RU189147U1 - FLEXIBLE CONCRETE COATING - Google Patents

Abstract

The utility model relates to the field of construction, in particular, to a flexible concrete pavement, and can be used for the construction of precast coverings for pedestrian roads, as well as in landscape architecture or interior design. The flexible concrete pavement containing concrete blocks interconnected with a gap using vibratory casting technology, while the blocks are interconnected by means of a reinforcing mesh made of flexible material that is enclosed in a mass of concrete and is not subject to rotting. The technical result of the utility model is to increase the reliability, safety and durability of the flexible concrete pavement by ensuring the stability of the specified gaps between the blocks, the smooth front surface of the blocks and increasing the strength of each block in bending and coating in general. Additional technical results are the acceleration of the process of laying the process of producing a flexible concrete pavement and its laying.

Description

The utility model relates to the field of construction, in particular to a flexible concrete surface, and can be used for the construction of prefabricated coverings for pedestrian roads, as well as in landscape architecture or interior design.

In the prior art it is known that slabs of various shapes and sizes are most often used for paving of pedestrian roads. The technology of construction of such coatings involves a time-consuming process of single-piece laying of each plate.

Known concrete paving slabs (GOST 17608-91), used to cover pedestrian roads. In most cases, the plates are stacked on the prepared base without attaching to each other.

The disadvantage of this concrete pavement is that over time, the gap between the plates increases, and there is a subsidence of individual plates, which leads to its premature destruction.

It is also known universal flexible protective concrete coating (RF Patent No. 2129635, Е02В 3/12, publ. 04/27/1999), containing concrete blocks, made in the form of double-sided truncated pyramids with smaller truncated bases, which are the ends of concrete blocks, on which grooves are made, and cables connected together in order and in rows along the other bases of the pyramids. Nylon monopolized in concrete blocks are used as cables.

The disadvantage of this coverage of pedestrian roads is that when laying on pedestrian roads between concrete blocks large gaps are formed (for example, with a coating thickness of 100 mm, the gap exceeds 70 mm), which can cause pedestrian injuries (dislocations, stretching of the lower extremities, etc.). ). In addition, the blocks of such a coating are also characterized by subsidence due to insufficient fixation between themselves and premature failure.

Also from the prior art known flexible coating of concrete blocks (RF Patent No. 115366, Е02В 3/14, publ. 04/27/2012), containing concrete blocks connected in order by flexible ties, in each block on its side adjacent to the blocks of the adjacent row, Two through holes are made, the axes of which are parallel to each other and are located in the horizontal plane symmetrically relative to the vertical plane of symmetry of the block, and each subsequent row of blocks is shifted relative to the previous one in the direction along the row in such a way that the above The openings of each block of one row, lining up coaxially with the holes of two adjacent blocks of the adjacent row, form straight channels for flexible connections, each element of the flexible connection being passed through two adjacent straight channels to form a loop beyond the peripheral row of coating blocks, after which its free ends connect with each other.

This concrete coating also does not have the necessary stability of the gaps between the blocks. In addition, blocks for coatings are made by vibropressing technology, which does not allow achieving a smooth and even front surface of such a coating, as well as its strength and durability.

Thus, the concrete coatings known from the prior art do not have the necessary reliability, safety and durability.

The task, which the utility model is aimed at, is the development of an improved flexible concrete pavement, devoid of the drawbacks of the above analogues, as well as the expansion of the arsenal of technical means for the specified purpose.

The technical result of the utility model is to increase the reliability, safety and durability of the flexible concrete pavement by ensuring the stability of the specified gaps between the blocks, the smooth front surface of the blocks and increasing the strength of each block to bend and the coating as a whole. Additional technical results are the acceleration of the process of production of flexible concrete pavement and its installation.

The technical result is achieved by the fact that a flexible concrete coating containing concrete blocks interconnected with a gap is made of concrete using vibratory casting technology, while the blocks are interconnected by means of a reinforcing mesh enclosed in a mass of concrete that is not subject to rotting.

