JPS6299561A - Reinforcement structure of reinforced concrete pillar - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] "Industrial Application Field" This invention applies to the use of reinforced concrete in existing building structures.
1-1 Reinforcement (This is related to 1 structure.

``Prior art'' As a method for reinforcing reinforced concrete columns, a method has already been proposed in which the outer periphery of the reinforced concrete column to be reinforced is wrapped in a ring shape with a steel plate (Special Publication No. 53
i3259). Its strength is reinforced concrete.
The outer periphery of 1-1 is covered with a steel plate, the gap between them is filled with mortar, and they are brought into close contact and integrated.

The confining effect produced by the steel plate 1 is expected to increase the compressive strength of reinforced concrete.

``Problems that the invention cannot solve'' However, the following problems were encountered with the reinforcing method of integrating reinforced concrete and cladding steel plates.

In other words, since the reinforced concrete and steel plates are closely integrated with each other, they behave as one. Therefore, if the steel plate and the reinforced concrete are distorted in the axial direction due to the axial compressive force acting on the reinforced concrete, the Mises yield condition may be exceeded or local buckling may occur. Therefore, due to the limited axial strength of the steel plate itself, it is no longer possible to expect a large confining effect from the steel plate, and the column must have a larger cross section than necessary.

This invention solves these problems.

``Means for Solving the Problems J'' In order to solve the above-mentioned problems, the present invention covers the outer periphery of a reinforced concrete column to be reinforced with a steel plate, and covers a portion of this steel plate in the axial direction generated in the body plate. A deformation absorbing portion is formed to absorb the deformation of the steel plate, a structural filler is filled between the steel plate and the reinforced concrete column, and the inner peripheral surface of the steel plate is unpounded to eliminate adhesion of the steel plate and the structural filler. It is characterized by having layers.

According to the reinforcing structure of the reinforced concrete column of this invention, when compressive force in the axial direction is applied, the reinforcement structure of the reinforced concrete column is caused by the unpond layer interposed between the reinforced concrete column and the steel plate covering the outer periphery of the column. , the steel plate and reinforced concrete column behave as separate bodies. A reinforced concrete column is compressed, and when it exceeds a predetermined strength, it produces axial strain and sudden radial transverse strain. However, compressive force in the axial direction acts on the steel plate, and the compressive force is absorbed by deformation of the deformation absorbing portion of the steel plate, so that almost no stress is generated in the axial direction of the steel plate. Then, the steel plate receives only the ring tension as a reaction that gives a confining effect to the reinforced concrete column, and the excellent confining effect sufficiently increases the strength of the reinforced concrete column.

"Embodiments" Examples of the present invention will be described below with reference to the drawings. 1st
1 and 2 illustrate one embodiment of the invention. In the figure, ■ indicates a reinforced concrete column that is to be reinforced in an existing building, and has a cylindrical shape. The outer periphery of this reinforced concrete column (hereinafter simply referred to as "column") l is covered with a steel plate 2 in a ring shape. This steel plate 2 is a member 2a divided into 'Fi numbers in the circumferential direction of the housing 1.
In this example, the member 2 is divided into two parts within a range of 180° around the axis of the column 1.
The bonding structure of a and 2a encapsulates the structure I.

Manoko, this steel plate 2 may be manufactured by joining members divided into a plurality of parts in the axial direction of the column l by welding or the like,
The upper end of the M plate 2 is in contact with the lower surface of the casing 3. In addition, this steel plate 2 has the following characteristics: In the layer of Note 1: near the center of the soil (the half-bending point of the moment), the steel plate 2 absorbs the axial deformation that occurs in the steel plate 2 due to expansion and contraction of that part. The position, number, and type of the deformation absorbing portions 2b provided with the deformation absorbing portions 2+ can be selected as appropriate.

As for the types, for example, a link-shaped gap is formed by cutting the edge of the steel plate 2 below -L, a ring-shaped gap is filled with a flexible material such as rubber, or a ring-shaped gap is formed on the inner or outer surface of the steel plate. 711! The steel plate 2 is cut to actively use that part as a weak part to make it easy to buckle, and a plurality of elongated holes extending in the circumferential direction are formed in the rope plate 2 to provide elasticity in the axial direction. In short, any material may be used as long as it has elasticity and local deformability, such as a lattice plate, and absorbs the axial deformation occurring in the entire steel plate 2 at that location.

