RU2599110C1 - Device for bearing structures reinforcement - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction and can be used for reinforcement of bearing structures of columns, walls and brick columns. Device for reinforcement of bearing structures includes installed on the bearing structure reinforcement element made in the form of a metal squeeze reduction hooping to envelope the reinforced bearing structure and be fixed on it with the possibility of joint operation due to contact surfaces. Squeeze reduction hooping is made of vertical elements of angle section interconnected by transverse planks. Inner faces of the vertical elements of angle section are additionally equipped with rods welded to them forming the surface roughness and providing joint operation of the reinforced bearing structure and the metal squeeze reduction hooping. Space between the inner faces of the vertical elements and the prepared contact surface of the reinforced bearing element having the roughness is filled with a concrete mix within the range of protective layer of the lengthwise reinforcing rods.

EFFECT: technical result is reduction of metal consumption.

13 cl, 10 dwg

Description

The invention relates to the field of construction and can be used to strengthen the supporting structures of columns, piers and brick pillars.

A device for reinforcing a reinforced concrete column is known, comprising a metal cage mounted on the column made of vertical corners welded to metal plates, which in turn are welded to the rods of the working longitudinal reinforcement using reinforcing shorts (Malganov A.I., Plevkov BC, Polishchuk A .I. Restoration and strengthening of building envelopes of buildings and structures. Atlas of diagrams and drawings. Tomsk. Tomsk Interindustry TsNTI, 1990, 315 pp. [Scheme of welding metal corners to working reinforcement th column on the sheet 106]).

The disadvantages of the known device are large labor costs and high metal consumption, as well as a decrease in the bearing capacity of the column at the time of the work due to the presence of the following factors: removal of the protective layer of reinforcement; strong heating during welding of longitudinal rods of working reinforcement; a possible reduction in the area of existing longitudinal reinforcement in the places of welding of reinforcing shorts.

It is also known that columns are reinforced with a metal cage containing longitudinal angles interconnected by transverse strips with the possibility of compression, while for reinforcing, the longitudinal corners are mounted on the column in solution and temporarily pressed against the column with clamps, and the transverse bars are welded to the longitudinal corners heated to temperature 200-250 ° C (Malganov A.I., Plevkov BC, Polishchuk A.I. Restoration and reinforcement of building envelopes of buildings and structures. Atlas of diagrams and drawings. Tomsk. That Moscow Interdisciplinary TSNTI, 1990, 315 pp. [installation diagram of prestressed clamps on sheet 106]).

The disadvantages of the known device are: firstly, low reliability due to the lack of the possibility of reliable fixation of the contact of the rounded part of the inner surface of the vertical corner with the corner of the column, which can lead to undesirable distortions and displacements of the angle in height in different planes when compressing with transverse bars; secondly, the possibility of local overheating of concrete in places of heating of the transverse slats; thirdly, the need for the availability of expensive equipment for temperature control when heating the transverse slats.

As a prototype, a device is used that is used in the known method for anchoring prestressed reinforcement brackets, comprising an anchor device that is directly attached to the reinforced structural member with clamping bolts, while the anchor device is made in the form of a steel clip of compression with thrust tables for cargo screws of the spacers, and the clip of compression made from composite brackets with persistent ribs at the end sections equipped with coupling bolts, and the inner surface of the brackets is machined to increase the forces peace (Patent of the Russian Federation No. 2315158 C2, priority date 10/03/2005, publication date 04/10/2007, authors: Ilyin N.A. et al., RU, prototype).

The disadvantages of the prototype are:

- firstly, the lowered adhesion of the tensioned struts with a reinforced element;

- secondly, the significant metal consumption of the reinforcing elements, due to the implementation of brackets, tightened by bolts and equipped with thrust tables for cargo screws of reinforcing struts;

- thirdly, significant dimensions of the reinforcing element, reducing the useful volume of the building.

The objective of the invention is to increase the efficiency of the device for reinforcing load-bearing structures by increasing the static coefficient of rest friction between the compression sleeve and the reinforced load-bearing element by reducing the metal consumption by reducing the weight of the reinforcing elements and by reducing the overall dimensions of the reinforced structure.

To solve this problem, a device for reinforcing load-bearing structures is proposed, including a reinforcing element mounted on a load-bearing structure made in the form of a metal clip of compression, covering the reinforced load-bearing structure and fixed on it with the possibility of ensuring joint operation due to contacting surfaces. According to the invention, the metal clip of the compression is made of vertical elements of the angular profile, interconnected by transverse strips, while the inner edges of the vertical elements of the corner profile are additionally equipped with welded reinforcing bars that form the surface roughness and ensure the joint work of the reinforced supporting structure and the metal clip of compression the space between the inner faces of the vertical elements and the prepared contact surface th amplified bearing member having a surface roughness, filled concrete mixture within a protective layer of longitudinal reinforcement.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by transverse reinforcing bars arranged in a row with the same pitch in each shelf between the outer and inner rounding of the faces of the shelves of the vertical elements.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by transverse reinforcing bars located in a row with the same pitch in each shelf and additional vertical reinforcing bars located near the internal and / or external rounding of the faces of the shelves of the vertical elements.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by transverse curved reinforcing bars arranged in a row with the same pitch and made with a bend radius corresponding to the inner rounding of the faces of the shelves of the vertical elements.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by reinforcing rods inclined in a row with the same pitch in each shelf between the outer and inner rounding of the faces of the shelves of the vertical elements.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by curved reinforcing bars in the form of a snake in each shelf with alternating horizontal and vertical sections equally oriented with respect to each other or to the edges of the shelves of the vertical elements.

