RU201193U1 - STEEL CONCRETE INSULATION FLOORING - Google Patents

Abstract

The utility model relates to the field of construction, namely to the structures of steel-concrete floors. The technical result of the utility model is to increase the load-bearing capacity of the floor, which is achieved due to the fact that a steel-concrete insulating floor containing vertically installed trusses made of a metal profile, a lower insulating layer and a filler mounted between the trusses, characterized in that the trusses contain, as at least one upper and lower chord, interconnected by vertical posts and diagonal braces, while along the length of the profile of the truss elements in its walls, recesses are made to ensure rigidity and increase the stability of the profile, a screed is made on top of the filler, consisting of at least two layers, between the layers of the screed, a reinforcing layer is mounted with the possibility of taking tensile stresses and strengthening in the compressed overlap zone. 19 p.p. f-ly, 2 dwg

Description

The utility model relates to the field of construction, namely to steel concrete floor structures [E04B 5/00].

From the prior art, a THERMAL INSULATING INTEGRATED MULTI-LAYER COVERING PLATE [CN207794400 (U), publ .: 08/31/2018] is known, comprising: a concrete layer and a layer of thermal insulation material provided above the concrete layer, and a monolithic concrete layer poured onto the layer of thermal insulation material, a concrete layer and the monolithic concrete layer are interconnected by reinforcement, the concrete layer is sealed with the transverse bottom reinforcement of the slab and the longitudinal lower reinforcement of the slab, and the monolithic concrete layer is preset with negative reinforcement of the transverse slab support and negative longitudinal support of the slab, the lower end of the reinforcing girder is connected to the transverse lower reinforcement of the slab or the longitudinal lower reinforcement of the slab, the top of the truss reinforcement is connected to the negative reinforcement of the transverse support of the slab or the negative reinforcement of the longitudinal slab, the heat-insulating material is made in the form of blocks on the concrete layer, the lower ends of the steel bars are connected and fixed to the transverse lower With plate reinforcement or longitudinal lower plate reinforcement, the upper truss element is associated with negative reinforcement of the transverse plate support or negative reinforcement of the longitudinal plate support, the edge of the layer of insulating material described above is 3-8 mm wide and inserted into the precast concrete layer in the form of a hypotenuse.

The disadvantage of the analogue is the low strength of the described floor slab, due to the implementation of the supporting metal structure in the form of unbound reinforcement.

Also known DEVICE AND METHOD FOR CONSTRUCTION FROM COMPOSITE CONCRETE AND STEEL FLOOR [US2005235590 (A1), publ .: 27.10.2005], consisting of: cast concrete slab; a plurality of separate laterally disposed parallel and supported beams, each of said plurality of beams comprising an upper chord and a lower chord connected by an intermediate web element, wherein at least a portion of said upper chord is embedded in a concrete slab; and wherein at least one of said upper chords of one of said plurality of beams comprises a substantially transverse cross-section about a longitudinal axis of said one of said upper chords.

The disadvantage of the analogue is poor sound insulation, due to the small thickness of the concrete slab and the small value of the withstand load on the surface of the structure.

The closest in technical essence is the STEEL CONCRETE FLOOR [RU112227 (U1), publ .: 01.01.2012], containing vertically installed steel trusses made of elements of the C-shaped cold-formed profile made of steel sheet with a thickness of 0.5 to 3.0 mm, a panel made of sheet material is remotely attached to the lower part of the trusses, and the space between the trusses, between the trusses and the panel is filled with a frozen foam concrete mixture.

The main technical problem of the prototype is the low strength and low load-bearing capacity of the floor.

The task of the utility model is to eliminate the shortcomings of the prototype.

The technical result of the utility model is to increase the bearing capacity of the floor.

The specified technical result is achieved due to the fact that a steel-concrete insulating floor containing vertically installed trusses made of a metal profile, a lower insulating layer and a filler mounted between the trusses, characterized in that the trusses contain at least one upper and lower chord, interconnected by vertical posts and diagonal braces, while along the length of the profile of the truss elements, recesses are made in its walls to ensure rigidity and increase the stability of the profile, a screed is made on top of the filler, consisting of at least two layers, a reinforcing layer is mounted between the screed layers with the ability to perceive tensile stresses and reinforcement in the compressed overlap zone.

In particular, the trusses are made of cold-formed profiles with a thickness of 0.5 to 3.0 mm.

In particular, the trusses are covered with a polymer coating.

In particular, the trusses are made with a width of 50 to 200 mm.

In particular, the trusses are made with a height of 100 to 1000 mm.

In particular, the truss elements are interconnected by a detachable connection at least in two places.

