RU169617U1 - STEEL CONCRETE COMPOSITION BEAM - Google Patents

Abstract

The utility model relates to the field of construction and can be used as floor beams of residential and public buildings. A useful model is aimed at increasing the strength of the steel profile wall in the concrete body, at reducing the complexity of manufacturing and material consumption, as well as at increasing the strength and reliability of the steel-concrete beam. The steel-concrete composite beam includes a steel thin-walled profile of an integral I-section or a composite I-beam, paired from two C-shaped bent profiles, concrete is monolithic shafts and flexible reinforcing bars, the studs are stamped alternately in both sides in two or more rows from the wall of the thin-walled profile, stamped with different steps, decreasing to the supports, while the studs are stamped perpendicular to the wall, along the line of sagging of the flexible reinforcing bars and in the descending direction inclined to the longitudinal axis of the profile from both its ends. To reinforce the load before concreting the side cavities of the steel profile, flexible reinforcing bars are placed at the ends of the beams of the upper row of studs and in the middle of the beam in the lower zone. the bearing 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 with U-shaped clamps welded to the walls of the profile with longitudinal rods missing under the U-shaped clamps (see Eurocode 4 "Design of steel-reinforced concrete structures", part 1-1, Minsk, 2010, p. 34, Fig. 6.10 (3)).

The disadvantages of steel-concrete beams are: high material consumption and the complexity of manufacturing a steel-concrete beam with a reinforcing cage. First you need to make a frame consisting of clamps and longitudinal rods, then weld the clamps to the walls, only then you can concreting the side cavities.

Known steel-concrete beam containing monolithic concrete and a steel I-beam having anchor elements welded to the wall of the I-beam along the sagging line of flexible reinforcing rods [see Utility Model Patent No. 155972].

The disadvantages of this steel-concrete beam are the complexity of welding the anchor rods to the wall and the reduced load-bearing capacity of the steel-concrete beam due to the possible premature loss of stability of the wall of a thin-walled profile, due to the absence or unfulfillment of additional structural measures in the wall of the maximum replicating forces (type of loss of wall stability see "Metal structures" under the editorship of Yu.I. Kudishin, M. - 2011, Fig. 7.17 and 7.18, pp. 200-201).

The closest is a steel-concrete beam containing monolithic concrete and a steel one-piece or composite I-beam, having anchor elements in the form of studs stamped across the wall of the studs along a downward inclined profile to the longitudinal axis from both ends of the I-beam [see Utility Model Patent No. 155973 E04c 3/293 dated 12/23/2014].

The disadvantages of this steel-concrete beam are the reduced bearing capacity of the steel-concrete beam due to the location of the flexible reinforcement far from the zone of appearance of inclined cracks and the possible premature loss of stability of the wall of the thin-walled profile, due to the non-oriented weakening of the wall by the studded studs. The attenuation bands are not located along the envelope of the beam moment diagram. There is no reinforcement in the zone of possible occurrence of inclined cracks (see the scheme of fracture of bent elements along an inclined section, Prince of Reinforced Concrete and Stone Structures. Authors: V. M. Bondarenko, PO Bakirov, V. G. Nazarenko, V. I. Rimshin. - M., Higher School, 2002, p. 280, Fig. 97; p. 263, Fig. 91; p. 257, Fig. 89).

The utility model is aimed at increasing the stability of the wall of a thin-walled profile, increasing the overall bearing capacity and reliability of a composite steel-concrete beam.

The result is achieved in that in a steel-concrete beam, including a steel thin-walled profile of an integral I-section or a composite I-beam, paired from two bent profiles of a C-shaped section, having anchor stamped studs with bends at the ends, located along the beam alternately on both sides of the wall in two and more than a row, with a step decreasing to the supports and concrete monolithic, according to the utility model, the stamping of the studs in the wall is performed along the envelope of the diagram of the bending moments and downward inclined to the prod Flax-axis profile.

The result is also achieved by the fact that the wall is stamped in descending order: from the left end from left to right, and from the right end from right to left.

The result is also achieved by the fact that the rows of studs are stamped perpendicular to the wall and bent upward in the support zone and downward in the span zone, and rods of flexible reinforcement are placed at the ends of the studs along the envelope of the bending moment diagram.

In FIG. 1 shows a steel-concrete beam consisting of a thin-walled profile of an I-section with anchor elements from stamped studs.

In FIG. 2 shows a steel-concrete beam in a section 1-1, consisting of two thin-walled profiles of a C-shaped section. In FIG. 3 shows a steel-concrete beam in a section 2-2, consisting of a solid I-beam.

The steel-concrete composite beam includes a thin-walled steel profile 1 and monolithic concrete 2. To ensure concrete adhesion and joint work with the steel thin-walled profile at the left and right ends of the profile along the line of the envelope of the moment diagram, studs 3 are stamped on both sides of the wall into two or more right angles row, in increments of a ₁ , a ₂ , a ₃ , etc. with a decrease in the beam supports. Anchor elements in the form of stamped pins 3 are made with bends at the ends. The steel part of the steel-concrete beam can be made of two thin-walled profiles of C-shaped section (section 1-1). C-shaped profiles are fastened together using the same studs 5. At the ends of the anchor elements 3 stamped from the wall, rods 4 of flexible reinforcement are placed.

The manufacture of steel-concrete composite beams is performed in the following sequence.

In the factory, first stamping the studs 3 from the wall of the thin-walled profile along the downward sloping from the left and right ends. If necessary, the studs 3 are performed with a bend. On the studs in the upper zone of the beam at the support and below in the span, flexible longitudinal rods 4 are placed along the line of their sagging. When stamping the studs 3, their pitch is reduced to the supports. When performing an I-section from two C-shaped profiles, they are fastened together using studs 5.

After preparatory procedures, the concrete cavities are monolithic in the lateral cavities of the entire (Fig. 3) thin-walled profile or composite (Fig. 2) I-beam from two C-shaped profiles.

The assembled steel-concrete beam increases the stability of the wall and the strength of the steel profile, provides a decrease in the total material consumption of steel on the beam, increases the overall bearing capacity and reliability of the beam.

Claims (3)

1. Steel-concrete composite beam, including concrete filling, flexible reinforcing bars, steel thin-walled profiles, forming an I-section, having anchor elements in the form of studs stamped in the wall with bends located alternately on both sides of the beam wall, characterized in that the stamping of the studs in the wall profile is made in at least two rows along the sagging line of longitudinal flexible reinforcing bars. 2. Steel-concrete composite beam according to claim 1, characterized in that the studs are stamped perpendicular to the wall and obliquely downward from the longitudinal axis of the profile from both ends. 3. Steel-concrete composite beam according to claim 1, characterized in that at the ends of adjacent rows of studs in the upper zone on the beam support, and in the span - in the lower zone of the beam, flexible reinforcing bars are placed along the line of their sagging.

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