JPH0753964B2 - Concrete structure - Google Patents

Description

TECHNICAL FIELD The present invention relates to a concrete structure such as a concrete floor slab installed on a bridge or the like.

(B) Conventional technology Conventionally, the floor slab A, which is one of the concrete structures, is
As shown in the figure, it consists of a slab a and a beam part b. When constructing the form c, at the same time assembling the form c, at the same time, reinforcing reinforcing bars d and e are arranged vertically, and then concrete is placed inside the form c. Is done by flowing into.

In the floor slab A, the compression side cross section g is formed at a portion above the neutral axis f of the beam b, and the tension side cross section h is formed at a portion below the neutral axis f. The cross sections g and h bear the compressive force and tensile force generated when the load W is applied to the floor slab A.

(C) Problems to be Solved by the Invention However, in the structure of the floor slab A, the tensile force applied to the floor slab A is given only by the lower reinforcing bar e, and the tensile side cross section h is formed. The concrete used does not exhibit any resistance to tensile force. Therefore, the floor slab A is
It was not possible to have sufficient resistance to tensile force.

Further, the floor slab A has a disadvantage that the weight is excessively increased by an amount corresponding to the tension side cross-section portion h.

It is an object of the present invention to provide a concrete structure capable of solving the problems of the conventional art.

(D) Means for Solving the Problems The present invention provides a concrete structure having a cross section that forms a compression side cross section and a tension side cross section at the upper and lower portions with the neutral axis as a boundary line. The side section,
Emulsion admixture prepared by mixing a composite polymer emulsion containing carboxy-modified styrene and cyclohexyl methacrylate as the main component with a main agent containing silicon oxide, calcium oxide, iron oxide as the main component or concrete containing cement, sand or gravel as the main component. The present invention relates to a concrete structure characterized in that it is formed of concrete, and at least the reinforcing bar embedded in the cross section on the tensile side is formed of a rod-shaped body made of wholly aromatic polyamide fiber.

(E) Action and effect Since the tensile side cross section formed in the lower part of the neutral shaft is made of concrete composed of the composite polymer emulsion and the main agent or cement, not only the lower reinforcing bar embedded in the tensile side cross section, The concrete itself also has sufficient tensile strength, and the tensile strength of the concrete structure can be remarkably increased.

Further, since such concrete has a strong adhesion strength to the lower reinforcing bar, the concrete and the lower reinforcing bar integrally resist the tensile force applied to the concrete structure, and the concrete structure is prevented from being broken or cracked. It is possible to reliably prevent the occurrence.

Since the lower reinforcing bar is a rod-shaped body made of wholly aromatic polyamide fiber, the tensile strength is significantly higher than that of the reinforcing bar,
The strength of the concrete structure can be improved also in this respect.

Since the lower reinforcing bar is a rod-shaped body made of wholly aromatic polyamide fiber, it has a low specific gravity, can be easily constructed and buried, and can enhance the construction efficiency.

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

As shown in FIG. 1, the floor slab 1 that constitutes a part of the bridge is
The slab 2 and the beam portion 3 are formed. Further, the beam portion 3 forms a compression side cross-section portion 5 in a portion above the neutral shaft 4 and a tension side cross-section portion in a portion below the neutral shaft 4. 6 is formed. The compression-side cross-section 5 and the tension-side cross-section 6 each have a plurality of reinforcing bars 7, 8.

Then, in such a configuration, the compression-side cross-section 5 and the tension-side cross-section 6 respectively bear the compressive force and the tensile force generated when the load W is applied to the floor slab 1.

The present invention substantially includes, in the above configuration, at least:
It is characterized in that the tensile side cross-section portion 6 is made of concrete by mixing a composite polymer emulsion containing carboxy-modified styrene and cyclohexyl methacrylate as main components with a main agent such as white cement.

Here, the composite polymer emulsion refers to, for example, those disclosed in Japanese Patent Application Nos. 57-33499 and 59-92112, and such a composite polymer emulsion has the following component constitution.

Carboxy-modified styrene butadiene 45% Cyclohexyl methacrylate 24% Methanol 5% Fatty acid soda soap 1% Water 25% Further, the main agent may have the following composition.