It is advisable that the coating was made of hydraulic concrete.

It is advisable that the reinforcing mesh was made of a composite material, preferably fiberglass.

It is advisable that the reinforcing mesh be integrated into the body of each block in the process of compacting the mass by vibrating the mold with concrete laid in it.

It is advisable that the bars of the reinforcing mesh connect the blocks in order and in rows, with each subsequent row of blocks being offset from the previous one in the direction along the row so that each block of one row is connected by at least one rod to at least one block of the next row.

It is advisable that the connecting blocks of the rod of the reinforcing mesh are enclosed in the mass of concrete and form connecting channels between the blocks.

It is advisable that the rods of the reinforcing mesh be integrated into the body of the block at a height of from 1/3 to 2/3 of the height of the block.

It is advisable that the diameter of the rods reinforcing mesh ranged from 2.0 to 4.0 mm.

It is advisable that at least two rods of reinforcing mesh, of which at least one longitudinal rod and at least one transverse rod, be integrated into each block.

It is advisable that the gap between adjacent blocks ranged from 5 to 40 mm.

The utility model is illustrated by drawings.

FIG. Figure 1 shows a fragment of a flexible concrete pavement — an isometric view.

FIG. Figure 2 shows a fragment of a flexible concrete pavement (radial design) - an isometric view.

FIG. 3 shows a fragment of a flexible concrete pavement - a plan view.

FIG. 4 shows a fragment of a flexible concrete pavement (radial design) - a plan view.

FIG. 5 shows a block of concrete pavement in section - side view.

FIG. 6 shows a block of concrete pavement in section (radial version) - side view.

FIG. 7 shows a fragment of a flexible concrete pavement in section - a plan view.

FIG. 8 shows a fragment of a flexible concrete pavement in section (radial version) - a plan view.

In a preferred embodiment, the flexible concrete coating is made of hydraulic concrete using vibratory casting technology and consists of several concrete blocks 1 interconnected by rods of reinforcing mesh 2 integrated into the body of each concrete block 1 and connecting channels 3 between blocks 1.

Concrete blocks 1, preferably, have a shape, which is based on a quadrangular truncated pyramid with beveled edges of the upper base, which allows you to bend, lift the floor by the edges without applying a "breaking out" load over the shoulder. The height of the block, preferably, is 25-40 mm, width from 40 to 150 mm, length from 90 to 110 mm. Also, concrete blocks 1 may have a different shape, for example, elliptical or round.

Reinforcing mesh 2 may be made of metal or composite material, preferably of fiberglass. The use of a mesh of composite material, in particular of fiberglass, allows to facilitate the coating, and, therefore, further simplify and accelerate the process of its installation, as well as transportation to the place of installation. In addition, the use of mesh of fiberglass allows you to further increase the strength of the product under tension, as well as its durability.

The mesh size of the reinforcing mesh 2 is preferably 50 × 50 mm. The use of reinforcing mesh 2 allows you to fix the gap between the blocks of the coating, which increases the durability and safety of the product, and also accelerates the process of laying the coating. The work of the reinforcing mesh 2 in compression in the interblock joints does not allow the individual blocks of the coating to move with a decrease in the seam.

The rods of the reinforcing mesh 2 are integrated into the body of each block 1 at a height of 1/3 to 2/3 of the block height, preferably 1/2 of the block height. To significantly increase the strength of each block and the coating as a whole, each block 1 preferably integrates from three to four rods of reinforcing mesh, of which at least two longitudinal rods connecting the blocks in rows and at least one transverse rod connecting the block with blocks of adjacent rows, with each subsequent row of blocks 1 being offset from the previous one in the direction along the row.

