RU197858U1 - OVERLAPPING BASED ON LIGHT STEEL CONCRETE STRUCTURES - Google Patents

Abstract

The utility model relates to construction, in particular to the construction of concrete floors. Essence: the overlap contains paired C-profiles located mirror-relative to each other, connected by vertical walls and installed vertically with a calculated step, forming floor beams. On the beams, on the one hand, corrugated board, working reinforcement and anti-shrink mesh, poured with monolithic concrete, are successively installed, and on the other hand, omega profiles installed with a calculated pitch and to which sheet material is attached. Decking is laid in the longitudinal plane of the overlap over its entire area, working fittings are laid in each cavity of the sheeting, and anti-shrink mesh is laid on each edge of the sheeting. The cavity between the corrugated board and the sheet material is filled with foam concrete. The surface of the cast concrete is leveled with a screed. The technical result is the creation of a horizontal hard disk that provides redistribution of loads and internal stresses in the ceiling structure, which allows to increase its strength characteristics. In addition, the claimed design of the floor allows you to reduce its metal consumption and eliminate the formation of the effect of "cold bridges" in the basement and attic floors. 2 s.p. f-ly, 4 ill.

Description

The utility model relates to construction, in particular to structures of steel-concrete floors.

A steel-concrete overlap is known, containing paired C-profiles located mirror-wise relative to each other and installed vertically with a calculated step, on which sheet material is mounted on one side and distance profiles to which sheet material is attached, the cavities between the sheet materials are filled with foam concrete moreover, paired C-profiles are interconnected by beams made of C-profile (see US Pat. RF No. 112227, EV 5/00).

A disadvantage of the known overlap is that the foam concrete mixture with a density of the order of 100-300 kg / m ³ filling the internal girder does not have sufficient rigidity, excluding the deflection of the upper layer of foam concrete with a higher density of 300-1500 kg / m ³ , which leads to cracks in the upper layer of foam concrete and its destruction together with the deformable lower layer. In addition, the use of truss floor beams leads to an increase in the total metal consumption of the structure, weight and thickness of the floor itself. And the excessive thickness of the ceiling leads to the need to fill its internal space with a large amount of foam concrete mixture.

The closest analogue to the claimed utility model is a steel-concrete slab containing paired C-profiles that are mirrored relative to each other and installed horizontally with a calculated step, on which, on the one hand, a sequentially bent profile and a flat reinforcing element are poured with concrete, and on the other - distance profiles to which the sheet material is attached, and the cavity between the bent profile and the sheet material is filled with foam concrete (see US Pat. RF No. 163026, EV 5/00).

The disadvantage of this overlap is the heterogeneity of its design, including heterogeneous compartments filled with materials with different mechanical and thermal characteristics. This does not allow to provide uniform thermotechnical properties of the floor, and structural reinforced concrete, perceiving the load, does not ensure the integrity and absence of destruction of insulating materials. If this floor is used as a basement and attic, the compartments filled with heavy reinforced concrete will contribute to the through freezing of the structure, the appearance of cold bridges and the accumulation of moisture inside the ceiling.

The technical problem of the known solutions is the low structural strength of the floors, due to the violation of its integrity under the action of loads.

The essence of the claimed utility model lies in the fact that the overlap contains paired C-profiles that are mirrored relative to each other, which are connected by vertical walls and installed vertically with a calculated step, forming floor beams. On the beams, on the one hand, a bent profile and a reinforcing element are cast in series, which are cast in with concrete, and on the other hand, distance profiles to which the sheet material is attached. A bent profile is a corrugated board laid in the longitudinal plane of the overlap over its entire area, the reinforcing element is made in the form of working reinforcement laid in each cavity of the corrugated board, and an anti-shrink mesh laid on each edge of the corrugated board. The cavity between the corrugated board and the sheet material is filled with foam concrete. Remote profiles made in the form of omega profiles are installed with a calculated step. The concrete surface is leveled with a screed.

The technical result provided by the claimed utility model is to create a horizontal hard disk that provides redistribution of loads and internal stresses in the ceiling structure, which improves its strength characteristics. In addition, the claimed design of the floor allows you to reduce its metal consumption and eliminate the formation of the effect of "cold bridges" in the basement and attic floors.

The essence of the claimed utility model is illustrated by drawings, where:

- in FIG. 1 schematically depicts the claimed overlap, a top view;

- in FIG. 2, section AA in FIG. 1;

- in FIG. 3 section BB in FIG. 1;

- in FIG. 4 schematically depicts the claimed overlap in isometry.

