SU1060778A1 - Reinforced girder - Google Patents

Abstract

REINFORCED BEAM, including lamellar blocks with a wedge placed between them with a notch under a pre-stressed free-sliding working reinforcement, characterized in that, in order to adjust the bearing capacity, the wedge is made with double sharp ends, and the cradle ends of the lamellar blocks at the wedge installation sites provided with cylindrical rolling bearings, the protruding part of the upper wedge is made with a bordering plate with edges, and the beam is equipped with different-arm levers on the rollers, small Lechi which are summed under the edges, and most of the shoulders are provided with contact rollers for bearing structures. L O) o | oo

Description

The invention relates to construction and can be used as supporting structures such as beams and foundations for precision instruments, as well as an independent power mechanism, for example, in vehicles.

Known beam, consisting of blocks connected by prestressed reinforcement with stops at the ends, freely sliding reinforcement which is located in the through channels of the blocks, and wedge-shaped clamps are installed between the ends of the blocks with an interference fit [1].

However, this solution is characterized by the fact that when the beam is working under load, the forces in it are not evenly distributed, especially between the upper and lower working zones, and the blocks in the lower working zone work in tension, leading to destruction. In addition, over time, under load, the prestressing of the rods of the freely sliding, working reinforcement decreases, which cannot be replaced.

Closest to the proposed one is a reinforced beam, including plate blocks with a wedge placed between them with a cutout for a prestressed, freely sliding working reinforcement. This design provides uniform load distribution over the entire area of the blocks of the blocks due to the presence of conical stops in the lodges between the ends of the blocks [2].

A disadvantage of the known solution is that the prestressed rod of the freely sliding reinforcement as a result of prolonged exposure to the load remains without voltage, which is partially compensated by the redistribution of the load when it increases to a certain limit, allowing again to increase the voltage of the bars of the working reinforcement, but by a relatively small amount.

The purpose of the invention is the regulation of the bearing capacity of the reinforced beam.

This goal is achieved by the fact that in the reinforced beam, which includes plate blocks with a wedge between them with a cutout for prestressed, freely sliding working reinforcement, the wedge is made with double sharp ends, and the lodgements of the ends of the plate blocks at the places of installation of the wedges are equipped with cylindrical .. rolling bearings, with the protruding part of the upper wedge is made with a restrictive plate with edges, and the beam is equipped with different levers on the rollers, the small shoulders of which are brought under Raina, with big shoulders are provided with contact rollers for supporting the load-bearing structures.

The drawing schematically shows the proposed reinforced beam.

, The beam consists of lamellar blocks 1 with a hole for the rod 2 of a prestressed freely sliding working reinforcement with stops at the ends 3. Between the ends of the blocks 1, two wedges 4 and 5 are rigidly mounted towards each other with sharp ends under the rod 2 of the reinforcement. The upper wedge 4 protrudes above the surface of adjacent plate blocks 1, at the wide end of the wedge 4, a restrictive plate 6 with flanges is mechanically in contact, mechanically in contact with different levers 7 on rollers 8 located on the upper part of adjacent plate blocks 1. Mounted on a long shoulder of a different lever 7 roller 9. On each side of the upper wedge 4, bearings 10 are mounted between the ends of adjacent plate blocks.

Under load, the reinforced beam works as follows.

Under the action of the load P through the building element 11, a torque is generated on the different levers so that the large shoulders of the different shoulders of the lever 7 are lowered, and its small shoulders rise to the edges of the plate 6 and move the rigidly connected wedges 4 and 5 up along the bearings 10 so that the lower wedge 5, entering the space between the plate blocks 1, strains them and the rod 2 of the working armature. The outer ends of the plate blocks 1 lying on the supports, due to friction, receive an emphasis that contributes to a greater compression of the material of the plate blocks, approaching the conditions of comprehensive compression, which provides unlimited opportunities to increase the bearing capacity of the beam with low material consumption, since the working rod 2 of the reinforcement loses part of the load, providing work only to the material of the plate blocks 1.

The advantage of the design of the proposed beam is the ability to withstand maximum loads, which, first of all, depends not on the strength of the reinforcement, but on the strength characteristics of the material of the plate blocks. With partial removal of the load, the beam parts can automatically return to their previous position, with residual deformation being affected.

Under conditions of vibrodynamic (shock) loads, a mechanized beam is capable of damping them due to plastic deformations of plate blocks during the movement of rigidly fixed wedges 4 and 5, as well as movements of block plates along the rod of the working reinforcement. Mechanical vibrations in a mechanized beam are damped by repeatedly reflecting them from the material of the block plates.

Claims (1)

REINFORCED BEAM, including plate blocks with a wedge placed between them with a cutout for prestressed freely sliding working reinforcement, characterized in that, for the purpose of adjusting the bearing capacity, the wedge is made with double sharp ends, and the lodgements of the ends of the plate blocks at the places of installation of the wedges are equipped with cylindrical bearings rolling, while the protruding part of the upper wedge is made with a restrictive plate with edges, and the beam is equipped with different levers on the rollers, small shoulders which are brought under the flanges, and the large shoulders are equipped with contact rollers for supporting bearing structures.