The gap between the steel plate 2 and the column l is filled with mortar as a structural filler 1, and the mortar is interposed between the outer periphery of the column l and the steel plate 2. An unbond processing layer 5 is formed. This unbonding layer 5 serves to maintain a non-adherent state between the pillar I and the steel plate 2, and in this example, it is a paraffin layer. To form this unbonded layer 5, for example, paraffin is applied in advance to the inner peripheral surface of the steel plate 2 that covers the column I, and after the column I is covered with this steel plate 2, the gap between them is Fill with mortar.

In the column I reinforced with such a structure, the steel plate 2 is in a non-adhesive state due to the unbonding treatment layer 5,
The steel plate 2 and the housing 1 themselves can be moved relative to each other in the axial direction. Therefore, the compressive force in the axial direction of the column 1 acts directly on the steel plate 2 d-ql', the column I is distorted in the axial direction, and only the compressive stress in the axial direction is generated in the steel plate 2. In addition, in response to the compressive force exerted by the beam 3, the deformation absorbing portion 2b provided in the steel plate 2 deforms to absorb the compressive force, and almost no stress is generated in the axial direction of the steel slope 2. do not. On the other hand, the column I is compressed, and when it exceeds a predetermined strength, it causes strain in the axial direction and sharp transverse strain in the radial direction.

Therefore, the printing plate 2 receives only the ring tension as a reaction that imparts a confining effect to the column 1, and the plate itself is not affected by the axial strength so much that it can fully exert its confining effect. . Therefore, the column 1 is guaranteed to have a much higher yield strength than the conventional one without increasing its cross-sectional area.

FIG. 3 shows an example of a reinforcing structure for the quadrangular column 1.

In this example, as in the case of the above-mentioned example, Note 1 is covered with a steel plate 2 in a ring shape, a deformation absorbing part is formed in a part of this steel plate 2, and the column 1 and the steel plate 2 are A structural filler 4 is filled in the gap therebetween, and an unhont treated layer 5 is formed. By the way, the material for forming the unpond layer 5 is not limited to paraffin, but can be selected as appropriate. For example, grease, vaseline, or oil applied to the inner corner surface of the steel plate 2, or It can be formed by plastic coating the inner corner surface. Furthermore, in the above embodiment, mortar is used as the structural filler 44 to fill the gap between the reinforced concrete column 1 and the rope plate 2, but other materials such as concrete and various hydraulic materials are also used. You can fill it up. For example, as the structural filler 4, it is also possible to use soil, sand, metal powder, crow powder, plastic, viscosity, and the like.

"Effects of the Invention" As explained above, the reinforced concrete column reinforcement structure according to the present invention covers the outer periphery of the reinforced concrete column with a steel plate through an unpond layer, and provides a deformation absorbing part in a part of the steel plate. ('3), it is avoided that the compressive force in the axial direction of the reinforced concrete column acts directly on the steel plate, and the deformation absorbing part absorbs the compressive force that acts directly on the steel plate from the beam. This prevents axial stress from occurring in the steel plate, and the steel plate is not significantly affected by its own axial strength, allowing it to fully demonstrate its confining effect and increase the yield strength of reinforced concrete. , without increasing the cross-sectional area of the reinforced concrete column, it is possible to guarantee a much higher strength compared to conventional columns.

[Brief explanation of drawings]

Figures 1 and 2 show examples of reinforced concrete columns of the same nature with the reinforcing structure of the present invention. It is a cross-sectional view when a reinforcement structure is applied to a square column-shaped reinforced concrete. 1. Reinforced concrete, 2... Steel plate, 2b... Deformation absorption part, 4... Structural filler 5... Unhonto treatment layer.

Claims (1)

[Claims] The outer periphery of the reinforced concrete column to be reinforced is covered with a steel plate, a deformation absorbing part is formed in a part of the steel plate to absorb the axial deformation that occurs in the steel plate, and a structural filler is installed between the steel plate and the reinforced concrete column. A reinforcing structure for a reinforced concrete column, characterized in that an unbonding treatment layer is provided on the inner peripheral surface of the steel plate to eliminate adhesion of the steel plate and structural filler.