RU90811U1 - REINFORCED CONCRETE overlapping - Google Patents

Abstract

1. Overlap, characterized in that it includes a three-dimensional mesh structure of solid-bodied foam concrete elements and reinforcing rods, which is monolithic with heavy concrete, moreover, foam concrete solid bodies are interconnected by reinforcing bars intersecting inside them, with the formation of a mesh, the nodes of which are said foam concrete solid elements, wherein each foam concrete element is preferably made of variable cross-section, and the space between the elements is filled with concrete m to form a rigid honeycomb structure, whose height is preferably equal to the height of foam concrete corpulent elements. ! 2. The overlap according to claim 1, characterized in that the height of each element is adopted no less than its length and / or width. ! 3. The overlap according to claim 1, characterized in that the mesh, the nodes of which are foam concrete solid elements, is designed to provide the functions of the lower reinforcing mesh of the ceiling. ! 4. The overlap according to claim 1, characterized in that the reinforcing rods of the mesh structure are rigidly fixed inside the foam concrete solid elements. ! 5. The overlap according to claim 1, characterized in that at the edges of the three-dimensional mesh structure there are additional elements made in the form of full-bodied foam concrete elements with cross-cutting through holes in them for passing through the reinforcement rods of the three-dimensional mesh structure. ! 6. The overlap according to claim 1, characterized in that the grid of the three-dimensional mesh structure is located not higher than half the height of the foam concrete solid element. ! 7. The overlap according to claim 6, characterized in that on the grid of a three-dimensional mesh structure

Description

The utility model relates to the field of construction, in particular to the construction of monolithic and precast monolithic ceilings, preferably monolithic or precast monolithic, mainly frame buildings, including high seismic resistance.

The prior art floor slab of reinforced concrete with a two-dimensional structure (US 5396747, E04B 5/43, 03/14/1995).

The prior art solutions with polymer elements are known, which are not widely used in practice due to disadvantages, which can be attributed to the high cost of polymer hollow elements. The price of polymer hollow elements is 2-3 times higher than the cost of foam concrete, and they also have a great complexity of installation.

The objective of this technical solution is to increase the strength and seismic resistance of the floor of a frame building, increase the technicality of installation work and reduce the cost of construction of a monolithic building as a whole.

The problem is solved due to the fact that the overlap includes a three-dimensional mesh structure of solid foam elements and reinforcing rods, which is monolithic with heavy concrete, and the foam concrete solid elements are interconnected by reinforcing bars intersecting inside them, with the formation of a mesh, the nodes of which are the mentioned foam concrete solid elements, wherein each foam concrete element is preferably made of variable cross-section, and the space between the elements behind olneno concrete to form a rigid honeycomb structure, whose height is preferably equal to the height of foam concrete corpulent elements.

The height of each element can be taken no less than its length and / or width.

The mesh, the nodes of which are foam concrete solid elements, can be performed providing the functions of the lower reinforcing mesh of the floor.

The reinforcing rods of the mesh design can be rigidly fixed inside the foam concrete solid elements.

At the edges of the three-dimensional mesh structure, additional elements made in the form of full-bodied foam concrete elements with cross-cutting through holes in them can be placed for passing reinforcement rods of the three-dimensional mesh structure.

The grid of the three-dimensional mesh structure can be located no higher than half the height of the foam concrete solid element.

Additional reinforcing bars can be laid on the grid of the three-dimensional mesh structure, which together with the reinforcing bars of the three-dimensional mesh structure form the lower reinforcing mesh.

The grid of a three-dimensional mesh structure in terms of metal content can be at least 50% of the total mass of the lower reinforcing mesh.

The overlap may further comprise an upper mesh located between the foam concrete elements.

The upper mesh may be located above half the height of the foam concrete solid element.

The cellular structure can be made of particularly strong concrete.

The cellular structure may be made of crack-resistant concrete or fiber reinforced concrete reinforced with dispersively distributed metal and / or polymer and / or silicate fibers.

The density of the foam concrete elements can be 300-500 kg / m ³ .

Foam concrete with a strength grade from B5 to B7.5 can be used.

As foam concrete can be adopted fiber concrete.

As reinforcing bars, reinforcement of a periodic profile of class A500-A400 can be used.

The foam concrete elements in shape can be made, preferably, with a flat base and decreasing from the lower part of the element to the upper. The foam concrete elements in shape can be made in the form of parallelepipeds, or prisms, or preferably truncated pyramids, cones, ellipsoids, paraboloids, ovoids, spheres.

