JP2766854B2 - Concrete structure - Google Patents

Description

The present invention relates to a concrete structure such as a civil engineering structure or a building structure.

(B) Conventional technology Conventionally, in concrete structures in the fields of civil engineering and construction, there is a concrete structure provided with an earthquake-resistant wall at a main part of the structure. Such a seismic wall is usually made of a thick concrete plate with reinforcing steel bars and reinforcing steel frames inside, and is fitted in a rectangular space formed by combining columns extending vertically and beams extending horizontally. By mounting, it is attached to a concrete structure.

In addition, with such a configuration,
Even in the case where horizontal, horizontal, front-rear or vertical seismic force is applied, the collapse of the concrete structure can be prevented in cooperation with the columns and beams.

(C) Problems to be solved by the invention However, such earthquake-resistant walls have problems in toughness and flexibility, such as a marked decrease in proof stress after the maximum stress, and the earthquake-resistant walls cannot follow the deformation of beams and columns. , Causing cracks and, consequently, severely diminishing its function as a shear wall.

An object of the present invention is to provide a concrete structure that can solve the above problems.

(D) Means for Solving the Problems The present invention relates to a concrete structure having an earthquake-resistant wall in a main part, at least a part of the earthquake-resistant wall is replaced with a reinforcing steel bar or a reinforcing steel frame having an adhesive layer formed on the surface. Is formed by a reinforcing concrete part embedded with reinforcement, and the reinforcing concrete part and the adhesive layer are formed by mixing a composite polymer emulsion containing an acrylate ester copolymer as a main component with silicon oxide, calcium oxide, and iron oxide. It is produced by mixing with the main component as the main component, or concrete containing cement, sand or gravel as the main component, and the mixing ratio of the composite polymer emulsion in the adhesive layer with respect to the main component or concrete is determined as the composite polymer emulsion in the concrete portion for reinforcement. The mixing ratio is higher than the mixing ratio to the main agent or concrete. It relates to a cleat structure.

The present invention is also characterized in that the reinforcing concrete portion is formed around the earthquake-resistant wall, and that the entire earthquake-resistant wall is formed as the reinforcing concrete portion.

(E) Function and effect With the above configuration, the present invention has the following function and effect.

At least a part of the earthquake-resistant wall is formed by a reinforcing steel having an adhesive layer formed on its surface or a reinforcing concrete part having reinforcing steel laid therein, and the reinforcing concrete part and the adhesive layer are formed by acrylic ester. A composite polymer emulsion containing a copolymer as a main component is formed by mixing it with a main component containing silicon oxide, calcium oxide, or iron oxide as a main component, or concrete containing cement, sand, or gravel as a main component. By setting the mixing ratio of the composite polymer emulsion to the main agent or concrete in the above to be higher than the mixing ratio of the composite polymer emulsion to the main agent or concrete in the reinforcing concrete portion, it is possible to impart toughness and flexibility to the earthquake-resistant wall. In addition, the adhesive strength between the concrete part and the reinforcing steel It has been able to further concrete structure having reliability.

Therefore, even if the concrete structure consisting of columns and beams is displaced by seismic force or other loads, the earthquake-resistant wall can easily follow its movement, preventing cracking and collapse of the earthquake-resistant wall. , That is, the function of preventing the concrete structure from collapsing can be maintained for many months.

(F) Embodiment Hereinafter, the present invention will be described in detail based on an embodiment shown in the accompanying drawings.

FIGS. 1 and 2 show a high-rise building A as one form of concrete structure, the basic structure of which comprises a number of vertical columns 10 and a number of horizontal columns. And the beam 11.

Further, as shown in FIG. 2, the high-rise building A is provided with an earthquake-resistant wall structure B at a main portion thereof (in the present embodiment, at a central portion thereof).