In particular, the trusses are installed in parallel.

In particular, the trusses are interconnected by transverse beams.

In particular, the number of chords of trusses is set depending on the magnitude of the load.

In particular, the lower insulating layer is in the form of a panel of sheet material.

In particular, the filler is made in the form of a fast-setting solution with a density of at least 150 kg / m ³ .

In particular, the upper level of the filler is not lower than the level of the upper chords of the trusses.

In particular, the filler is made in the form of a mineral fiber with a density of at least 10 kg / m ³ .

In particular, on farms with the ability to distribute the load and increase the load-bearing capacity of the floor, an unloading plate is mounted.

In particular, the discharge plate is in the form of a metal sheet.

In particular, the discharge plate is made in the form of a galvanized profiled sheet.

In particular, a damping layer is mounted between the discharge plate and the upper chord of the trusses.

In particular, the screed is made of a fast-setting mortar with a density of at least 600 kg / m ³ .

In particular, the reinforcing layer is made in the form of a mesh of metal reinforcement.

In particular, the reinforcing layer is in the form of a composite mesh.

Brief description of the drawings.

FIG. 1 shows a general view of a steel concrete insulating floor in a floor embodiment.

FIG. 2 shows a general view of a steel-concrete insulating floor in an interfloor embodiment.

The figures indicate: 1 - lower chords, 2 - upper chords, 3 - struts, 4 - braces, 5 - insulating layer, 6 - filler, 7 - screed, 8 - reinforcing layer, 9 - damper tape, 10 - bearing coating, 11 - perforations.

Implementation of the utility model.

A reinforced concrete insulating floor consists of at least a pair of vertically installed parallel rows of trusses made of thin-walled cold-formed U- or C-shaped profiles, for example, from galvanized steel with a thickness of 0.5 to 3.0 mm. Recesses are made along the profile in its walls (not shown in the figures) to provide rigidity and increase the stability of the profile. Each of the trusses contains at least one lower 1 and one upper 2 chords (see Fig. 1), connected at the edges by vertical posts 3, and along the chord 1 and 2 are interconnected by diagonal braces 4. Braces 4 and posts 3 are connected with chords 1 and 2 a detachable connection made at least at two points, for example, riveted and screwed, or double riveted, or double screwed, etc. connections. With an increase in the planned load on the floor, the number of interconnected lower 1 and upper 2 belts increases.

An insulating layer 5 is mounted to the lower chords 1 of the trusses, made in the form of a sheet material, for example, from a gypsum board, a cement-bonded particle board, a magnesia glass sheet or a cement board, a metal sheet, etc.

In an embodiment, as a floor covering, the space between the trusses is filled with filler 6, made in the form of a fast-hardening solution with a density of at least 150 kg / m ³ , for example, in the form of foam concrete, expanded polystyrene concrete, gypsum concrete, etc., while the upper level of filler 6 is made higher the level of the upper belts of 2 trusses. A screed 7 is made on top of the filler 6, containing at least two layers made of, for example, foam concrete, expanded polystyrene concrete, gypsum concrete, etc. Between the layers of the screed 7 is mounted a reinforcing layer 8 made in the form of a mesh of steel or composite reinforcement.

In an embodiment as an interfloor overlap (see Fig. 2), the space between the trusses is filled with mineral fiber filler 6 with a density of at least 10 kg / m ³ , for example, in the form of basalt fiber, ecowool, penoizol, polyurethane foam, etc. with the ability to provide heat and sound insulation of the floor. On the surface of the upper chords 2 of the trusses, a damper tape 9 is mounted with the possibility of providing thermal insulation and reducing heat loss. On top of the upper chords 2 of the trusses, directly onto the damper tape 9 with the possibility of distributing the load and increasing the load-bearing capacity of the floor, a load-bearing coating 10 provided with stiffening ribs, made in the form of, for example, a galvanized profiled sheet, is mounted. A screed 7 is mounted on top of the load-bearing coating 10, containing at least two layers made, for example, of foam concrete, expanded polystyrene concrete, gypsum concrete, etc. Between the layers of the screed 7 is mounted a reinforcing layer 8 made in the form of a mesh of steel or composite reinforcement.

Reinforced concrete insulating floor is assembled as follows.

For the equipment of a steel concrete insulating floor as a floor covering, the site is initially prepared by leveling and filling it, for example, with crushed stone. With the possibility of providing vapor and waterproofing, the surface of the site is covered with a hydro and / or vapor barrier layer (not shown in the figures) in the form of a roll material.

The assembled trusses are vertically installed with the lower chords 1 parallel to each other at a distance from each other, while an insulating layer 5 of sheet material is pre-assembled to the lower part of the trusses to the lower chords 1.