White cement 28.0% Quartz sand (SiO ₂ ) 71.6% Iron powder (Fe ₃ O ₄ ) 0.2% Zinc white (ZnO) 0.1% Titanium white (TiO ₂ ) 0.1% Concrete consisting of such complex polymer emulsion and base compound was excellent. It has physical and chemical properties, and the following effects can be obtained by forming the tension side cross-section 6 of the floor slab 1 from such concrete.

Since the concrete has sufficient adhesion or affinity to concrete of other components or compositions, it is also integrally and firmly connected to ordinary concrete forming the compression side cross-section portion 5 of the floor slab 1.

Since concrete has a sufficient tensile strength and also has a strong adhesive force to the lower reinforcing bar 8, it can cooperate with and resist the tensile force applied to the floor slab 1. It is possible to completely prevent the destruction and crack generation.

Further, the present invention is also characterized in that at least the lower reinforcing bar 8 is formed of a rod-shaped body of wholly aromatic polyamide fiber (aramid).

Here, the wholly aromatic polyamide fiber refers to a polyamide-based fiber such as aramid having high tensile strength, high heat resistance, and high bending resistance, and commercially available ones can be used.

By using the reinforcing bar 8 as such a material, the tensile strength of the tensile side cross-section portion 4 can be further improved. Also,
Since the specific gravity of wholly aromatic polyamide fiber is small,
The assembly and burial work of can be easily performed.

Note that a large number of rod-shaped members made of wholly aromatic polyamide fibers can be used as the reinforcing bar 8 as they are, but since such rod-shaped members generally lack rigidity, at least on the surface thereof, preferably up to the inside thereof, It is desirable that the mixed material of the composite polymer emulsion having each of the above component configurations and the main agent is applied and solidified in advance by a method such as dobbing. Also, by doing this, the rigidity and hardness of the reinforcing bar can be increased,
It can be handled in the same manner as ordinary rebar and the like, and the adhesive force between concrete and the reinforcing bar 8 can be further enhanced.

The upper reinforcing bar 7 may be either a normal reinforcing bar or a rod-shaped body made of wholly aromatic polyamide fiber.

Next, a procedure for constructing the concrete structure will be described.

First, as shown in FIG. 1, the form 9 is assembled and the upper and lower reinforcing bars 7 and 8 are arranged.

Then, the concrete composed of the composite polymer emulsion according to the present invention and the main agent is filled inside the mold 9 corresponding to the tensile side cross-section 6. In this case, the mixing ratio of concrete is preferably the ratio of the main agent 5 to the composite polymer emulsion 1.

After filling the concrete up to the neutral shaft 4, concrete consisting of cement, sand, and gravel having a normal composition is continuously filled in the formwork 9, and the compression side cross-section 5 of the beam 3 and the slab 2 are filled. Form.

Then, after a certain period of curing, the form 9 is removed.

In the above examples, the emulsion-mixed concrete forming the tensile side cross-section 6 was formed by the composite polymer emulsion and the main agent. However, the composite polymer emulsion was mixed with ordinary concrete composed of cement, sand, and gravel. Can also be formed.

Further, in the emulsion-mixed concrete, it is possible to further mix a reinforcing base material composed of a mesh body such as glass fiber, carbon fiber, wholly aromatic polyamide fiber or short fiber to increase the tensile strength.

[Brief description of drawings]

FIG. 1 is a perspective view of a concrete structure according to the present invention, and FIG. 2 is a perspective view of a conventional concrete structure. In the figure, 1: Floor slab 2: Slab 3: Beam section 4: Neutral axis 5: Compression side section section 6: Tensile side section section 7: Upper reinforcing bar 8: Lower reinforcing bar 9: Form W: Load

Claims (1)

[Claims] 1. A concrete structure having cross sections forming a compression side cross section and a tension side cross section at the upper and lower portions with the neutral axis as a boundary line, and the tensile side cross section is carboxy-modified styrene, methacryl A composite polymer emulsion containing cyclohexyl acid as a main component is formed from an emulsion-mixed concrete produced by mixing silicon oxide, calcium oxide, a main agent containing iron oxide as a main component or cement, sand, or concrete containing gravel as a main component, Furthermore, at least the reinforcing bar embedded in the tensile side cross-section is formed by a rod-shaped body made of wholly aromatic polyamide fiber.