According to the invention, the surface roughness of the inner faces of the vertical elements is formed by a fine-mesh reinforcing mesh.

According to the invention, reinforcing rods providing the joint operation of the reinforced supporting element and the metal compression sleeve are welded to the branches of the holder located in the stretched zone.

According to the invention, the contacting surfaces of the vertical elements of the corner profile of the metal compression sleeve and the reinforced load-bearing structure are configured to increase the friction coefficient.

According to the invention, a layer of elastic material is located between the vertical elements of the angular profile of the metal compression sleeve and the reinforced supporting structure.

According to the invention, either non-shrinkable fine-grained concrete mixture, self-tensioning fine-grained concrete, or fine-grained fiber-reinforced concrete can be used as a concrete mixture in the space between the inner faces of the vertical elements of the compression metal clip and the reinforced supporting structure.

In FIG. 1 schematically shows a device for strengthening load-bearing structures, general view; in FIG. 2 schematically shows a section of a device for reinforcing load-bearing structures; in FIG. 3 - node A in FIG. 2; in FIG. 4 schematically depicts a vertical element of the angular profile of a compression sleeve with reinforced roughness of internal faces formed by welded transverse reinforcing bars in each shelf, general view; in FIG. 5 is the same, an option with additionally welded vertical rods near the outer rounding of the edges of the shelves; in FIG. 6 - the same version with additionally welded vertical rods near the outer and inner rounding of the edges of the shelves; in FIG. 7 is the same, the version with welded transverse curved reinforcing bars having a bending radius corresponding to the inner radius of rounding of the shelves of the vertical element; in FIG. 8 - the same version with welded inclined reinforcing bars in a row to each shelf; in FIG. 9 is the same, an option with curved shaped reinforcing rods welded to each shelf of vertical elements in the form of snakes equally oriented with respect to each other; in FIG. 10 - the same version with curved shaped reinforcing rods welded to each shelf of vertical elements in the form of snakes that are equally oriented with respect to the edges of the shelves of vertical elements.

The device for reinforcing the supporting structures comprises a reinforcing element mounted on the reinforced supporting structure, for example, column 1, connected with the reinforced structure to ensure joint operation. The reinforcing element is made in the form of a metal clip of compression 2, covering the supporting structure and consisting of vertical elements of the corner profile 3, interconnected by transverse strips 4 (Fig. 1). To ensure the joint work of the reinforced supporting structure and the metal clip of compression to the inner faces of the shelves of the vertical elements 3, reinforcing bars 5 are welded, forming the surface roughness, and the space between the inner faces of the shelves of the vertical elements and the prepared contact surface 6 of the reinforced supporting element 1 within the protective layer of the longitudinal reinforcement 7 reinforced supporting element 1 is filled with fine-grained concrete, connecting the contacting surface (Fig. 2, Fig. 3) .

Reinforcing rods 5, welded to the inner faces of the shelves of the vertical elements 3, can be made round or other shape, with and without corrugation, as well as:

- transverse reinforcing bars in a row welded to each shelf (Fig. 4);

- transverse reinforcing bars in a row welded to each shelf, with additionally welded vertical bars near the outer fillet edges of the shelves (Fig. 5);

- transverse reinforcing bars, in a row welded to each shelf, with additionally welded vertical bars near the outer and inner fillet edges of the shelves (Fig. 6);

- transverse curved reinforcing bars in a row of vertical elements welded to the inner shelves, with a bending radius corresponding to the inner radius of rounding of the shelves of the vertical element (Fig. 7);

- inclined reinforcing bars located in a row with the same pitch in each shelf between the outer and inner rounding of the faces of the shelves of the vertical elements (Fig. 8);

- reinforcing bars of curved shape in the form of snakes welded to each shelf of vertical elements and made with alternating horizontal and vertical sections, equally oriented with respect to each other (Fig. 9);

- reinforcing bars of curved shape in the form of snakes, welded to each shelf of vertical elements and made with alternating horizontal and vertical sections, equally oriented with respect to the edges of the shelves of vertical elements (Fig. 10).

To ensure a more reliable contact of the metal clip of the compression and reinforced load-bearing structure, the following design features and techniques are also possible.

Reinforcing rods providing the joint work of a reinforced eccentrically-supported supporting element having a large eccentricity and a metal compression sleeve can be welded to the branches of the holder located only in the stretched zone.

