RU78833U1 - MULTILAYER BUILDING BLOCK (OPTIONS) - Google Patents

Abstract

1. A multilayer building block consisting of an outer layer, a bearing layer and a heat-insulating layer located between them, fastened together by rods, characterized in that the bearing, heat-insulating and outer layers are connected by three basalt-plastic reinforcing rods located at right angles to the open surfaces of the bearing and the outer layers of the block in such a way that in the plan they form an isosceles triangle, and in the body of the block they form the spatial structure of the prismatic shape, while in the longitudinal and operechnom sectional distance "a" between the projections and the end faces of the cores are equal, and the distance between the rods and the sides of the exposed surfaces in the transverse plane is equal to half the distance "a" .2. A multilayer building block according to claim 1, characterized in that the sides of the heat-insulating layer adjacent to the outer and the bearing layers are made with surface perforation either of a round, oval, or other shape. A multilayer building block according to claim 1, characterized in that the shanks of the reinforcing bar are made of a coating of an epoxy resin-based composition with sand applied to it. A multilayer building block according to claim 1, characterized in that the entire reinforcing bar is made with a coating of an epoxy resin-based composition with sand applied to it. A multilayer building block consisting of an outer layer, a bearing layer and a heat-insulating layer located between them, fastened together by rods, characterized in that the supporting, heat-insulating and outer layers are connected by three basalt-plastic reinforcing rods

Description

The utility model relates to the production of building materials used in particular in low-rise construction, as well as in the construction of civil and industrial facilities with high requirements for decorative exterior cladding of buildings, heat and sound insulation of premises, such as residential buildings, cottages and other buildings.

Known three-layer outer wall of the building, containing the inner supporting layer, the outer layer and the insulating layer located between them, connected by rows of reinforcing rods (patent RU No. 2243336, class E04C 1/76, 2004). This design provides a sufficiently strong connection of the outer and inner layers, but has a high material consumption, is expensive and complex.

A well-known building wall block containing two building layers separated by a core of heat-insulating material, while the heat-insulating core is made of polystyrene foam or other material similar in strength and thermophysical properties (patent RU No. 2131501, class Е04С 1/40, 2000). Such a building block requires additional finishing of the outer front surface of the walls erected from it. In addition, the connection between the layers does not provide sufficient strength of the entire block, despite the variety of forms of configuration of the insulating core.

Known multilayer building block, consisting of an external decorative layer adjacent to it a concrete layer, which adjoins a heat-insulating layer, and an internal concrete bearing layer connected by fiberglass rods (patent RU No. 2208102, cl.

E04C 1/40, 2003). This building block is complex and expensive to manufacture and assemble.

The closest technical solution to the claimed utility model is a multilayer building block consisting of a decorative layer, a bearing layer and a heat-insulating layer of expanded polystyrene located between them, fastened together by polymer rods installed at different angles to all layers of the block (see patent RU No. 2317381 , CL E04C 1/40, 2008).

This utility model is aimed at solving the technical problem of increasing the strength and stiffness of a block and its layers together, simplifying and cheapening the construction of a building block and the technology for its manufacture.

The solution of the technical problem, according to the first embodiment, is achieved by the fact that in a multilayer building block consisting of an outer layer, a carrier layer and a heat-insulating layer located between them, all layers are fastened together by three basalt-plastic reinforcing bars located at right angles to the open surfaces of the carrier and the outer layers of the block in such a way that in the plan they form an isosceles triangle, and in the body of the block they form a spatial structure of a prismatic shape, while in longitudinal SG and the cross-sectional distance "a" between the projections and the end faces of the cores are equal, and the distance between the rods and the sides of the exposed surfaces in the transverse plane is equal to half the distance "a". The sides of the heat-insulating layer adjacent to the outer and supporting layers are made with surface perforation of either round, oval, or other shape. Either the shanks of the reinforcing rod, or the entire reinforcing bar is made of a coating of an epoxy resin composition with sand applied to it.

According to the second option, the solution of the problem is achieved by the fact that in a multilayer building block consisting of an outer layer,

the bearing layer and the heat-insulating layer located between them, fastened together by rods, all layers are connected by three basalt-plastic reinforcing rods located at right angles to the open surfaces of the outer and the bearing layers of the block in such a way that they form an isosceles triangle in plan, and rods with their monolithic outer and bearing layers ends form a spatial structure of a prismatic shape, while in the longitudinal and transverse sections of the distance "a" between the projections times and end faces are equal to each other, and the distance between the rods and the open surfaces of the sides in the transverse plane is half the distance "a", while the sides of the heat-insulating layer are made with surface perforation either round, oval, or another shape, or reinforcing shanks the rod or the entire reinforcing bar is coated with an epoxy resin-based composition with sand applied to it.