As shown in FIGS. 2 to 4, the earthquake-resistant wall structure B includes four pillars 10 erected at four corners at the center of a high-rise building A, and upper ends of the pillars 10 and lower ends thereof. Four beams extending horizontally to connect each other and forming a rectangular frame in plan view
11 and four earthquake-resistant walls 12 fitted into the space defined by the left and right or front and rear columns 10, 10 and the upper and lower beams 11, 11, and integrated with the columns 10, 10 and the beams 11, 11 .

In the above configuration, in the present embodiment, as shown in FIG. 3, at least a part of the earthquake-resistant wall 12 is formed by a reinforcing concrete part C, and the reinforcing concrete part C is
A composite polymer emulsion mainly composed of an acrylate copolymer is formed by mixing silicon oxide, calcium oxide, a main ingredient mainly composed of iron oxide or cement, sand, concrete mainly composed of gravel, and It is characterized in that it is formed by arranging reinforcing steel or reinforcing steel inside.

That is, in FIG. 3, the earthquake-resistant wall 12 forms a reinforcing concrete portion C around a central portion D made of a normal concrete having a rectangular shape.

However, the reinforcing concrete portion C may be the whole of the shear wall 12.

Here, the composite polymer emulsion which is a composition component forming the concrete part C for reinforcement is described in, for example,
57-33499 and Japanese Patent Application No. 59-92112.

Two examples of the composition of such a composite polymer emulsion are as follows: Example 1) (weight) carboxy-modified styrene butadiene 13% cyclohexyl styrene methacrylate copolymer 56% fatty acid soda soap 1% water 30% Example 2) (weight) carboxy Modified styrene butadiene 13% Styrene 28% Cyclohexyl methacrylate 28% Fatty acid soda soap 1% Water 30% In addition, the main component to be mixed with the composite polymer emulsion may have the following components.

(Wt%) White cement 28.0% Silica sand (SiO ₂ ) 71.0% Iron powder (Fe ₂ O ₃ ) 0.2% Zinc white (ZnO) 0.1% Titanium white (TiO ₂ ) 0.1% Glycine and other 0.6% component weight ratio of _{(weight%) CaO 65.4% SiO 2 23.1} % iron powder _{(Fe 2 O 3) 0.2%} Igloss 2.7% insol 0.2% Al 2 O 3 4.3% MgO 0.6% SO 3 2.8% other 0.7% Yes, Portland cement can be used in place of this white cement.

In addition, the mixing ratio of the main agent and the composite polymer emulsion forming the reinforcing concrete portion C is preferably 6 to 20: 1.

The reinforcing concrete portion C composed of the composite polymer emulsion and the main component has excellent physical and chemical properties, and can obtain the following effects.

That is, a composite polymer emulsion containing an acrylic ester copolymer having high adhesive strength, tensile strength, and bending strength as a main component is mixed with a base material or concrete, and the earthquake-resistant wall is mixed.
Since the reinforcing concrete portion C, which is a part of the concrete wall 12, is formed, the tough wall 12 can be given sufficient toughness and flexibility.

Therefore, even if the high-rise building A composed of the pillars 10 and the beams 11 such as concrete members is displaced by seismic force or other load, the seismic wall 12 easily follows the movement, and Can be absorbed to prevent the earthquake-resistant wall 12 from cracking, which can prevent a concrete structure such as a high-rise building A from collapsing for many months.

FIG. 5 shows a modified example according to this embodiment. As shown in FIG. 5, the columns 10 and the beams 11 surrounding the earthquake-resistant wall 12 are shown.
Similarly, the corner E is formed by mixing a composite polymer emulsion mainly composed of an acrylate ester copolymer having high adhesive strength, tensile strength and bending strength in a base material or concrete.

Therefore, the columns 10 and the beams 11 surrounding the earthquake-resistant wall 12 can also have sufficient toughness and flexibility similarly to the above-mentioned earthquake-resistant wall 12, and in cooperation with the earthquake-resistant wall 12, further increase the height of the high-rise building A or the like. Of the concrete structure can be prevented.

