above elements and means, the invention is implemented as follows (the presented description of the object illustrates a particular case of its execution, other implementations are possible using the features of this technical solution).

According to the first embodiment, the building wall panel is manufactured as follows. On the vibrating table, a side equipment is installed that corresponds to the configuration of the building wall panel according to the first embodiment as a whole. At the same time, the shape of the sides is made in accordance with the sequence of filling the layers. Let us describe an example with the beginning of pouring from the formation of the first concrete-containing layer 1. A concrete mixture is poured, for example, grade B25. If necessary, reinforcing elements, lifting elements, embedded parts for fastening, adjusting elements, embedded parts for panel screed, embedded parts for connection are placed inside the mold. After that, a concrete mortar is poured into the mold to form the second concrete-containing layer 5. The concrete mortar partially penetrates into the first concrete-containing layer 1, which has not yet hardened, and their mutual engagement with each other occurs. After the concrete mortar has hardened, the resulting building wall panel is removed from the mold.

According to the second embodiment, the invention is implemented as follows. On the vibrating table, a side equipment is installed that corresponds to the configuration of the building wall panel according to the second embodiment as a whole. At the same time, the shape of the sides is made in accordance with the sequence of filling the layers. Let us describe an example with the start of pouring from the formation of the second concrete-containing layer 5. A concrete mixture is poured, for example, grade B25. In the specified layer (which forms the second concrete-containing layer 5 after solidification), before solidification, connecting elements 20 are installed at one end. of the heat-insulating element 27 and the incompleteness of the drying process of the concrete mixture, the second concrete-containing layer 5 partially adheres to the second heat-insulating plate 4. If necessary, reinforcing elements, lifting elements, embedded parts for fastening, adjusting elements, embedded parts for panel screed, embedded parts are placed inside the mold for connection. After that, a concrete solution is poured into the mold to form the first concrete-containing layer 1. The concrete solution partially penetrates the porous structure of the heat-insulating element 27 and their mutual engagement with each other occurs. The ends of the connecting elements 20 opposite to those fixed in the second concrete-containing layer 5 are fixed in the first concrete-containing layer 1 after solidification. After the concrete mortar has solidified, the resulting building wall panel is removed from the mold.

According to the third embodiment, the building wall panel is manufactured as follows. On the vibrating table, the side equipment is installed, corresponding to the configuration of the building wall panel as a whole. At the same time, the shape of the sides is made in accordance with the sequence of filling the layers. Let us describe an example with the start of pouring from the formation of the second concrete-containing layer 5. A concrete mixture is poured, for example, grade B25. In the specified layer (which forms the second concrete-containing layer 5 after solidification), connecting elements 20 are installed at one end before solidification. the porosity of the structure of the second heat-insulating plate 4 and the incompleteness of the drying process of the concrete mixture, the second concrete-containing layer 5 is partially adhered to the second heat-insulating plate 4. The first heat-insulating plates 2 are installed on the second heat-insulating plate 4 with the formation of a distance between them to form ribs 3 and crossbars. If necessary, reinforcing elements, lifting elements, embedded parts for fastening, adjusting elements, embedded parts for panel screed, embedded parts for connection are placed inside the mold. After that, a concrete solution is poured into the mold to form the first concrete-containing layer 1 with ribs 3 and crossbars. The concrete mortar partially penetrates into the porous structure of the first heat-insulating plate 2 and the second heat-insulating plate 4 and their mutual engagement with each other takes place. The ends of the connecting elements 20, opposite to those fixed in the second concrete-containing layer 5, after hardening, are fixed in the first concrete-containing layer 1 and/or, in particular, in the ribs 3 and crossbars. After the concrete mortar has hardened, the resulting building wall panel is removed from the mold.

The installation of the building wall panel according to the first embodiment, the second embodiment and the third embodiment is carried out as follows. The building wall panel is delivered to the installation site and mounted in such a way that the building wall panel faces the first outer surface 8 into the interior of the room. At the same time, the installation position of the building wall panel is such that the first concrete-containing layer 1 and the second concrete-containing layer 5 are arranged vertically. In this case, the first upper surface 16 and the second upper surface 13 are located higher than the first lower surface 19 and the second lower surface 17.

The adjacent panel 23 is placed in the L-shaped corner formed by the side joint surface 25. The building wall panel is connected to the adjacent panels 23. The seam formed at the joint has an L-shaped configuration. At the same time, between the building wall panel and adjacent panels 23, fire-prevention pads 21 are located, which are a layer of mineral (basalt) wool, and ensure fire safety during the operation of the structure. Fire-resistant pads 21 are made as part of the adjacent panel 23. From the side of the room, the seam is additionally filled with mounting foam 22. From the outside, the seam is additionally filled with a sealing compound 24. The sealing compound 24 is located behind the side protrusion 6 of the building wall panel, which has a positive effect on the appearance of the structure in in general.

Under the influence of environmental factors, such as wind, rain, soil subsidence, mechanical impact, cracks may appear at the junction of the building wall panel with the adjacent panel 23. In this case, in the case of a straight-line seam, as in the prototype, there is a risk of leakage and how a consequence of the penetration into the room of cold air and moisture from the external environment. The implementation of the seam curvilinear contributes to the increase, in comparison with the rectilinear, aerodynamic resistance for the penetration of environmental factors through the crack. In a particular case, when making a L-shaped seam, a crack usually appears in one of the parts of the L-shaped seam. At the same time, the other part of the seam, located at an angle to the damaged one, remains intact, which prevents the penetration of air and moisture into the room. It follows from the above that the implementation of the building wall panel according to this technical solution reduces heat losses, reduces or prevents moisture penetration, which increases the operational reliability and wear resistance of the seam as a whole.

