SU1043278A1 - Ferroconcrete girder - Google Patents

Description

one

The invention relates to construction and can be used as load-bearing walls and partitions of buildings.

Known reinforced concrete structures, including a concrete body, reinforcement cage and embedded parts, in which embedded parts are flush with the concrete body 1.

However, the use of structures to beams-walls does not significantly increase the strength, since the areas of application of the load and the support of the structure are not connected by a supporting metal element.

The closest technical solution to the invention is a reinforced concrete beam-wall comprising a concrete body, a spatial armature framework and attached thereto, embedded parts, in which the latter are flush with the concrete body, while the areas of application of the load and the supporting structure are connected by a supporting metal element in the form of rigid reinforcement 2}.

However, the carrying capacity increases, but the steel consumption increases.

The purpose of the invention is to reduce the metal capacity.

The goal is achieved by the fact that in a reinforced concrete basement comprising a concrete body, a spatial reinforcement cage, and embedded parts attached to it, in the load application areas and the beams-walls interconnected by a reinforcing bar of the framework, the embedded parts are installed with a gap relative to the concrete body, moreover, the gap is filled with a sealant, and the gap size is not less than half the product of the relative maximum deformations by the length of the reinforcing bar.

FIG. 1 shows the beam-wall in FIG. 2 is a section A —A in FIG. one; in fig. 3 shows a section BB in FIG. one,

Reinforced concrete beam-wall 1 includes the concrete body 2, spatial reinforcement cage 3, embedded parts i, welded to the frame 3. In the load application zones 5 and the load-bearing zones 6 and 6, connect 10-1432782

between the reinforcing bar 7 of the frame 3, there is a gap of 8 me. I am waiting for the embedded part k and the concrete body 2, the gap is filled with sealant. 5 the gap size is not less than half the product of the relative maximum deformations by the length of the rebar 7.

Filling the gap 8 with sealant eliminates the direct transfer of the load through the embedded parts to the concrete body 2. In addition, the sealant simultaneously serves to protect the protruding part of the frame 3 from corrosion during operation of the beam-wall 1 in the building.

The cores of the spatial frame 3 of the reinforced concrete beam-wall 1, in order to bring it closer to the theoretically optimal one, are placed along the lines of main elongations of the strain rate field with the specified principal rates of elongation. Moreover, in the cross section of the frame 3 may have the form of a triangle, forming a closed spatial triangular system, which increases the rigidity of the beam-wall 1.

Technical and economic advantages of reinforced concrete beams-walls Compared with the known ones, there is a significant reduction in steel consumption, since the supporting metal element connecting the load and bearing areas is made of flexible reinforcement and does not require increased consumption of steel for rigid reinforcement.

In addition, compared to beams-walls reinforced with flexible reinforcement, in which there is no gap between the embedded part and the concrete body, the moment of cracking increases by 2-2.5 times, the work of the spatial reinforcement cage approaches the theoretically optimal Michelle truss, the beam wall has an increased the bearing capacity of the extreme compressed rods of the spatial reinforcing frame, which leads to an increase in the bearing capacity of the beam-wall to.

Cpuz.l

(Ree. 5

Claims (1)

(57) REINFORCED CONCRETE BEAM-WALL, including a concrete body, a spatial reinforcing cage and embedded parts attached to it, characterized in that, in order to reduce the metal consumption, in the areas of load application and supporting the beam-wall, the embedded parts are interconnected by a reinforcing core of the frame are installed with a gap relative to the concrete body, the gap being filled with sealant, and the gap size is at least half the product of the relative maximum strains and the length of the reinforcing bar.