The foam concrete elements in shape can be made in the form of polyhedra, for example, such as Archimedes bodies, Poinsot bodies, Plato bodies, Fedorov bodies, including truncated ones.

The foam concrete elements in their upper part may preferably contain open intersecting or intersecting channels in which the rods of the upper reinforcing mesh are laid, while the space between the foam concrete elements, as well as the said channels, are filled with heavy concrete.

The overlap can be performed resting on columns whose reinforcement passes through the body of the ceiling, at a distance of 1000-2000 mm. from the reinforcement of the column, the ceiling is made entirely of heavy concrete and contains foam concrete elements only outside these limits, while the distance from the edges of the ceiling to the extreme foam concrete elements is at least 150 mm.

Foam concrete elements can be located in longitudinal and transverse rows.

A three-dimensional mesh structure can be formed by mounting blocks each of which consists of longitudinal and transverse rows of foam concrete elements, preferably twenty-five elements in each block, while the blocks are connected to each other by the end parts of the reinforcing bars by welding or other methods known in the art.

The technical result achieved through the use of this technical solution is to reduce the weight of the floor, increase its scattering power and reduce the impact of seismic loads on the building as a whole due to the use of a three-dimensional mesh structure of solid concrete foam elements of a certain configuration and reinforcing rods in the floor structure while saving metal and heavy concrete, as well as providing the possibility of quick installation of structural structures roofs of various sizes and configurations.

The implementation of a rigid cellular structure, the height of which H, is preferably equal to the height h of the foam concrete solid elements, in contrast to the known ceilings, provides absorption, dispersion and damping of vibrations during seismic loads due to the combined operation of the rigid cellular structure and three-dimensional compliant structure due to increased energy absorption.

The technical solution is illustrated by the following graphic materials, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only particular examples of the utility model, where:

figure 1 is a transverse section of a monolithic overlap along the axes of the columns;

figure 2 is a section along aa in figure 1;

figure 3 is a three-dimensional mesh design of full-bodied foam concrete elements and reinforcing bars, a perspective view;

figure 4 is a separate solid foam element;

figure 5 is a cross section bB in figure 4.

The overlap 1 includes a three-dimensional mesh structure 2 of full-bodied foam concrete elements 3 and reinforcing rods 4, which is monolithic with concrete 5 or reinforced concrete, moreover, the full-concrete foam concrete elements 3 are interconnected by reinforcing bars 4 intersecting inside them, with the formation of a grid 6, the nodes 7 of which are mentioned full-concrete foam elements 3, each foam concrete element 3 is preferably made of variable cross section 8 with decreasing from the lower part 9 to the upper 10 element, at least measure, with one geometrical dimension a of cross section 8, and the space 11 between the elements is filled with solidified monolithic concrete 5 or reinforced concrete with the formation of a rigid cellular structure, the height of which H is preferably equal to the height h of the foam concrete solid elements.

The height h of each element is accepted no less than its length a and / or width b.

The mesh, the nodes of which 7 are foam concrete solid elements 3, also performs the function of the lower reinforcing mesh of the floor.

The reinforcing rods 4 of the mesh structure are rigidly fixed inside the foam concrete solid elements 3 until they are filled with monolithic concrete 5 or reinforced concrete.

The grid of the three-dimensional mesh structure is located not higher than half the height h / 2 of the foam concrete solid element.

The grid is a three-dimensional mesh structure, additional reinforcing rods 12 are laid, which together with the reinforcing rods 4 of the three-dimensional mesh structure form the lower reinforcing mesh of the ceiling.

The grid of a three-dimensional mesh structure in terms of metal consumption is at least 50% of the total mass of the lower reinforcing mesh.

As additional elements, full-bodied foam concrete elements with cross-cutting through holes in them were used to pass reinforcement rods of a three-dimensional mesh structure.

The overlap further comprises an upper mesh 13 located between the foam concrete elements.

In this case, the upper mesh is located above half the height of the foam concrete solid element.

The cellular structure is made of especially durable concrete or reinforced concrete.

The cellular structure is made of crack-resistant concrete and / or fiber-reinforced concrete reinforced with dispersively distributed metal and / or polymer and / or silicate fibers.

The density of the foam concrete elements 300-500 kg \ m ³ .

