RU220086U1 - Reinforced metal support column - Google Patents

Abstract

The utility model relates to the field of construction, namely to the strengthening of building structures and can be used to improve the seismic resistance of industrial buildings with a metal frame, operated in a seismically hazardous area.

The technical result of the utility model is to reduce the movement of the metal carrier column and the stresses in it, arising from seismic effects, to improve the seismic resistance of the metal frame of an industrial building while reducing the cost of work.

The technical result is achieved by using a reinforced metal carrier column in the metal frame of an industrial building, including a metal column, on which a concrete clip is installed at 1/6 of the height from the base of the metal column with a thickness of at least 3 cm in each direction from the outer contour of the metal column so that that the concrete cage and the metal column together form a monolithic structure, and a composite casing is installed on the outer surface of the concrete cage, formed by transverse and longitudinal reinforcement of the concrete casing with carbon tape with the same pitch using an adhesive composition. 2 w.p. f-ly, 2 ill.

Description

Technical field

The utility model relates to the field of construction, namely to the strengthening of building structures and can be used to improve the seismic resistance of industrial buildings with a metal frame, operated in a seismically hazardous area.

State of the art

Known external reinforcing structure of the column (patent RU 140540, E04G 23/02), including a metal cage removable U-shaped configuration, the halves of which are connected to each other into a single unit by flanges, bolted together, characterized in that the cage is made of self-sealing steel fiber reinforced concrete .

The disadvantages of this device are the instability of the characteristics and the high cost of steel fiber concrete and metal products used to create the holder, the increase in the cross-sectional area of the columns.

An external reinforcing structure is known (patent RU 85926, E04C 3/30), including a reinforced concrete cage with longitudinal and transverse reinforcement in the form of closed clamps and a layer of adhesive coating, characterized in that a layer of adhesive coating with fiberglass is applied to the inner surface.

An external reinforcing structure of a reinforced concrete column is known (patent RU 151500, E04G 23/02), including a reinforced concrete cage with longitudinal and transverse reinforcement in the form of closed clamps, characterized in that a layer of liquid glass with fiberglass is applied to the outer surface of the reinforced concrete column.

The disadvantages of the above two designs are the destruction of fiberglass under the influence of the alkaline environment of concrete, as well as the high cost of metal reinforcement of the reinforced concrete casing.

An external reinforcing structure of columns is known (patent RU 149451, E04C 3/00), including a reinforced concrete cage with longitudinal and transverse reinforcement in the form of closed clamps with an adhesive coating of epoxy glue applied to the surface of the reinforced element, characterized in that liquid glass.

The disadvantages of this design is that the chemical adhesion of concrete and liquid glass is extremely low, and there is no joint work of old and new concrete, and when exposed to high temperatures, adhesion becomes even lower; as well as the high cost of metal reinforcement of the reinforced concrete casing, an increase in the cross-sectional area of the columns.

A well-known design is obtained as a result of the implementation of a method for strengthening a reinforced concrete column of rectangular or square section (patent RU 2773490, E04G 23/02), including a formwork around the column, subsequent concreting with fine-grained self-expanding concrete, rounding the corners of the cross section of the column, cleaning the surface from dust and damaged concrete, surface priming; after the formwork and subsequent concreting, the formwork is removed and composite materials are glued transversely onto the column, while the formwork is arranged without a gap, close to the rounded corners of the column, and the composite material is glued to the rounded sections of the concrete casing.

The disadvantages of the design are the high complexity of work on strengthening and the use of a higher, therefore, expensive class of concrete, an increase in the cross-sectional area of the columns.

Known reinforced column for high-rise buildings (patent RU 143976, E04C 3/30) in the form of a reinforced concrete structure, including reinforcing elements, which use longitudinal metal rods, characterized in that it is additionally equipped with a metal frame formed by interconnected by means of stiffening ribs angular elements in which risers with at least one reinforcing element are installed, while on the side faces of the column and additionally installed on each end of the plates, through holes are made, and in the lower part of the column - blind holes.

The disadvantages of the solution are the large amount of reinforcement and, consequently, the high cost of the metal products used and the high labor intensity of the installation of metal structures.

Disclosure of the essence of the utility model

In accordance with the current SP 14.13330.2018, the calculated intensity of the seismic impact for a specific area for the location of an industrial building is taken from the maps of the general seismic zoning of the territory of the Russian Federation - OSR-2015. The maps that were valid until the 1990s regulated the estimated intensity of the earthquake, as a rule, by 1-2 points lower than in the OSR-2015. Thus, the task of increasing the seismic resistance of long-term exploited industrial buildings located in seismically active areas becomes urgent.

The technical result of the utility model is to reduce the movement of the metal carrier column and the stresses in it, arising from seismic effects, to improve the seismic resistance of the metal frame of an industrial building while reducing the cost of work.

The technical result is achieved by using a reinforced metal carrier column in the metal frame of an industrial building, including a metal column, on which a concrete clip is installed at 1/6 of the height from the base of the metal column with a thickness of at least 3 cm in each direction from the outer contour of the metal column so that that the concrete cage and the metal column together form a monolithic structure, and a composite casing is installed on the outer surface of the concrete cage, formed by transverse and longitudinal external reinforcement of the concrete casing with carbon tape with the same pitch using an adhesive composition.