The utility model is illustrated by drawings. Figure 1 shows the building block, Figure 2 is the same, section aa, figure 3 is the same, view G on the carrier layer, figure 4 is a heat-insulating layer, section bb.

The multilayer building block includes an outer face layer 1, an adjacent heat-insulating layer 2 and a carrier layer 3, fastened together by three basalt-plastic reinforcing bars 4, 5. The heat-insulating layer 2 is made of a dense, heat-efficient material, for example, polystyrene foam or foam or other similar material . Either the shanks of the reinforcing bars 4, 5 or all the reinforcing bars are coated with a composition based on epoxy resin with sand applied to it. The reinforcing bars 4, 5 are located at right angles both to the open surface 6 of the outer, face layer of the block, and to the open surface 7 of the bearing layer, so that they form an isosceles triangle in plan (see figure 3, is indicated by a dotted line), and in the body of the block rods 4, 5 form a spatial

prismatic structure. The prism is formed by two rods 4, one rod 5, and their ends are monolithic by the bearing and outer layers, i.e. the ends are connected respectively by the carrier layer 3 and the outer layer 1. The rods 4, 5 are located in the body of the building block in such a way that in the longitudinal and transverse sections the distances “a” between the projections of the rods 4, 5 are equal. The distance between the rods 4 and the end faces 8 of the block is equal to the distance "a", while the distance between the rods 4, 5 and the sides 9, 10 is equal to half the distance "a". The carrier layer 3 is made of expanded clay mixture with a density of 900 ÷ 1000 kg / m ³ and the outer layer 1 is made of expanded clay mixture with a density of 1600 ÷ 1800 kg / m ³ . If necessary, a plasticizer or coloring pigment is added to the expanded clay mixture of the outer layer. Due to the high strength of the carrier 3 and the outer 1 layers, the ends of the rods 4, 5 after solidification of the mixtures are rigidly clamped on both sides, firmly pulling together the layers 1, 2 and 3. The spatial prism formed by three rods 4, 5 has high strength characteristics, which makes it possible to reduce the cost of materials for the manufacture of rods. This block reinforcement allows you to redistribute the load from eccentric compression from the carrier layer 3 to the outer layer 1, removing part of the load from the most loaded carrier layer 3. The use of basalt-plastic mixtures in the manufacture of rods can significantly reduce their cost while increasing the strength characteristics of each rod. Due to the fact that the rod polymers are reinforced with basalt fibers, their strength increases and thermal conductivity decreases, which eliminates the formation of “cold bridges” between layers 1 and 3. The use of a composition based on epoxy resin coated with sand for reinforcing bars or their shanks increases adhesion (adhesion ) rods with expanded clay mixture of layers 1 and 3, increasing the strength of the block.

The heat-insulating layer 2 is made using materials having low thermal conductivity, for example, from polystyrene foam,

possessing qualities universal for the construction of this unit and providing the necessary heat-insulating properties and good damping during compression-stretching of the blocks, especially when changing seasons (from plus to minus and vice versa). In the manufacture of the polystyrene insert of the heat-insulating layer 2, surface perforations are made on both sides of the surface — dents 11 are either round, oval, or another shape (for example, by hot pressing).

In the manufacture of the block, a factor-forming matrix is preliminarily laid on its bottom, and then the mixture is poured to obtain the outer layer 1, then the polystyrene foam of the heat-insulating layer 2 is laid and pierced with rods until the ends of the rods partially enter the layer 1, and then the ends of the rods are poured with a claydite-concrete mixture bearing from above layer 3. The rods penetrate the entire block at three points with the formation of an isosceles triangle at their ends and equal distances between their projections.

The multilayer building block is intended for use in all areas of Russia and other countries, regardless of climatic conditions, as with sufficient simplicity of design and external decorativeness, it provides good thermal insulation properties (resistant to low and high temperatures) and the stability of the outer layer 1. In cold regions, houses from these multilayer blocks retain heat indoors, and in hot countries they keep cool with minimal air conditioning . In earthquake-prone regions, the design of such a multilayer block with a spatial prism of rods provides seismic stability of buildings and structures. Blocks are used for masonry walls, fix them with a solution of a binder composition (for example, masonry glue) with the outer layer 1 facing outward, and the carrier layer 3 facing the inside of the room. One of the functions of the carrier layer 3 is the frame; the masonry structure is supported on it. Using a spatial prism of the rods allows part of this function to be redistributed to the outer layer 1, reinforcing

the whole structure as a whole. Layers 1, 2 and 3 vertically and horizontally tightly adhere to the same layers of other blocks, forming a single monolithic wall. In this case, the heat-insulating layer 2 of each block is in close contact with the heat-insulating layers of 2 adjacent blocks, forming a single heat-insulating space.