Thus, the implementation of a building wall panel with the set of essential features indicated in the formula ensures a reduction in heat losses of the building structure as a whole.

Claims (5)

1. Building wall panel containing the first concrete-containing layer and the second concrete-containing layer, the first concrete-containing layer is limited by the first outer surface, the first two side surfaces, the first upper surface and the first lower surface, the first side surfaces are located on opposite sides of the first concrete-containing layer, the first upper surface and the first lower surface is located on opposite sides of the first concrete-containing layer, the second concrete-containing layer is limited by the second outer surface, two second side surfaces, the second upper surface and the second lower surface, the second side surfaces are located on opposite sides of the second concrete-containing layer, the second upper surface and the second lower the surface is located on opposite sides of the second concrete-containing layer, the first outer surface and the second outer surface are made larger than the other surfaces, while the first concrete-containing layer and the second concrete-containing layer are made integrally from the concrete-containing material, so that the first outer surface and the second outer surface are located with opposite sides, while the second concrete-containing layer on the side of one second side surface forms one side protrusion with respect to the first concrete-containing layer, and on the side of the other second side surface forms another side protrusion with respect to the first concrete-containing layer, with the formation of one first side surface and adjacent to it the surface of the side protrusion of one side docking surface, and with the formation of the other first side surface and the surface of the side protrusion of the other side docking surface adjacent to it, both side docking surfaces are L-shaped in cross section, the second concrete-containing layer from the side of the second upper surface forms an upper protrusion with respect to the first concrete-containing layer, and the first upper surface and the surface of the upper protrusion adjacent to it form an upper mating surface made L-shaped in cross section. 2. Building wall panel containing the first concrete-containing layer, the second concrete-containing layer, heat-insulating element and connecting elements, the first concrete-containing layer is limited by the first outer surface, the first two side surfaces, the first upper surface and the first lower surface, the first side surfaces are located on opposite sides of the first concrete-containing layer, the first upper surface and the first lower surface are located on opposite sides of the first concrete-containing layer, the second concrete-containing layer is limited by the second outer surface, two second side surfaces, the second upper surface and the second lower surface, the second side surfaces are located on opposite sides of the second concrete-containing layer, the second upper surface and the second lower surface are located on opposite sides of the second concrete-containing layer, the first outer surface and the second outer surface are larger than the other surfaces, the heat-insulating element is limited by two third side surfaces, a third upper surface and a third lower surface, the third side surfaces are located on opposite sides of the heat-insulating element, the third upper surface and the third lower surface are located on opposite sides of the heat-insulating element, the heat-insulating element is located between the first concrete-containing layer and the second concrete-containing layer and is connected to them, while the first outer surface and the second outer surface are facing in opposite directions from heat-insulating element, and the second concrete-containing layer on the side of one second side surface forms one lateral protrusion with respect to the heat-insulating element and the first concrete-containing layer, and on the other second side surface forms another side protrusion with respect to the heat-insulating element and the first concrete-containing layer, with the formation one first lateral surface, one third lateral surface and the surface of the lateral protrusion of one side docking surface adjacent to it, and with the formation of the other first side surface, the other third side surface and the surface of the side protrusion of the other side docking surface adjacent to it, moreover, both side docking surfaces made L-shaped in cross section, the second concrete-containing layer from the side of the second upper surface forms an upper protrusion with respect to the heat-insulating element and the first concrete-containing layer, and the first upper surface, the third upper surface and the surface of the upper protrusion adjacent to it form an upper mating surface, made L-shaped in cross section, each connecting element is located with one of its ends in the first concrete-containing layer, and with its other end in the second concrete-containing layer. 3. Building wall panel containing the first concrete-containing layer, the second concrete-containing layer, the first heat-insulating slabs, the second heat-insulating slab, ribs, the top crossbar, the bottom crossbar and connecting elements, the first concrete-containing layer is limited by the first outer surface, the first inner surface, the first two side surfaces , the first upper surface and the first lower surface, the first outer surface and the first inner surface are made larger than the other surfaces of the first concrete-containing layer, and are generally parallel to each other, the first side surfaces are located on opposite sides of the first concrete-containing layer, the first upper surface and the first lower surface is located on opposite sides of the first concrete-containing layer, the upper crossbar is located on the first inner surface near the first upper surface, the lower crossbar is located on the first inner surface near the first lower surface, the ribs are located on the first inner surface generally parallel to each other and to the first side surfaces from the upper crossbar to the lower crossbar, the first concrete-containing layer, the ribs and the crossbars are made integrally from the concrete-containing material, the first heat-insulating plates are located between the ribs flush with the surfaces of the ribs opposite the first inner surface, the second heat-insulating plate adjoins one of its largest surfaces to the first heat-insulating plates and ribs, the second concrete-containing layer is bounded by the second outer surface, the second inner surface, the two second side surfaces, the second upper surface and the second lower surface, the second outer surface and the second inner surface have larger areas than the other surfaces of the second concrete-containing layer, the second outer surface and the second the inner surface is generally parallel to each other, the second side surfaces are located on opposite sides of the second concrete-containing layer, the second upper surface and the second lower surface are located on opposite sides of the second concrete-containing layer, the second concrete-containing layer is adjacent with the second inner surface to the second heat-insulating slab, while the second the concrete-containing layer on the side of the second side surfaces forms lateral ledges with respect to the second heat-insulating plate, the second concrete-containing layer on the side of the second upper surface forms an upper ledge with respect to the second heat-insulating plate, the connecting elements are made in the form of rods with fasteners at the ends, each connecting element is located with one end in the first concrete-containing layer, and with its other end in the second concrete-containing layer. 4. Building wall panel according to claim 3, characterized in that the fasteners are made in the form of bulges. 5. Building wall panel according to claim 3, characterized in that the fasteners are made in the form of protrusions.

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