JPH0366465B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a method of constructing reinforced concrete structures such as beams, columns, walls, etc.

<Prior Art> As is well known, concrete structures of buildings and structures are provided with reinforcing materials such as reinforcing bars or steel frames inside to maintain sufficient strength. In addition, in a reinforced concrete structure having buried reinforcement reinforcing bars to which no stress is applied, cracks occur at approximately constant intervals even under normal service conditions. In addition, even in precast concrete members that have reinforcing reinforcing bars to which stress is applied, cracks occur in the same way as in the above-mentioned ordinary concrete when an earthquake or overload is applied.

As mentioned above, when cracks occur in a reinforced concrete structure, oxygen is released from the cracked area.
Outside air containing corrosive factors such as moisture and chlorine ions easily enters the inside of the concrete, and the reinforcing reinforcing bars gradually corrode. Further, even if no cracks occur, corrosive factors may penetrate through minute voids in the concrete surface and corrode reinforcing bars. In particular, sea breezes blow onto concrete pillars, beams, and road surfaces for railways and elevated roads installed near the coast, making it easy for harmful components such as chlorine ions and sulfate ions, as well as the aforementioned corrosive factors, to permeate through the surface.
Reinforcing materials such as reinforcing bars placed inside are at risk of corroding and collapsing.

<Problems to be Solved by the Invention> Therefore, in concrete structures, it is necessary to prevent the above-mentioned corrosive factors from penetrating into the interior. The structure must be able to withstand changes in climatic conditions, chemical conditions against acids and alkalis, mechanical conditions when the water content freezes and thaws, stress conditions when loads are applied, etc. Many concrete structures that can withstand such conditions have been proposed.

The most common method is to paint the concrete surface with anticorrosion paint. However, even if the surface of concrete is painted, its effectiveness in preventing corrosion is not only a problem, but also in concrete structures that crack under normal service conditions, painting cannot follow the cracks, so it is rarely used as a corrosion prevention measure. It has no meaning and is just surface decoration. Furthermore, there is the inconvenience of having to paint the concrete structure with anticorrosive paint after construction.

In addition, as another method to prevent corrosion of reinforcing materials,
There is also a concrete structure that uses a reinforcing material whose surface is coated with epoxy resin, etc., and this reinforcing material is buried in concrete, so that the epoxy resin on the surface has a corrosion-preventing effect.

However, with this method, apart from the effectiveness of the anti-corrosion effect, if the surface of the reinforcing material is damaged, the epoxy resin etc. will peel off, so it is not possible to weld the reinforcing materials together. Careful attention is required and there are problems with workability.

Furthermore, as a corrosion prevention method for reinforcing materials, there is a method of mixing special admixtures into cement to lower the diffusion coefficient of concrete and suppress the infiltration of corrosive factors from the outside air. However, even with this method, the admixture is extremely expensive, and if cracks occur in the concrete and reach the vicinity of the reinforcing material, there is little practical value because there is little anti-corrosion effect.

Polymer-impregnated concrete is said to be the most effective reinforcement material for corrosion protection.

This polymer-impregnated concrete is made by placing fresh concrete in a formwork, curing the concrete, drying it, dewatering it, impregnating the microscopic voids with a polymerizable monomer, and polymerizing the impregnated monomer by heating or irradiating it with radiation. , a polymer integrated with concrete.

Even with the polymer-impregnated concrete described above, there are some drawbacks. For example, polymerizable monomers are extremely expensive, so impregnating all concrete structures with the monomers would be extremely expensive and would require enormous costs if used in large-scale structures.

In addition, once the concrete structure is cured, it is dried and dehydrated to impregnate the microscopic voids with polymerizable monomers, so if the concrete structure becomes large-scale, it becomes virtually impossible to impregnate the monomer, making it easy to achieve high efficiency. Polymer-impregnated concrete cannot be made at low cost.

Moreover, even polymer-impregnated concrete has no anticorrosive effect if cracks occur.

<Means for Solving the Problems> The present invention has been proposed in view of the above-mentioned problems.The present invention has been proposed in view of the above-mentioned problems. A reinforcing plate with a width larger than that and with tensile or bending strength to the extent that it will not crack under normal service conditions is attached, and between adjacent reinforcing plates, there is a structure that has salt resistance, durability, alkali resistance, and elasticity. Cracks that occur in a reinforced concrete structure are caused to occur at the joint positions of reinforcing plates by interposing a sealing material having a material such as the like, and the cracks that occur are closed with the sealing material to prevent the cracks from being exposed to the outside. It provides a construction method for reinforced concrete structures.

Next, the principle of the present invention described above will be explained based on FIG. 4.

In the present invention described above, when polymer-impregnated concrete is used as the reinforcing plate, the tensile stress-strain curves of ordinary concrete and polymer-impregnated concrete are shown in FIG.

In Figure 4, the vertical axis is tensile stress (Kg/cm ² ),
The horizontal axis is strain (x10 ^-6 ), line a is the strain curve against tensile stress for ordinary concrete, and line b is the strain curve against tensile stress for polymer-impregnated concrete.

Generally, the breaking point A of ordinary concrete is a strain of 120×10 ^-6 when the tensile stress reaches 36 kg/cm ² .
The breaking point B of the polymer-impregnated concrete occurs when the strain reaches 300×10 ⁻⁶ when the tensile stress reaches 135 Kg/cm ² .

