RU220418U1 - Construction composite block - Google Patents

Abstract

The utility model relates to the production of building materials, and can be used, in particular, in low-rise construction, as well as in the construction of civil and industrial facilities, such as residential buildings, cottages and other buildings. The technical results of the claimed utility model are increasing the strength and durability of a building structure made of composite building blocks, expanding the arsenal of tools for similar purposes. The specified technical result is achieved by the fact that in a building composite block, characterized by execution in the form of a panel in the shape of a parallelepiped, consisting of three layers fastened together: two outer plates and an inner layer of filler, while the outer plates are equally offset relative to the inner layer of filler horizontally and vertical planes, according to the claimed utility model, the filler layer has a smaller geometric size in the vertical plane along the block relative to the geometric size in the vertical plane of the outer plates, which ensures the formation of vertical and horizontal adhesive gaps between the inner layers of filler of interconnected building composite blocks, while the outer plates are structural and made of a slab containing a fractional composition of crushed wood on a cement base with mineral additives. 5 ill.

Description

The utility model relates to the production of building materials, and can be used, in particular, in low-rise construction, as well as in the construction of civil and industrial facilities, such as residential buildings, cottages and other buildings.

A building block is known, consisting of a load-bearing layer, a front layer and an internal thermal insulation layer of polyurethane foam, while the load-bearing and front layers are fixed relative to each other due to the high adhesive properties of the polyurethane foam located between them. The adhesive connection of the heat-insulating layer with the load-bearing and front layers is formed after the polyurethane foam has cured. [RU 88705, E04C 1/00, publ. 20.11.2009]

A multilayer building block for the construction of buildings and structures is known, consisting of a central and two outer protective layers, with the outer layers made of graphite fiber, intercalated graphite and a binder based on liquid glass, and the central layer is made of structural and thermal insulation material, which contains includes wood filler, the central layer can be made of structural and heat-insulating wood concrete, structural and heat-insulating fiberboard, structural and heat-insulating xylotite. [RU 205479, E04C 1/00, publ. July 15, 2021]

The disadvantages of these analogues are the insufficient strength of the building structure, namely load-bearing walls for the construction of buildings and structures when using a multilayer building block.

The closest in technical essence and achieved effect is a building block made in the form of a panel in the shape of a rectangular parallelepiped, consisting of three layers fastened together - two panel parts and a filler layer between them. Both panel parts are made in the form of identical assemblies symmetrically located relative to the horizontal axis of the building block. Each assembly consists of two plates fastened together in the largest plane, parallel offset relative to each other on two sides.

Between the inner plates of the panel parts, on their opposite sides and flush with their outer edges, two or more identical racks are fixed in the form of rectangular parallelepipeds, oriented with their longitudinal axes parallel to the vertical axis of the building block. A layer of panel core is placed between the posts. All panel parts are fastened together using glue or fasteners. When a building structure is assembled from building blocks, the protrusions formed by the inner plates of the opposing parts of the building block assemblies are aligned in both horizontal and vertical planes with the corresponding recesses formed by the outer plates of the opposing parts of the building block assemblies in adjacent building blocks, which allows the building blocks to the assembly is self-centering in two planes without additional devices or auxiliary technological operations. At the same time, in the vertical plane of the structure erected from building blocks, the racks of each overlying building block rest on the racks of the underlying building block, so that upon completion of the vertical assembly of the building structure, a whole series of hidden multi-link vertical load-bearing racks are formed inside it, significantly increasing its load-bearing capacity, determined by the design and rack material. [RU 2588264, E04C 1/40, publ. June 27, 2016]

The disadvantage of the closest analogue is the complexity of installation of the structure, high labor costs, increased construction time of load-bearing walls, insufficient strength of the connection of building blocks with each other when using a building block and, as a consequence, the strength and stability of the building structure as a whole.

The technical problem of the claimed utility model is the creation of a building composite block, the design of which provides a strong and durable building structure, reliable connection and fixation of the layers of masonry blocks relative to each other.

The technical results of the claimed utility model are increasing the strength and durability of a building structure made of composite building blocks, expanding the arsenal of tools for similar purposes.

The specified technical result is achieved by the fact that in a building composite block, characterized by execution in the form of a panel in the shape of a parallelepiped, consisting of three layers fastened together: two outer plates and an inner layer of filler, while the outer plates are equally offset relative to the inner layer of filler horizontally and vertical planes, according to the claimed utility model, the filler layer has a smaller geometric size in the vertical plane along the block relative to the geometric size in the vertical plane of the outer plates, which ensures the formation of vertical and horizontal adhesive gaps between the inner layers of filler of interconnected building composite blocks, while the outer plates are structural and made of a slab containing a fractional composition of crushed wood on a cement base with mineral additives.