The contacting surfaces of the vertical elements of the angular profile of the metal cage and the reinforced supporting element can be made with the possibility of increasing the coefficient of friction. In this case, the surfaces of the reinforced supporting element 1 to provide roughness on the contact spot with the vertical elements of the compression cage can be notched, and the inner surfaces of the vertical elements 3 are respectively treated, for example, with a sandblasting mixture.

Between the vertical elements of the angular profile of the metal cage and the reinforced structure, a layer of elastic material (conventionally not shown) can be located.

To ensure the joint operation of the metal clip of the compression and reinforced bearing element can be used in various techniques and materials.

The gap between the inner faces of the shelves of the vertical elements of the compression sleeve and the reinforced load-bearing element can be filled with fine-grained concrete mixture, non-shrinking fine-grained concrete mixture, self-tensioning fine-grained concrete or fine-grained fiber-reinforced concrete. In this case, one of the possible methods for ensuring joint work may be the application of fine-grained concrete mixture on the inner surfaces of the vertical elements of the metal cage installed in the design position, followed by pressing them to the reinforced supporting element with clamps, accompanied by squeezing the excess concrete mixture with filling the entire surface of the zone the contact of the vertical elements of the clip cage and the bearing element.

The reduction in the overall dimensions of the reinforced structure is ensured by the possibility of compressing the vertical elements of the ferrule with clamps until the welded reinforcing bars fully adhere to the prepared rough surface of the reinforced element body with full squeezing of the concrete mixture within the protective layer of longitudinal reinforcement.

Alternatively, it is also possible to perform roughness on the surface of the reinforced element directly in the contact zone with the welded reinforcing bars in the form of reciprocal recesses repeating the contour of the welded rods with a slight increase in the size of this contour relative to the dimensions of the section of the rods (not shown conditionally).

The technical result achieved by the proposed device for reinforcing load-bearing structures is to increase the static coefficient of static friction between the compression sleeve and the reinforced load-bearing element, to reduce the metal consumption by reducing the weight of the reinforcing elements and to reduce the overall dimensions of the reinforced structure.

At the same time, the advantages of the claimed device for reinforcing load-bearing structures that provide the specified technical result are due to the use of a metal compression sleeve as a reinforcing element, covering the reinforced structure with the possibility of working together due to significant rest friction, which is provided by welding reinforcing bars to the inner faces of the shelves a solution layer on the treated surface of the reinforced supporting element.

Claims (13)

1. A device for reinforcing load-bearing structures, including a reinforcing element mounted on a load-bearing structure, made in the form of a metal clip of compression, covering the reinforced load-bearing structure and mounted on it with the possibility of ensuring joint work due to contacting surfaces, characterized in that the metal clip of compression is made of vertical elements of the corner profile, interconnected by transverse bars, while the inner faces of the vertical elements of the corner profile to are equipped with reinforced rods welded to them, forming surface roughness and ensuring the joint operation of the reinforced supporting structure and the metal clip of compression, and the space between the inner faces of the vertical elements and the prepared contact surface of the reinforced bearing element with roughness is filled with concrete mix within the protective layer of longitudinal reinforcement . 2. A device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by transverse reinforcing bars arranged in a row with the same pitch in each shelf between the outer and inner rounding of the faces of the shelves of the vertical elements. 3. A device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by transverse reinforcing bars located in a row with the same pitch in each shelf, and additional vertical reinforcing bars located near internal and / or external rounding the edges of the shelves of vertical elements. 4. A device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by transverse curved reinforcing bars located at the same pitch and made with a bend radius corresponding to the inner rounding of the edges of the shelves of the vertical elements. 5. A device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by reinforcing bars that are inclined in a row with the same pitch in each shelf between the outer and inner rounding of the faces of the shelves of the vertical elements. 6. The device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by curved reinforcing bars in the form of a snake in each shelf with alternating horizontal and vertical sections equally oriented with respect to each other or to the edges shelves of vertical elements. 7. A device for reinforcing load-bearing structures according to claim 1, characterized in that the surface roughness of the inner faces of the vertical elements is formed by a fine-mesh reinforcing mesh. 8. A device for reinforcing load-bearing structures according to claim 1, characterized in that the reinforcing bars providing the joint operation of the reinforced load-bearing element and the metal clip of compression are welded to the branches of the clip located in the stretched zone. 9. A device for reinforcing load-bearing structures according to claim 1, characterized in that the contacting surfaces of the vertical elements of the corner profile of the metal compression sleeve and the reinforced load-bearing structure are configured to increase the friction coefficient. 10. A device for reinforcing load-bearing structures according to claim 9, characterized in that a layer of elastic material is located between the vertical elements of the angular profile of the metal compression sleeve and the reinforced load-bearing structure. 11. A device for reinforcing load-bearing structures according to claim 1, characterized in that non-shrinkable fine-grained concrete mixture is used as a concrete mixture in the space between the inner faces of the vertical elements of the compression metal clip and the reinforced load-bearing structure. 12. A device for reinforcing load-bearing structures according to claim 1, characterized in that self-tensioning fine-grained concrete is used as the concrete mixture. 13. A device for strengthening load-bearing structures according to claim 1, characterized in that fine-grained fiber-reinforced concrete is used as a concrete mixture.

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