The strength of the foam concrete elements selected with a strength grade from B5 to B7.5.

As foam concrete adopted fibropenobeton.

Claims (23)

1. Overlap, characterized in that it includes a three-dimensional mesh structure of solid-bodied foam concrete elements and reinforcing rods, which is monolithic with heavy concrete, moreover, foam concrete solid bodies are interconnected by reinforcing bars intersecting inside them, with the formation of a mesh, the nodes of which are said foam concrete solid elements, wherein each foam concrete element is preferably made of variable cross-section, and the space between the elements is filled with concrete m to form a rigid honeycomb structure, whose height is preferably equal to the height of foam concrete corpulent elements. 2. The overlap according to claim 1, characterized in that the height of each element is adopted no less than its length and / or width. 3. The overlap according to claim 1, characterized in that the mesh, the nodes of which are foam concrete solid elements, is designed to provide the functions of the lower reinforcing mesh of the ceiling. 4. The overlap according to claim 1, characterized in that the reinforcing rods of the mesh structure are rigidly fixed inside the foam concrete solid elements. 5. The overlap according to claim 1, characterized in that at the edges of the three-dimensional mesh structure there are additional elements made in the form of full-bodied foam concrete elements with cross-cutting through holes in them for passing through the reinforcement rods of the three-dimensional mesh structure. 6. The overlap according to claim 1, characterized in that the grid of the three-dimensional mesh structure is located not higher than half the height of the foam concrete solid element. 7. The overlap according to claim 6, characterized in that additional reinforcing bars are laid on the grid of the three-dimensional mesh structure, which together with the reinforcing bars of the three-dimensional mesh structure form the lower reinforcing mesh. 8. The overlap according to claim 7, characterized in that the grid of a three-dimensional mesh structure in terms of metal consumption is at least 50% of the total mass of the lower reinforcing mesh. 9. The overlap according to claim 7, characterized in that it further comprises an upper mesh located between the foam concrete elements. 10. The overlap according to claim 9, characterized in that the upper mesh is located above half the height of the foam concrete solid element. 11. The overlap according to claim 1, characterized in that the cellular structure is made of especially durable concrete. 12. The overlap according to claim 1, characterized in that the cellular structure is made of crack-resistant concrete or fiber reinforced concrete reinforced with dispersed metal and / or polymer and / or silicate fibers. 13. The overlap according to claim 1, characterized in that the density of the foam concrete elements 300-500 kg / m ³ . 14. The overlap according to claim 1, characterized in that the foam concrete with a strength grade from B5 to B7.5 is used. 15. The overlap according to claim 1, characterized in that the foam concrete adopted fibropenobeton. 16. The overlap according to claim 1, characterized in that as the reinforcing bars used reinforcement of the periodic profile of class A500-A400. 17. The overlap according to claim 1, characterized in that the foam concrete elements in shape are preferably made with a flat base and decreasing from the bottom of the element to the top. 18. The overlap according to claim 1, characterized in that the foam concrete elements in shape are made in the form of parallelepipeds, or prisms, or preferably truncated pyramids, cones, ellipsoids, paraboloids, ovoids, spheres. 19. The overlap according to claim 1, characterized in that the foam concrete elements in shape are made in the form of polyhedra, for example, such as bodies of Archimedes, Poinsot bodies, Plato bodies, Fedorov bodies, including truncated ones. 20. The overlap according to claim 1, characterized in that the foam concrete elements in their upper part preferably comprise open intersecting or intersecting channels in which the rods of the upper reinforcing mesh are laid, while the space between the foam concrete elements, as well as the said channels, are poured with heavy concrete. 21. The overlap according to claim 1, characterized in that the overlap is based on columns whose reinforcement passes through the body of the overlap, while at a distance of 1000-2000 mm from the reinforcement of the column, the overlap is made entirely of heavy concrete and contains foam concrete elements only outside these limits while the distance from the edges of the overlap to the extreme foam concrete elements is at least 150 mm. 22. The overlap according to claim 1, characterized in that the foam concrete elements are located in longitudinal and transverse rows. 23. The overlap according to claim 1, characterized in that the three-dimensional mesh structure is formed by mounting blocks, each of which consists of longitudinal and transverse rows of foam concrete elements, preferably twenty-five elements in each block, while the blocks are interconnected by the end parts of the reinforcement rods by welding or other methods known in the art.