For the equipment of a steel-concrete insulating floor as an interfloor floor, pre-assembled trusses are installed vertically on load-bearing walls or mounted to the walls through fasteners in parallel at a distance from each other.

The space between the trusses is filled with filler 6, made in the form of a rapidly solidifying solution, while the filler 6 is performed above the level of the upper chords 2 of the trusses.

On top of the filler 6, the first layer of the screed 7 is poured, the reinforcing layer 8 of steel or composite reinforcement is laid and the second layer of the screed 7 is poured.

The space between the trusses is filled with filler 6 made in the form of mineral fibers.

A damper tape 9 is mounted to the surfaces of the profiles of the upper chords. 9. A supporting coating is placed on top of the damper tape 9. The first layer of screed 7 is poured on top of the supporting coating 10, a reinforcing layer 8 of steel or composite reinforcement is laid and the second layer of screed 7 is poured.

EFFECT: increased load-bearing capacity of the floor is achieved due to

performing a steel-concrete insulating floor from parallel rows of vertically mounted trusses, the upper 1 and lower 2 chords of which are interconnected by vertical posts 3 and diagonal braces 4, while the elements of the trusses are made of a metal profile with grooves made along the entire length in the walls of the profile, providing rigidity and increasing the stability of the profiles, and the connection of the truss elements to each other is made by a double detachable connection. The space between the trusses is filled with filler 6, made in the form of a rapidly hardening solution or mineral fiber, a screed 7 is mounted on top of the filler 6, made of at least two layers with a reinforcing layer 8 laid between the said layers in the form of a mesh of metal reinforcement or composite material, In this case, in the embodiment of the filler 6 in the form of a mineral fiber, a bearing coating 10 is mounted on top of the trusses, an insulating layer 5 of sheet material is mounted in the lower part of the trusses to the lower chords 1, in aggregate, ensuring uniform load distribution and an increase in the bearing capacity of the floor.

Claims (20)

1. Reinforced concrete insulating floor containing vertically installed trusses made of a metal profile, a lower insulating layer and a filler, mounted between the trusses, characterized in that the trusses contain at least one upper and lower chord, interconnected by vertical posts and diagonal braces, while along the length of the profile of the truss elements in its walls, recesses are made to ensure rigidity and increase the stability of the profile, a screed is made on top of the filler, consisting of at least two layers, a reinforcing layer is mounted between the screed layers with the ability to perceive tensile stresses and strengthen in compressed overlap area. 2. Overlap according to claim 1, characterized in that the trusses are made of cold-formed profiles with a thickness of 0.5 to 3.0 mm. 3. Overlapping according to claim 1, characterized in that the trusses are covered with a polymer coating. 4. The overlap according to claim 1, characterized in that the trusses are made with a width of 50 to 200 mm. 5. Overlapping according to claim 1, characterized in that the trusses are made with a height of 100 to 1000 mm. 6. Overlap according to claim 1, characterized in that the elements of the trusses are interconnected by a detachable connection, at least in two places. 7. Overlapping according to claim 1, characterized in that the trusses are installed in parallel. 8. The overlap of claim. 1, characterized in that the trusses are interconnected by transverse beams. 9. Overlap according to claim 1, characterized in that the number of truss belts is set depending on the size of the load. 10. The overlap of claim. 1, characterized in that the lower insulating layer is made in the form of a panel of sheet material. 11. The overlap of claim. 1, characterized in that the filler is made in the form of a fast-hardening solution with a density of at least 150 kg / m ³ . 12. The overlap of claim. 1, characterized in that the upper level of the filler is made not lower than the level of the upper chords of the trusses. 13. Overlapping according to claim 1, characterized in that the filler is made in the form of a mineral fiber with a density of at least 10 kg / m ³ . 14. The overlap according to claim 1, characterized in that the unloading plate is mounted on the farms with the ability to distribute the load and increase the bearing capacity of the floor. 15. The overlap of claim. 14, characterized in that the unloading plate is made in the form of a metal sheet. 16. The overlap of claim. 14, characterized in that the unloading plate is made in the form of a galvanized profiled sheet. 17. Overlap according to claim 14, characterized in that a damping layer is mounted between the unloading plate and the upper chord of the trusses. 18. Overlapping according to claim 1, characterized in that the screed is made of a fast-hardening mortar with a density of at least 600 kg / m ³ . 19. The overlap of claim. 1, characterized in that the reinforcing layer is made in the form of a mesh of metal reinforcement. 20. The overlap of claim. 1, characterized in that the reinforcing layer is made in the form of a mesh of composite material.

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