It is a known fact that the strength and durability of building structures are characterized by the following factors: improved adhesion, reduced likelihood of cracks, load absorption, shrinkage compensation, increased adhesion, compensation for unevenness, load distribution.

Making the filler layer having a smaller geometric size in the vertical plane along the block relative to the geometric size in the vertical plane of the outer plates, which ensures the formation of vertical and horizontal adhesive gaps between the internal layers of filler of interconnected building composite blocks, ensures the above-mentioned strength and durability characteristics of building structures made of the declared building composite block, namely:

1. Improved adhesion: The gap between the building composite blocks allows you to reduce the amount of adhesive and get better adhesion between the building composite blocks. The adhesive composition evenly fills the gap and creates a monolithic structure, which increases the strength and reliability of the connection.

2. Reducing the likelihood of cracks: the adhesive gap allows for slight differences in the size of the filler layer, if there is an adhesive gap, an irregularly shaped connection between adjacent composite building blocks can be compensated. This eliminates the possibility of cracks, distortions or breaks in the wall.

3. Load Absorption: The gap between building composite blocks can serve as shock absorption when subject to increased loads, such as earthquakes or thermal loads. The gap will help reduce stress in the wall and prevent destruction.

4. Shrinkage compensation: The gap allows you to compensate for the shrinkage of materials. Over time and different climatic conditions, building materials may shrink slightly. The gap provides additional space for shrinkage, minimizing possible damage to the structure as a whole.

5. Increased adhesion: The presence of gaps allows the adhesive composition to penetrate between the building composite blocks and fill all micro-irregularities of the surface. This results in an increase in the contact area between the compound, which increases adhesion (cohesion) and a stronger connection.

6. Compensation for unevenness: Adhesive gaps can compensate for small unevenness or dimensional discrepancies between composite building blocks. The adhesive compound can fill these imperfections and provide a more reliable adhesive connection.

7. Load distribution: Adhesive gaps between building composite blocks allow the adhesive composition to be quickly distributed over the entire joint surface. The adhesive composition that fills the gaps allows for higher loads, which increases the strength of the joints and eliminates the risk of cracks and peeling.

Increasing the strength and durability of a building structure made from building composite blocks is also ensured through the manufacture of outer plates from a fractional composition of crushed wood on a cement base with mineral additives. This material has high strength characteristics. In particular, when moisture is gained and lost, the outer plates made of a fractional composition of crushed wood on a cement base with mineral additives do not have linear expansion, which eliminates ruptures/tears of adjacent blocks at the gluing site.

The building composite block is illustrated by drawings, where figure 1 shows a building composite block, general view, figure 2 shows a side view, a longitudinal section in a vertical plane, without displacement of the outer plates, figure 3 shows an example of the implementation of a building composite block in a building structure, figure Figure 4 is an installation option for a building composite block in a building structure with a view of the adhesive gap in the horizontal plane; figure 5 is an installation option with a view of the adhesive gap in the vertical plane.

The building composite block contains three layers fastened together: two outer plates 1 (Fig. 1, 3, 4, 5) and an inner layer of filler 2. The outer plates 1 (Fig. 1, 3) are equally offset relative to the inner layer of filler 2 along horizontal plane 3 and vertical plane 4. Due to the displacement in the vertical 4 and horizontal 3 planes, an articulation unit 5 is formed (Fig. 3, 4, 5) and adhesive gaps 6 between the inner layers of filler 2 of two adjacent building structural blocks. The adhesive gap 6 is formed due to the fact that the filler layer 2 (Fig. 2) has a smaller geometric size in the vertical plane along the block relative to the geometric size in the vertical plane 4 of the outer plates 1. The outer plates 1 are structural and are made of a plate containing a fractional composition crushed wood on a cement base with mineral additives. As a material for the manufacture of outer plates 1 of a building composite block, for example, Fibrolite can be used, which is a special case of a board containing a fractional composition of crushed wood on a cement base with mineral additives, or other boards based on a similar fractional composition of crushed wood on a cement base with mineral supplements for example:

Fibrolite boards (Fibrolite) are a board material made from wood fibers (the so-called “wood wool” - long and thin ribbon-like shavings), a binder and mineral additives.

Cement particle board (CPB) - made from thin wood chips, cement and chemical additives

Particle-cement board (PCB) is a pressed board of size consisting of coniferous wood chips and cement, with the addition of liquid glass (an aqueous alkaline solution of sodium and (or) potassium silicates).

Chip-cement board - made from wood chips with a cement binder and mineral additives.