In the development of the utility model, the material of the concrete casing is, for example, concrete grade B15.

The use of a reinforced metal carrier column to increase the seismic resistance of the metal frame of an industrial building ensures the redistribution of stress from seismic effects inside the reinforced metal carrier column and reduces their maximum values, as well as evenly distributes the stresses arising in the reinforced metal carrier column onto the concrete casing, while reducing the cost works to ensure the seismic resistance of an industrial building due to:

- use of fewer materials: concrete, carbon tape and adhesive composition;

- exclusion of work on the installation of a power reinforcing cage: its function is performed by existing metal columns;

- reducing the complexity of work to ensure the seismic resistance of an industrial building.

Brief description of the drawings

In FIG. 1 shows a cross section of a reinforced column.

In FIG. 1 adopted the following designations:

1. Metal column;

2. Concrete clip;

3. Carbon tape clip.

In FIG. 2 shows a perspective view of a reinforced column.

In FIG. 2, the following designations are adopted:

1. Metal column;

2. Concrete clip;

3. Carbon tape clip.

Implementation of the utility model.

Earthquake records show that in most cases, the greatest danger to multi-storey buildings is the horizontal components of the seismic action. Strengthening the lower 1/6 of the supporting metal columns reduces the horizontal displacement of the upper part of the supporting metal columns, which occurs due to seismic effects, to a value that provides the necessary bearing capacity of the metal frame of an industrial building due to an increase in the overall rigidity of the structures.

Reinforced metal bearing column is a metal column 1, reinforced with a concrete casing 2, created by monolithic column 1 from the base to 1/6 of its height with concrete grade B15, with an increase in the existing contour of the column by 3 cm in each direction. The concrete cage is reinforced with a casing made of carbon tape 3, which acts as an external reinforcement. Wrapping with carbon tape is carried out in one layer in the longitudinal and transverse directions with the same pitch using adhesive compositions, for example, Carbon Wrap Resin. The step of pasting the carbon tape is taken based on the loads perceived by the reinforced metal carrier column, in accordance with the design documentation developed in accordance with SP 164.1325800.2014 Reinforcement of reinforced concrete structures with composite materials. Design rules.

The advantages of using the utility model are:

- reduction of the class and volume of concrete used to create the cage;

- eliminating the need to reinforce the concrete casing with a power reinforcing cage;

- reducing the effective height of the reinforcement structure to 1/6 of the column height;

- insignificance of the increase in the geometric dimensions of the column.

The operability of the claimed device is confirmed by mathematical modeling of the supporting metal frame of the building of a thermal power plant (CHP) located in the Far East, and its individual components, including options: reinforced metal supporting column and columns without reinforcement. Modeling was carried out in the ANSYS software package, based on the finite element method, in a three-dimensional setting using three-dimensional elements that simulate the behavior of metal, concrete and shell elements for modeling external composite reinforcement. In accordance with the verification of the universal industrial software package ANSYS and the finite elements used for mathematical modeling, the calculation error does not exceed 5% relative to other calculation systems and full-scale laboratory studies.

The seismic impact from a 10 magnitude earthquake was modeled explicitly by setting artificial accelelograms. The proposed utility model allows you to optimize and improve the seismic resistance of the metal frame of an industrial building at the first 10 frequencies and modes of natural vibrations that have the largest contribution. As a result of the calculations, it was determined that the maximum stresses occur in the embedment of the metal column to the foundation and the first third of the height of the metal column.

The calculations showed that the horizontal displacements of the upper part of the reinforced metal bearing column 27.5 m high amounted to 235.75 mm (634.85 mm without reinforcement). The maximum stresses in the reinforced metal bearing column (in the area of the end of the reinforcing structure) do not exceed the design resistance of steel (245 MPa), while the maximum stress is 80.06 MPa (1136.20 MPa without reinforcement). The maximum stresses in carbon tapes are 597.44 MPa, which is within the allowable tensile strength of the tape (1000 MPa).

The claimed utility model reduces stresses in the metal frame of an industrial building from seismic effects. The deformation of the reinforced metal bearing column does not exceed the allowable values. Increasing the rigidity of the reinforced metal supporting column in the support node changes the vibration frequencies towards higher frequencies, reducing their overall contribution to the operation of the structures.

Thus, the claimed utility model makes it possible to ensure the seismic resistance of the metal frame of an industrial building under seismic loads up to 10 points.

Claims (3)

1. Reinforced metal bearing column, including a metal column, on which a concrete cage is installed at 1/6 of the height from the base of the metal column with a thickness of at least 3 cm in each direction from the outer contour of the metal column so that the concrete cage and the metal column together form a monolithic structure , and a composite clip is installed on the outer surface of the concrete cage, formed by transverse and longitudinal reinforcement of the concrete cage with carbon tape using an adhesive composition. 2. Reinforced metal bearing column according to claim 1, characterized in that the material of the concrete cage is concrete grade B15÷B20. 3. Reinforced metal bearing column according to claim 1, characterized in that the reinforcement of the concrete cage with carbon tape is carried out with the same step.