The use of thermal insulation, for example, from polystyrene foam, with dents 11 on the surface of the heat-insulating layer 2 provides not only thermal insulation properties and good damping during compression-tension of the blocks during temperature changes, but also significantly increases adhesion (adhesion) to the carrier layer 3 and the outer layer 1. The adhesion of the block increases during its manufacture, when the outer layer 1 is poured, and after installing the insert of the insulating layer 2, the liquid mixture penetrates the dents 11 and freezes in them. After pouring the carrier layer 3, the cement mixture penetrates the dents 11 from the opposite side of the insulating layer 2 and also solidifies. The design of the block with a spatial prism and surface perforation of the heat-insulating layer 2, filled with mixtures of layer 1 and layer 3 from different sides, forms a strong, rigid structure, significantly reducing the likelihood of separation of the block during transportation and accidental fall.

The use of basalt-plastic reinforcing bars for screeding all layers 1, 2 and 3 eliminates the formation of corrosion during operation of the building in wet conditions. And the spatial prism of reinforcing bars 4, 5 with a special adhesive coating provides strong retention and contraction of the outer layer 1, the heat-insulating layer 2 and the carrier layer 3 in a multilayer building block, excluding the rotation of the rods around its axis. The location of the rods in the form of a trihedral spatial prism helps to increase the strength and fracture toughness of the structure.

This design using basalt-plastic reinforcing bars 4, 5 in the form of a trihedral spatial prism and surface

perforation of the insulating layer 2 is used in blocks having additional layers: for example, decorative, intermediate bearing and others.

Due to the use of basalt-plastic reinforcing rods 4, 5 with a special adhesive coating for screeding layers 1, 2 and 3 during wall laying, which allow redistributing part of the load from eccentric compression from the carrier layer 3 to the outer layer 1, and additional adhesion from the use of surface-perforated inserts for thermal insulation layer 2, all vertical, lateral and angular loads are evenly distributed along the height and width of the masonry between the bearing layers 3 and the outer layers 1 of all blocks.

Thus, the claimed utility model solves the technical problem of increasing the strength and stiffness of the block and its layers among themselves, simplifying and cheapening the construction of the building block and the technology of its manufacture.

Claims (5)

1. A multilayer building block consisting of an outer layer, a bearing layer and a heat-insulating layer located between them, fastened together by rods, characterized in that the bearing, heat-insulating and outer layers are connected by three basalt-plastic reinforcing rods located at right angles to the open surfaces of the bearing and the outer layers of the block in such a way that in the plan they form an isosceles triangle, and in the body of the block they form the spatial structure of the prismatic shape, while in the longitudinal and operechnom sectional distance "a" between the projections and the end faces of the cores are equal, and the distance between the rods and the sides of the exposed surfaces in the transverse plane is equal to half the distance "a". 2. The multilayer building block according to claim 1, characterized in that the sides of the heat-insulating layer adjacent to the outer and the bearing layers are made with surface perforation of either round, oval, or other shape. 3. The multilayer building block according to claim 1, characterized in that the shanks of the reinforcing rod are made with a coating of an epoxy resin composition with sand applied to it. 4. The multilayer building block according to claim 1, characterized in that the entire reinforcing rod is made with a coating of an epoxy resin composition with sand applied to it. 5. A multilayer building block, consisting of an outer layer, a bearing layer and a heat-insulating layer located between them, fastened together by rods, characterized in that the bearing, heat-insulating and outer layers are connected by three basalt-plastic reinforcing rods located at right angles to the open surfaces of the outer and of the bearing layers of the block in such a way that in the plan they form an isosceles triangle, and in the body of the block the rods with their monolithic outer and bearing layers ends form a space the prismatic shape, while in the longitudinal and transverse sections, the distances “a” between the projections of the rods and the end faces are equal to each other, and the distance between the rods and the exposed surfaces of the sides in the transverse plane is half the distance “a”, while the sides of the heat-insulating layer made with surface perforation either round, oval, or other shape, or either the shanks of the reinforcing rod, or the entire reinforcing bar is made with a coating of an epoxy resin-based composition with sand on it.