The overlap contains composite beams 1 of paired galvanized thin-walled C-profiles connected by vertical walls by means of self-tapping screws 2 installed with a design pitch. The optimal use of the characteristics of the cross section of paired C-profiles allows minimizing the metal consumption of the overlap, and, despite the small thickness of their walls, in the total cross-sectional area, galvanized C-profiles are not inferior to the traditionally used steel counterparts, but they significantly exceed the cross-sectional height subject to equal cross-sectional areas , which affects the decrease in the value of the total deflection of the floor. To the upper shelves of the composite LSTC-beam 1, corrugated board 3 from a bent galvanized profile is attached. The fastening is made by self-tapping screws 2 in each cavity of the corrugated board 3 in pairs with a step equal to the spacing of the beams 1 on the floor. The direction of the waves of profile 3 is perpendicular to the direction of the composite LSTC-beams 1. Profile sheet 3 eliminates the transfer of loads from the surface of the floor to the inner filling and prevents its mechanical destruction. A thin-walled galvanized omega-profile 4 is fastened to the lower shelves of the composite LSTK-beam 1 in the assembly in the direction perpendicular to the beam 1 with a design step by four self-tapping screws 2 to ensure reliable fastening to it of a fixed formwork made in the form of a sheet of facing material 5. Fastening of a sheet material 5 is made by self-tapping screws 2. The internal cavities between the corrugated board 3 and the sheet material 5, separated by beams 1, are filled with foam concrete 6. The omega-profile 4 placed inside the foam concrete layer 6 eliminates the effect of “cold bridges” and prevents it from freezing through steel elements in case of use as an attic and basement. In addition, the omega-profile 4 together with the C-profile creates a spatial core of rigidity and significantly strengthens the structure under the action of bending moment. The internal filling of the ceiling, depending on its density, performs heat-insulating and sound-proofing functions and, in addition, foam concrete, despite its low strength properties, has a positive effect on the operation of the ceilings, participating in the redistribution of stresses, prevents completely or partially local stressed effects in profile sheet 3 such as local loss of stability, deplanation, crushing (based on practical laboratory tests at LLC Venture - Scientific Research 02/2018). The surface of the corrugated board 3, on which the working reinforcement 7 and the anti-shrink mesh 8 are laid, is poured with monolithic concrete 9, the surface of which is leveled with screed 10. The reinforced concrete monolithic coating 9 increases the rigidity of the structure, creating a horizontal hard drive and evenly distributing the load on the ceiling. At the same time, the monolithic concrete 9 takes part of the loads independently, transferring forces not to the paired load-bearing beams 1 from the C-profile, but directly to the load-bearing walls or through the load-bearing beams 1 to the load-bearing walls with a smaller shoulder, significantly reducing bending moments in the structure. Thus, it allows to increase the strength of the overlap.

The manufacture of the claimed design of the floor is as follows.

The floor beams 1 are made of two steel galvanized C-profiles, which are connected by vertical walls in mirror image using self-tapping screws 2 with a design pitch for reliable fastening and to prevent displacement relative to each other under the action of loads. The step of the beams 1 and their number in the overlap is determined by calculation based on the characteristics of the cross section of the C-profile, affecting its stiffness and strength. On the upper shelves of the beams 1, lay the corrugated board 3 from a bent galvanized profile and fasten using self-tapping screws 2 in each cavity of the corrugated board 3 in pairs with a step equal to the step of the supporting beams 1. To the lower shelves of the composite LSTC-beam 1 in the unit, perpendicular to the beam 1 the direction is fastened with four self-tapping screws 2 with a calculated step, a thin-walled galvanized omega-profile 4 for reliable fastening to it of a fixed formwork made in the form of sheet cladding material 5. Fastening of the sheet material 5 is carried out with a self-tapping screw 2. Then, using plasma or gas cutting, they are cut into corrugated board 3 of pouring-outlet holes 11 in each section formed and limited by beams 1, corrugated board 3 and sheet material 5. Through the filler-outlet holes 11, foam concrete 6 is poured into each section sequentially, as well as air outlet when filling. The thickness and volume of filling the inner cavity of the floor with foam concrete 6 depends on the results of the heat engineering and sound insulation calculation. Next, fill-in and outlets 11 are closed with thin-walled steel plates (not shown in Fig.) With fastening with self-tapping screws and the working reinforcement 7 is laid in each cavity of the corrugated board 3. The working reinforcement 7 is laid on special stops (chairs) (not shown in Fig. ), providing subsequently the presence of a protective layer of reinforcement 7 in the concrete slab 9. Similarly to the working reinforcement 7, stops (not shown) are installed on each edge of the corrugated board 3 for laying anti-shrink mesh 8, which prevents the shrinkage of monolithic concrete 9 when it hardens and builds strength after pouring. At the end of these measures, cast monolithic concrete 9 is poured onto the surface of corrugated board 3 with appropriate measures for the care of concrete during hardening and curing. If necessary, a formwork (not shown in the figure) is preliminarily installed along the perimeter of the floor, preventing concrete 9 from escaping the floor during pouring, and the floor is also broken into grips. The breaking of the floor into the grips is carried out in the case of reinforced concrete flooring according to profiled sheeting 3 of a large area, based on a special calculation taking into account the structure of expansion and temperature joints. Alignment of the surface of the reinforced concrete slab according to the corrugated board 3 after the concrete has set strength 9 is carried out with a screed 10 for the purpose of the subsequent installation of the finishing floor.

Thus, the claimed design of the floor allows you to increase its strength by increasing the rigidity of the structure by creating a horizontal hard drive that provides a uniform distribution of loads and internal stresses in the floor. In addition, the proposed floor has a low metal consumption and eliminates the accumulation of moisture in the construction of basement and attic floors.

Claims (3)

1. Overlap containing paired C-profiles located mirror-relative to each other and installed with a calculated step, on which, on the one hand, a sequentially bent profile and a reinforcing element are installed, poured with concrete, and on the other, distance profiles to which the sheet material is attached, moreover, the cavity between the bent profile and the sheet material is filled with foam concrete, characterized in that the paired C-profiles are installed vertically and connected by vertical walls, the bent profile is a corrugated board laid in the longitudinal plane of the ceiling over its entire area, the reinforcing element is made in the form of working reinforcement, laid in each cavity of the corrugated board, and anti-shrink mesh laid on each edge of the corrugated board. 2. The overlap according to claim 1, characterized in that the distance profiles made in the form of omega profiles are installed with a calculated step. 3. Overlap under item 1 or 2, characterized in that the concrete surface is leveled with a screed.

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