RU2664085C1 - Method of strengthening of single-bay reinforced concrete beams and building and structure beams - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to the field of construction, namely, to a method for reinforcing single-span reinforced concrete beams or a slab of overlying reinforcement. Reinforcement method consists in that the tensioned reinforcement is placed in the span of the building frame on the lower edge of the beam or plate in the zone of tensile stresses, at the same time, metal plates are installed from below and above the beam or plate in the support zone and are tightened by the studs with a reduction force, less than the prismatic strength of the concrete, and the tension force of the reinforcement P is provided by the condition P≤N⋅f, where N is the compression force, f is the coefficient of friction of the surface of the metal plate and concrete, after which the abutments are rigidly fixed on the lower plates and the ends of the reinforced reinforcement are placed in them, the reinforcement is heated and fixed in the stops by anchor devices followed by cooling by transferring the tension force through the plates to the structure.EFFECT: technical result consists in reducing the labor intensity of the assembly work.1 cl, 4 dwg

Description

The invention relates to the field of construction, namely to strengthening and increasing the bearing capacity of structures of single-span reinforced concrete beams and floor slabs, previously constructed, reconstructed buildings and structures in operation.

A known method of reinforcing beams and plates, including welding additional reinforcement using a connecting element to an existing open working reinforcement of the lower edge, or by tightening along the side faces, abutting on the supporting tables attached to the ends of the structures / 1 /.

It is known that for reinforcement it is necessary to open the end sections of the walls at the points of support of the ends of the beams or plates to install support elements with stops for tightening reinforcements located on the side faces of the reinforced structures. Puffing is possible with free access to the side faces of reinforcement structures / 2 /.

Closest to the proposed is a reinforcement method, including opening the working reinforcement at the attachment points of additional reinforcement reinforcement, fixing by welding the connecting element with the working reinforcement of the structure and after welding the ends of the reinforcement reinforcement with reinforcement connecting reinforcement / 3 /.

The disadvantages of the known methods is that the protective layer of concrete is removed, a section of the working reinforcement is opened, and the connection of the connecting element with the working reinforcement is fixed by welding. Further reinforcement reinforcement is also fixed to the connecting element by welding. A welded method of fastening with working fittings in tension is not recommended. The forces arising in the reinforcement reinforcement are transferred to the structure through the working reinforcement in tension.

The technical task is to develop a method of reinforcing the structure, in which installation work is simplified, welding work is reduced and material costs are reduced.

The problem is solved in such a way that in the method of reinforcing single-span reinforced concrete beams and floor slabs of buildings and structures with prestressing reinforcement according to the invention, prestressing reinforcement is placed in the spans of the building frame on the lower face of the structure in the zone of tensile stresses of the ceilings and beams, while previously lower and upper floors in metal plates are installed in the supporting zone and pulled together with studs with a compression force less than the prismatic strength of the concrete structure, and the tension force arm guides P is ensured by the condition Р≤N⋅f, where N is the compression force, f is the friction coefficient of the surface of the metal plate and concrete, after which the stops are rigidly fixed to the lower plates and the ends of the tensioned reinforcement are placed in them, the reinforcement is heated and fixed in the stops with anchor devices, followed by cooling, transferring tension forces through the plates to the structure. At the same time, to increase the reinforcement tension force, use a metal plate with notches on the side adjacent to the concrete structure, to increase the reinforcement tension force use a metal plate with notches on the sides adjacent to the concrete structure with a friction coefficient of the metal plate and concrete of 0.5-3, 0.

The proposed method differs from the known one in that the tensioned reinforcement is placed in the spans of the building frame on the lower face of the structure in the zone of tensile stresses of the floor and beams, and metal plates are preliminarily installed at the bottom and top of the floor in the support zone and pulled together with studs with a reduction force of less than prismatic concrete strength, and the reinforcement tension force P is provided by the condition Р≤N⋅f, where N is the compression force, f is the coefficient of friction of the surface of the plate and concrete N, after which on the lower plate stops rigidly attached and positioned therein the ends of the prestressing reinforcement, reinforcement is heated and fixed in abutment with the anchor devices at the subsequent cooling, the tensile force transfer through the plates to the structure. To increase the tension force of the reinforcement, a metal plate with notches on the sides adjacent to the concrete of the structure with a friction coefficient of the metal plate and concrete of 0.5-3.0 is used.

To strengthen the structure, reinforcement reinforcement for single-span beams and floor slabs is laid on anchor plates with stops previously fixed on sections of structural reinforcement zones. Reinforcing reinforcing elements are made of reinforcement of measured length, at the ends of which a screw thread is made. Reinforcing elements are laid on anchor plates with stops that are pre-fixed with studs. The plates are located on top without stops and below with stops in the supporting areas of the structure, close to the supports.

This arrangement of the plates makes it possible to simultaneously strengthen the structures in the spans in the zones of bending moments and on supports in the zones of shearing forces.

The upper and lower anchor plates are fixed between each other and with reinforcement structures using studs laid in drilled holes in the structures.

Reinforcing reinforcing elements are laid on anchor plates, their ends are inserted into the stops, and nuts or collet clamps are installed on the ends.

For prestressing, reinforcing elements are heated to a certain temperature, the reinforcement gets elongation. In this state, by tightening the nuts at the ends or anchoring the collet clamps, the reinforcement is fixed on the stops. The reinforcement cools down, and the voltage is transmitted through the anchor plates to the reinforcement structure.