An example of the use of a building composite block for the manufacture of external plates can be, in particular, boards from the Green Board ® company consisting of: 60% wood wool, 39.8% Portland cement, 0.2% sodium silicate solution (liquid glass) - natural mineralizer.

As filler layer 2, insulation can be used, for example, Expanded polystyrene, polystyrene foam (EPS), Extruded polystyrene foam (EPS), Polyurethane foam (PPU), Polyisocyanurate (PIR), Penoizol (organic cellular urea foam), Mineral wool (insulation with a fibrous structure ) or other similar material.

The building composite block is manufactured as follows.

The first of the outer plates 1, made of a slab containing a fractional composition of crushed wood on a cement base with mineral additives, is placed on a work table equipped with form-building clamps that repeat the shape of a building composite block. An adhesive composition is applied to the outer plate 1. A layer of filler 2 is placed on the outer plate 1 with the adhesive composition, offset relative to the outer plate 1 along the horizontal 3 and vertical 4 planes. The filler layer 2 has a smaller geometric size in the vertical plane 4 along the block relative to the geometric size in the vertical plane of the outer plates 1. Next, an adhesive composition is applied to the filler layer 2 and the second outer plate 1 is laid with an offset repeating the displacement of the first outer plate 1 in the horizontal 3 and vertical 4 planes. The position of the outer plates 1 is fixed strictly parallel to the filler layer 2. Due to the equal displacement of the outer plates 1 relative to the filler layer 2, an articulation unit 5 is formed, a groove on one side of the building composite block and a protrusion on the other side of the latter. After laying the outer plates 1 and a layer of filler 2 with an adhesive composition applied between all contacting planes. The workpiece is fixed and tightened for a strong and uniform connection of the outer plates 1 and the filler layer 2. After the adhesive joint has gained strength, the finished building composite block is removed from the work table and then used for its intended purpose on the construction site.

The building composite block is used as follows.

To manufacture building structures, in particular, load-bearing walls and partitions, building elements are laid in the form of ready-made building composite blocks with articulation units 5 with adjacent building blocks in the vertical 4 and horizontal 3 planes.

When laying building composite blocks, they are connected at joints 5, which are created by equally offset outer plates 1 in the vertical 4 and horizontal 3 planes. Adjacent building composite blocks in the vertical and horizontal planes have adhesive gaps 6 formed between the inner layers of filler 2, due to the smaller geometric size in the vertical plane 4 along the block relative to the geometric size in the vertical plane of the outer plates 1. The adhesive gap 6 of interconnected building composite blocks blocks are filled with adhesive material, for example, polyurethane adhesive foam. It is possible to use any other adhesive composition, including a cement-based one, that has the necessary binding properties. Building composite blocks are laid according to the rules for laying blocks during the construction of walls of building structures and structures. An example of the implementation of the claimed utility model with explanations of the locations of adhesive gaps in a building structure made from the claimed composite building block is also presented in Figure 3.

Due to the presence of adhesive gaps formed between the inner layers of filler 2, due to the smaller geometric size in the vertical plane 4 along the block relative to the geometric size in the vertical plane of the outer plates 1 and their subsequent filling with adhesive material, as well as due to the execution of the outer plates from the slab, containing a fractional composition of crushed wood on a cement base with mineral additives, increases the strength and durability of the building structure made from the declared building composite blocks.

In addition, the claimed composite block has the following characteristics:

high performance indicators - the main resistance of the walls to loads is effective in the outer edge zones, where the outer plates are located, since the cross-section of the building composite block is a T-beam.

sound insulation characteristics - a three-layer construction of a composite building block, namely external plates made from a fractional composition of crushed wood on a cement base with mineral additives and installed on both sides and a layer of filler, effectively insulate and absorb sound and impact noise.

environmentally friendly - external plates made of a fractional composition of crushed wood on a cement base with mineral additives, created on the basis of wood filler on an organic binder and cement base (environmentally friendly material) fence off and completely isolate the external environment from the adhesive composition and filler.

fire safety - external plates made of a fractional composition of crushed wood on a cement base with mineral additives do not support combustion

reduction of the total time for the construction of buildings and structures - due to simple installation.

Claims (1)

A building composite block, characterized by being made in the form of a panel in the shape of a parallelepiped, consisting of three layers fastened together: two outer plates and an inner layer of filler, while the outer plates are equally offset relative to the inner layer of filler along the horizontal and vertical planes, characterized in that the layer the filler has a smaller geometric size in the vertical plane along the block relative to the geometric size in the vertical plane of the outer plates, which ensures the formation of vertical and horizontal adhesive gaps between the inner layers of the filler of interconnected building composite blocks, while the outer plates are structural and made of a slab containing fractional composition of crushed wood on a cement base with mineral additives.