The rods of reinforcement stacks 2, located in the connecting channels 3, must have sufficient flexibility and their diameter ranges from 2.0 to 4.0 mm, preferably 2.5 mm, which allows laying the coating on curved surfaces. The width of the connecting channel is from 5.0 to 8.0 mm, preferably - 7 mm.

The gap between adjacent concrete blocks 1 is from 5.0 to 40.0 mm.

Concrete coating made by vibratory casting technology. The use of this technology allows not only to achieve a smooth, even surface of the blocks and a high durability of the coating, but also to create, if necessary, complex patterns and reliefs on the front surface of the blocks, for example, to imitate the texture of a natural stone.

For the manufacture of coating pre-prepared concrete mix. Concrete preparation is based on the selection of the particle size distribution and mineral aggregates, the amount and grade of cement, chemical additives and the calculation of the amount of water.

The concrete mix is poured into a polymer form with cavities that follow the shape of blocks 1 and connecting channels 3 between the blocks, with reinforcing mesh 2 laid in them. The cavities of channels 3, like the cavities of the blocks, are filled with concrete mix, which provides additional fixation of the gap between the blocks when laying cover.

After the concrete mixture is distributed in shape, it is compacted by vibration to remove excess air and fill voids, which allows increasing the density of the concrete mass and, consequently, the strength of the coating.

The distributed and compacted concrete mass is left to solidify. The finished concrete surface is removed from the mold and stored. The finished product has a light weight (about 25 kg) and can be delivered by vehicles to the place of installation and laid without the use of construction equipment and small mechanization.

According to the claimed technical solution, when laying the coating of the rods of the reinforcing mesh 2, located in the connecting channels 3, can be eaten by hand building tools (nippers, garden shears, etc.) to create complex radial patterns, as well as to fit the dimensions without using power tools. Concrete coating is laid on the prepared surface, covering the required area. At the same time, the integration of the reinforcing mesh into the blocks of the coating allows to increase the operational loads and simplify the design of the underlying layers. The coating can be laid on curved surfaces of complex shape. Interblock joints are filled with mineral filler without a binder or mortar for filling the joints of the pavement.

Concrete pavement of blocks is designed for indoor and outdoor use, including on inclined and vertical surfaces.

Claims (11)

1. Flexible concrete pavement containing concrete blocks interconnected with a gap, characterized in that it is made of concrete using vibratory casting technology, and the blocks are interconnected by means of a reinforcing mesh made of flexible material not subject to rotting. 2. Flexible concrete pavement according to claim 1, characterized in that it is made of hydrotechnical concrete. 3. Flexible concrete pavement according to claim 1, characterized in that the reinforcing mesh is made of a composite material. 4. Flexible concrete pavement according to claim 3, characterized in that the reinforcing mesh is made of fiberglass. 5. Flexible concrete pavement according to claim 1, characterized in that the reinforcing mesh is integrated into the body of each block in the process of compacting the mass by vibrating the mold with concrete laid in it. 6. Flexible concrete pavement according to claim 1, characterized in that the connecting blocks of the rods of the reinforcing mesh are enclosed in the mass of concrete and form connecting channels. 7. Flexible concrete pavement according to claim 1, characterized in that the rods of the reinforcing mesh connect the blocks in sequence and in rows, with each subsequent row of blocks being offset from the previous one in the direction along the row so that each block of one row is connected by at least one rod with at least one block of the adjacent row. 8. Flexible concrete pavement according to claim 1, characterized in that the rods of the reinforcing mesh are integrated into the block body at a height of from 1/3 to 2/3 of the block height. 9. Flexible concrete pavement according to claim 1, characterized in that the diameter of the rods of the reinforcing mesh is from 2.0 to 4.0 mm. 10. Flexible concrete pavement according to Claim. 1, characterized in that at least two rods of reinforcing mesh are integrated into each block, of which at least one longitudinal rod and at least one transverse rod. 11. Flexible concrete paving according to claim 1, characterized in that the gap between adjacent blocks is from 5.0 to 40.0 mm.

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