The forces arising from the reinforcement voltage are absorbed by the anchor plate. The solidity (immobility) of the anchor plate is ensured by the value of the compression force of the plate, which is calculated by the formula N⋅f≥P = P _sd ,

Where

- N is the compression force of the anchor plate;

- f is the coefficient of friction between the surfaces of the metal plate and concrete structure;

- P - tensile reinforcement;

- R _sd - the shear force arising on the plate from the tension of the reinforcement.

The value of N is limited by the condition N≤R _b ,

Where

- R _b - prismatic strength of concrete.

Thus, the magnitude of the tension reinforcement reinforcement is provided by the condition: P = P _sd ≤N ≤f. The method of fixing the anchor plate provides reliable fastening of the anchor plate with a reinforcement structure.

The force arising from the reinforcement voltage is transmitted through the anchor plates to the reinforcement structure. The section in the span between the anchor plates goes into a stressed state of compression. The shear force arising in the anchor plate from the tension of the reinforcement is compensated by the compression force of the plate with concrete and is directly perceived by the reinforcement structure.

At the same time, the studs that compress the plates and ensure the anchoring of the plates with the structure are at the same time reinforcement of the supporting sections of the structure from cutting (forcing) forces on the supports.

The technical result is a reduction in the number of elements of the reinforcement structure and the simplicity of their manufacture, a decrease in the complexity of installation work, during which a voltage arises in the reinforcement reinforcement, which is transmitted through the anchor plates to the reinforced structure. In this case, prior to the increase in operating loads, the structure is pre-stressed, and the reinforcement reinforces the loads in the zone of bending moments, and the anchor plates with studs absorb the stresses arising from shear (forcing) forces in the supporting zones, thereby increasing the bearing capacity of the structure as a whole.

The method is illustrated by drawings, where in FIG. 1 is a diagram of a gain structure; FIG. 2 is a view according to A of FIG. one; FIG. 3 - node A of FIG. 1, FIG. 4 is a view according to B of FIG. 3.

The design of a single-span plate 1 is based on walls or columns 2. The reinforcement design consists of reinforcement reinforcement 6 and a support element (assembly B) consisting of support plates 3, stops 4, studs 5 and nuts 7.

The method is as follows.

On the supporting sections of the beam or plate 1, resting on the walls or columns 2, holes are drilled and support plates 3 are installed with stops 4, which are fastened and secured to the reinforced structures using studs 5. The reinforcement reinforcement 6 is inserted into the stops 4 and is heated to elongation and fixed on the stops 4 from both ends by nuts 7. The reinforcement 6, cooling, is strained. The force from the voltage of the reinforcement through the base plates 3 is transmitted to the reinforcement structures 1 and is controlled by the heating temperature of the reinforcement. When this reinforcement reinforcement 6 perceives the load reinforced structure 1.

An example of calculating the elongation and heating temperature for valves of class A500C

составит Δ

=Р⋅L/Е⋅A_S=14130⋅600/200⋅10⁴⋅3,14=1,35 см=13,5 мм, где Е=200⋅10⁴ кгс/см² модуль упругости арматуры. Температура нагрева арматуры Т для получения удлинения Δ

=1,35 см будет Т=Δ

/α⋅L=1,35/11,3⋅10^-6⋅600=199,1°С, где α=11,3⋅10^-6 коэффициент линейного (теплового) расширения металла. Принимаем предельную температуру нагрева арматуры класса А500С - 200°С.The maximum value of the tensile force P of reinforcement of class A500C for diameter Ф20 with the design resistance R _S = 4600 kgf / cm ² is equal to P = R _S ⋅ A _S = 4600⋅3.14 = 14130 kgf, where A _S = 3.14 cm ² area section of reinforcement. For the estimated length of the reinforcement L = 6 m = 600 cm, in order to obtain a tensile force P = 14130 kgf, elongation Δ

will be Δ

= R⋅L / E⋅A _S = 14130⋅600 / 200⋅10 ⁴ ⋅3,14 = 1,35 cm = 13.5 mm, where E = 200⋅10 ⁴ kgf / cm ² modulus reinforcement. Rebar heating temperature T to obtain elongation Δ

= 1.35 cm will be T = Δ

/ α⋅L = 1.35 / 11.3⋅10 ^-6 ⋅600 = 199.1 ° С, where α = 11.3⋅10 ^{-6 the} coefficient of linear (thermal) expansion of the metal. We accept the limiting temperature of heating of class A500C reinforcement - 200 ° С.

Information sources

1. Fedorov V.V. Reconstruction and restoration of buildings. M .: SI.

2. A.L. Shagin and others. Reconstruction of buildings and structures Textbook. allowance. M .: Higher. school., 1991, 352 p.

3. Recommendations for the design of reinforced concrete structures of buildings and structures of reconstructed enterprises. Overground structures and structures. Moscow, Stroyizdat, 1992 / prototype /.

Claims (2)

1. A method of reinforcing single-span reinforced concrete beams or floor slabs of a building and structures with prestressing reinforcement, characterized in that the prestressing reinforcement is placed in the spans of the building frame on the lower edge of the beam or slab in the tensile stress zone, with the beam and slab previously in the support zone they install metal plates and tighten them with studs with a compression force less than the prismatic strength of concrete, and the reinforcement tension force P is provided by the condition P≤N⋅f, where N is the compression force, f is the coefficient friction of the surface of the metal plate and concrete, after which the stops are pre-rigidly fixed to the lower plates and the ends of the prestressed reinforcement are placed in them, the reinforcement is heated and fixed in the stops by anchor devices, followed by cooling, by transferring the tension force through the plates to the structure. 2. The method according to p. 1, characterized in that to increase the tension of the reinforcement, a metal plate is used with notches on the sides adjacent to the concrete structure with a coefficient of friction of the surface of the metal plate and concrete of 0.5-3.0.

Images