FIG. 6 shows the cross-sectional structure of the earthquake-resistant wall 12, and FIGS. 7 and 8 show the cross-sectional structures of the columns 10 and the beams 11.

That is, the reinforcing wall b and the reinforcing steel c are embedded in the concrete body a of the earthquake-resistant wall 12, the column 10 and the beam 11, and carboxy-modified styrene-butadiene and cyclohexyl methacrylate are provided on the surface of the reinforcing reinforcing b and the reinforcing steel c. An adhesive layer d is formed by mixing a composite polymer emulsion mainly composed of silicon oxide, calcium oxide, and iron oxide as a main component.

It is preferable that the ratio between the main agent forming the concrete adhesive layer d and the composite polymer emulsion is 3 to 5: 1.

The adhesive layer d composed of the composite polymer emulsion and the main agent has excellent physical and chemical properties, and can obtain the following effects.

That is, the concrete body a and the reinforcing bar b or the reinforcing steel frame c
Can be strengthened, and in cooperation with the shear walls 12, columns 10 and beams 11 containing the composite polymer emulsion described above,
Further, cracking of the earthquake-resistant wall 12 can be prevented, and collapse of the concrete structure can be prevented.

In addition, strength comparison tests were performed on concrete mixed with a composite polymer emulsion forming the earthquake-resistant wall 12 according to the present invention and plain concrete without the addition of the composite polymer emulsion. The results are shown below.

In addition, the mixing | blending of the concrete used here is as showing in Table 1.

(Test results) Table 2 shows the test results. The test material age was 4 weeks in each case.

In addition, the results of the test on the elongation ability under bending stress show that when the magnitude of the tensile strain when the bending load suddenly decreases is defined as the
In contrast to the range of μm to 200 μm, the concrete according to the present invention has a length of 700 μm to 1000 μm, which indicates a greater elongation capacity than concrete.

(Discussion) From the test results, the following has been found.

The earthquake-resistant wall made of concrete mixed with the composite polymer emulsion according to the present invention is rich in flexibility, adhesion performance is increased, and bending strength and tensile strength are improved, and concrete such as concrete members caused by seismic force and other loads is improved. It is possible to follow the displacement of the structure,
It has also become possible to prevent cracks in the earthquake-resistant wall.

[Brief description of the drawings]

FIG. 1 is a front view of a high-rise building which is a concrete example of the concrete structure according to the present invention, FIG. 2 is an enlarged sectional view taken along the line II of FIG. 1, and FIG. Arrow view by line,
FIG. 4 is a perspective view of a main part of the earthquake-resistant wall, FIG. 5 is an explanatory view of a modification of the concrete structure, and FIGS. 6 to 8 are explanatory views of the sectional structure of the earthquake-resistant wall, columns and beams. In the figure, 10: pillar, 11: beam 12: earthquake-resistant wall, A: high-rise building B: earthquake-resistant wall structure C: concrete part for reinforcement

Claims (3)

(57) [Claims] In a concrete structure having an earthquake-resistant wall in a main part, at least a part of the earthquake-resistant wall is provided by a reinforcing steel part having an adhesive layer formed on a surface thereof or a reinforcing concrete part in which a reinforcing steel frame is laid and embedded. In addition to forming the reinforcing concrete part and the adhesive layer, a composite polymer emulsion containing an acrylate copolymer as a main component is converted into a main agent containing silicon oxide, calcium oxide, and iron oxide as a main component, cement, or sand. It is produced by mixing with concrete mainly composed of gravel, and the mixing ratio of the composite polymer emulsion to the main agent or concrete in the adhesive layer is higher than the mixing ratio to the main agent or concrete of the reinforcing concrete portion. A concrete structure characterized by the following. 2. The concrete structure according to claim 1, wherein the reinforcing concrete portion is formed around the shear wall. 3. The concrete structure according to claim 1, wherein all of the earthquake-resistant walls are concrete portions for reinforcement.