RU199482U1 - STEEL-REINFORCED CONCRETE RIBBED FLOORING - Google Patents

Abstract

The utility model relates to the field of low-rise construction, namely to structures used as floors and coverings of residential and public buildings. The utility model is aimed at increasing the rigidity, strength and reducing the labor intensity of manufacturing both beams and the entire floor as a whole. slab includes load-bearing beams with stamped anchors, united by a monolithic slab. According to the utility model, the load-bearing beams are made of steel thin-walled profiles in the form of an inverted hat-shaped section with stamped in the upper flange with a variable pitch decreasing to the anchor supports, moreover, the anchors have carved "ruffs", which improves the joint work of the steel beam with concrete. due to the presence of wedge-shaped anchors in the shelves of the curved profile with carved "ruffs", it has increased rigidity and strength, due to the joint work of beams with a concrete slab and, as a result, provides a decrease in steel consumption. The presence of wedge-shaped anchors in the upper flange of the beams with an increased width at the base, provides an increased bearing capacity of the anchors themselves and the entire floor. The presence in the stretched zone of ribs-beams of reinforcing bars placed on the "holes" by stamped pins increases the bearing capacity of the ribs-beams and the entire floor.

Description

The utility model relates to the field of low-rise construction and can be used as floors in residential and public buildings.

Known steel-concrete floor, including load-bearing steel beams, filling elements, united by a monolithic slab, where “P” shaped anchors with bends are welded to the load-bearing beams in the form of steel T-bars (see RF patent No. 171103, E04B 5/00, publ. 05/22/2017 , bulletin No. 15).

The disadvantages of steel-concrete floors are the comparatively low stiffness and strength of the T-bars, the laboriousness of manufacturing a steel beam with anchors and, as a consequence, of the entire floor.

It is known a steel-concrete floor, including load-bearing beams, filling elements united by a monolithic slab, where the load-bearing beams are made of bent profiles, connected by stamped bends in wall sections, the upper chords for connection with a concrete slab are stamped with ribs and with holes with bends (see RF patent No. 170084, IPC E04B 5/23, publ. 04/13/2017, bul. No. 11).

The disadvantages of a steel-concrete floor are the relatively low rigidity and strength, the laboriousness of manufacturing a lattice beam and, as a consequence, the entire floor.

The closest is a steel-concrete floor consisting of steel composite beams and various slab structures (concrete, wood or polymer fiberboards) US 20120124796 AI 2012 entitled “System for producing composite beams and floor structures of buildings by means of bent sections made of steel and another material attached by means of connectors formed in the section made of steel ", where the secondary steel beams as part of the beam cage of the floor for the convenience of conjugation with the main beam are made of bent profiles forming mainly an I-section, the upper belt of the floor is taken mainly from prefabricated slabs (concrete, wood or fiberboard). The connection of the slabs with a composite beam of bent sections is carried out by means of anchors of various shapes, cut from the upper chord of I-beams (see patent US 20120124796 AI 2012).

The disadvantages of overlapping are the high laboriousness of manufacturing composite steel beams, low efficiency of the anchors (the bends of the ends of the anchors are oriented in different directions without taking into account the action of shear forces acting in a bent element consisting of several layers). The same pitch of the anchors, which does not take into account the maximum and minimum values of the overlapping forces of the bending elements, the smooth bore of the anchors, and the constancy of the section of the anchors along their length. In the proposed sections of the beams of the invention made of thin-walled bent profiles at high loads and spans, the loss of stability of the stretched zone of the wall is also possible (see the book. Metal structures, edited by Yu.I. Kudishin, Moscow, 2011, p. 200, Fig. 7 , 17) and longitudinal buckling of the beam.

The utility model is aimed at reducing the labor intensity of manufacturing a steel beam and floor, increasing the longitudinal stability, rigidity and strength of the beam and floor.

The result is achieved by the fact that in a steel-reinforced concrete ribbed floor, including load-bearing steel beams, a monolithic slab according to the utility model, the load-bearing beams are made of thin-walled steel profiles in the form of an inverted hat-shaped section. The result is also achieved by the fact that for joint work with concrete, wedge-shaped anchors with expansion towards the base are stamped into the steel bearing beam with a hat-shaped section in the upper flange, and in order to improve adhesion with concrete, "ruffs" are carved on the anchors. The result is also achieved by the fact that in order to increase the bearing capacity of the ribs-beams on their walls in the stretched zone, studs are carved with "loupes" on which reinforcing bars are placed.

FIG. 1 shows a steel-reinforced concrete ribbed floor in perspective; in fig. 2 - node A, where "ruffs" cut from anchors are shown; Fig. 3 - node B, which shows a hairpin with a "hole" for the placement of bar reinforcement.

The overlap includes steel bearing beams with a hat-shaped section 1, a monolithic slab 2 is supported on the beams 1. Steel bearing beams 1 made of thin-walled hat-shaped profiles in the upper flange have stamped anchors 3. In order to obtain a rational section, anchor 3 is stamped from the upper flange of a thin-walled steel wedge-shaped profile forms with expansion at the base. In order to improve the adhesion of the concrete shelf 2 with the upper chord of steel beams-ribs 1 of the floor, the anchors 3 are stamped with a variable pitch a ₁ , a ₂ , and ₃ ... with a decrease to the supports, moreover, in the anchors 3 "ruffs" are carved 4. In order to increase the bearing capacity of the ribs-beams on the carved studs 5 with "holes" 6 is the rod reinforcement 7.

The installation procedure for the ribbed floor is as follows. First, steel load-bearing beams 1 with stamped anchors 3 are installed on the walls or main beams of the building frame, then formwork elements are installed on these beams, mesh 8 is mounted, monolithic concrete 2 is laid.

The assembled steel-reinforced concrete floor, due to the presence of stamped anchors of rational section with pins in the upper flange in the steel beams and their arrangement with a step decreasing to the supports, has increased rigidity and strength, as a result, provides a decrease in steel consumption. The use of beams in floors made of such bent profiles reduces the laboriousness of their manufacture, and the presence of stamped wedge-shaped anchors in the shelves with an increased cross-section at the base, as well as the presence of carved studs in the anchors, increases the bearing capacity of the anchor ties and the entire floor.

Claims (2)

1. Reinforced concrete ribbed slab, including bearing steel ribs-beams with carved pins, a monolithic slab and anchor ties, characterized in that the bearing beams are made of a thin-walled steel profile in the form of an inverted hat-shaped section filled with concrete with anchors stamped on the walls and in the upper shelf wedge-shaped with increased width at the base with a variable pitch, decreasing towards the supports, which have "ruffs" carved. 2. Reinforced concrete ribbed floor according to claim 1, characterized in that, in order to increase the bearing capacity of the ribs-beams filled with concrete, longitudinal reinforcing bars are placed on the “holes” of the studs carved from the stretched zone of the walls.

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