RU190913U1 - STEEL CONCRETE BEAM - Google Patents

Abstract

The utility model relates to the field of construction and can be used as floor joists of residential and public buildings. The utility model is aimed at increasing manufacturability, reducing labor-intensive manufacturing and material consumption, as well as increasing the bearing capacity, improving the reliability of the steel-reinforced concrete beam. Steel-reinforced concrete beam includes steel thin-walled zytoobrazny profile, in which the reefs are stamped with at least two rows with variable pitch, decreasing to the supports, and in the walls of the stamps The studs on which the reinforcing bars are placed, to increase the bearing capacity, the upper cavity of the zyo-shaped profile is filled with concrete with increased compressive strength, and the lower cavity with concrete with increased tensile strength, for example, polymer concrete or fiber-reinforced concrete. labor-intensive, provides a reduction of material consumption, increases the overall carrying capacity of the beam and the reliability of its work.

Description

The utility model relates to the field of construction and can be used as floor beams of residential and public buildings.

A steel concrete beam is known, including a steel I-beam profile with stud-bolts and cementing welded to the profile walls (see Eurocode 4 “Design of composite concrete structures”, part 1-1, Minsk, 2010, p. 25, table 5.2).

The disadvantages of steel concrete beams are: high consumption of materials due to the rolling profile and the complexity of manufacturing steel concrete beams. First you need to weld stud bolts to the walls, then concreting the side cavities.

The steel-concrete beam is known, containing a monolithing concrete and a steel I-beam having anchor elements welded to the wall of the I-beam along the line of sagging of flexible reinforcing bars [see patent for utility model No. 155972].

The disadvantages of this steel beam are the laboriousness of welding anchor rods to the wall and the reduced bearing capacity of the steel concrete beam due to the possible premature loss of stability of the wall of a thin-walled profile.

The closest is a steel concrete beam containing a monolithing concrete and a steel solid or composite I-beam of two “C” shaped profiles, having anchor elements in the form of studs transversely across the wall [see patent for utility model No. 155973 Е04С 3/293 of December 23, 2014].

The disadvantages of this steel concrete beam are the reduced carrying capacity of the steel concrete beam due to the possible premature loss of stability of the wall of a thin-walled profile, due to weakening of the wall by stamped pins.

The utility model is aimed at improving manufacturability and reducing the complexity of manufacturing, increasing the overall bearing capacity and reliability of the composite steel beam.

The result is achieved in that in the steel concrete beam, which includes a thin-walled steel profile, monolithing concrete and reinforcing rods of the utility model, the thin-walled profile is adopted in a zeta-shaped section, in which the riffs and walls are stamped in at least two rows with variable pitch, decreasing to the supports.

The result is also achieved by the fact that, according to the utility model, studs are stamped into the inside walls of the section, at the ends of which reinforcing bars are placed.

The result is also achieved by the fact that the upper cavity of the zet-shaped profile is filled with heavy concrete, and the lower one with increased design tensile strength, for example, fiber concrete or polymer concrete.

FIG. 1 depicts an aggregate reinforced concrete beam consisting of a thin-walled zet-shaped profile with reefs and studs that are also supports for reinforcing bars.

FIG. 2 depicts a composite beam in section A-A, consisting of a thin-walled z-shaped profile with reefs, studs and reinforcing bars with cavities filled with concrete with different strength characteristics.

Reinforced concrete beam includes thin-walled steel zetoobrazny profile 1, monolithing concrete 2 and 3. To ensure the joint operation of steel thin-walled profile 1 and adhesion with concrete in the shelves and in the walls, reefs 4 with steps a ₁ , a ₂ , a ₃ , etc. were stamped with a decrease to the supports beams and studs 5 inside the wall. At the ends of the studs 5 are rebar 6. The upper profile cavity is filled with concrete 3, the lower cavity is filled with concrete 2.

The manufacture of the composite beam is performed in the following sequence.

In the factory, they first make a zyo-shaped profile 1 with reefs 4, studs 5, then rebar 6 are installed on the holes of studs 5.

After the preparatory procedures, the monolithing of 2 side cavities of the thin-walled profile with concrete is carried out. After acquiring the strength of concrete 2, turn the profile on the other side and put in the concrete 3.

A composite beam made in such a sequence increases the strength of the steel profile, provides good adhesion of the composite I-beam across the entire contact surface with concrete and decreases material consumption, increases the overall bearing capacity due to different concrete and reliability of the beam.

Claims (3)

1. Steel concrete beam, comprising a thin-walled steel profile, filling concrete, reinforcing bars, characterized in that the thin-walled profile is adopted with a zenith section, in which reefs in the walls and shelves are stamped at least in two rows with variable pitch, decreasing towards the supports. 2. Steel concrete beam according to claim. 1, characterized in that studs with “holes” are stamped into the profile inside walls, at the ends of which reinforcement bars are placed. 3. Steel concrete beam according to claim. 1, characterized in that the upper cavity of the zyo-shaped profile is filled with heavy concrete with increased design compressive resistance, and the lower cavity with concrete with increased design tensile resistance.

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