Therefore, even if ordinary concrete reaches the breaking point, polymer-impregnated concrete does not reach the breaking point, and even if ordinary concrete cracks, polymer-impregnated concrete does not crack because of its high tensile strength. In addition, even if tensile stress that is close to cracking the polymer-impregnated concrete is applied, since ordinary concrete and polymer-impregnated concrete are integrated, by using a sealing material with no strength between the reinforcing plates, ordinary concrete can be By concentrating cracks that occur on the sealing material, it is possible to prevent cracks from occurring on the reinforcing plate.

Therefore, as reinforcing plates, we used polymer-impregnated concrete plates, resin concrete plates, reinforced synthetic resin plates, and resin-coated plates that had a larger breaking point than ordinary concrete and completely blocked the infiltration of corrosive factors from the outside. A metal plate or the like can be used. Then, by connecting the reinforcing plates with a sealing material that blocks the infiltration of corrosive factors from the outside and remains elastic even after a long period of time, corrosive factors from the outside are prevented from infiltrating the concrete structure. be able to.

<Example> Examples of the present invention will be specifically described below.

1 to 3, the reinforced concrete structure 1 of the present invention has a structure in which a plurality of reinforcing bars 3 to which stress is not applied is embedded in the concrete 2 in the longitudinal direction, and is used for roads and railways. It is applied to beams, columns, floors, walls, etc.

On the outer surface of this reinforced concrete structure 1, reinforcing plates 4 having a width that is approximately equal to or slightly larger than the crack interval calculated in advance according to the structural aspect of the reinforced concrete structure 1 are attached.

The width of the reinforcing plate 4 is specified as described above, and this width is determined based on the reinforced concrete structure 1.

Generally, in reinforced concrete structures where stress is not applied to the reinforcing bars, the crack interval S _rn can be calculated as follows.

S _rn =2(C+S/10)+K ₁ K ₂ ·φ/ρ _r However, in the above formula, each symbol is as follows.

C: Reinforcing bar cover (cm) S: Reinforcing bar spacing (cm) However, when S<15φ, S=15φ φ: Reinforcing bar diameter (cm) K ₁ : A coefficient related to the adhesion characteristics of reinforcing bars, 0.4 for deformed reinforcing bars, round 0.8 K ₂ for reinforcing bars; coefficients related to the shape of strain distribution, 0.125 for triangular tensile strain distribution in bending, 0.25 for uniform strain distribution in pure tension ρ _r ; reinforcing bar ratio, ρ _r = A _s / A _{c ,ef} A _c,ef ; Concrete cross section where reinforcing bars act effectively for crack control (cm ² ) A _s ; Total reinforcing bar cross-sectional area within A _c,ef (cm ² ) As mentioned above, the structure of reinforced concrete structure 1 Since the intervals between cracks that occur vary depending on the condition, the width of the reinforcing plate 4 is determined by calculating from the reinforced concrete structure 1 designed in advance.

The reinforcing plate 4 described above has adhesion strength to concrete, and also has tensile or bending strength to the extent that it does not crack under normal use conditions.
Moreover, it uses plate materials that are salt-resistant, durable, and economical, such as concrete plates impregnated with polymers, high-strength synthetic resin plates, and metal plates whose surfaces are coated with resin. can.

The above-mentioned polymer-impregnated concrete board is produced by deaerating the microscopic voids of the concrete board that has been molded and cured as described above, filling the microscopic voids with a monomer made of a polymeric synthetic resin, and thermally polymerizing the monomer. Made of polymer, it has sufficient strength, durability, and chemical resistance. Therefore,
Ideal for use in the method of the invention.

The reinforcing plates 4 described above can be used in place of formwork when constructing the reinforced concrete structure 1, but the reinforcing plates 4 can also be attached to necessary parts of the outer surface after the reinforced concrete structure 1 is installed. good.

On the other hand, since the reinforcing plate 4 has a fixed width calculated in advance as described above, if the reinforced concrete structure 1 is sufficiently longer than the width of the reinforcing plate 4, the reinforced concrete structure can be constructed by making a plurality of reinforcing plates 4 adjacent to each other. It must be pasted on the outer surface of object 1. In this case, a sealing material 5 is interposed between adjacent reinforcing plates 4.

This sealing material 5 is air-impermeable, salt-resistant, durable,
The material is selected in consideration of alkali resistance, long-term elasticity, economic efficiency, etc., and for example, silicone resin can be used. If this sealing material 5 is simply interposed between adjacent reinforcing plates 4, there is a possibility that it will peel off or come off after a long period of time, so as shown in FIG. It is effective to form diagonal notches 4' and insert the sealing material 5 between the notches 4' of adjacent reinforcing plates 4.

In order to construct the reinforced concrete structure 1 according to the present invention, as described above, the reinforcing plate 4 is
may be assembled instead of a formwork, a sealing material 5 is inserted between adjacent reinforcing plates 4, reinforcing bars 3 are placed, and concrete 2 is poured and hardened. However, it is also possible to construct the reinforced concrete structure 1 in advance and then attach the reinforcing plate 4 to the outer surface with the sealing material 5 interposed therebetween.

<Effects of the Invention> Since the present invention has the above configuration, the constructed reinforced concrete structure has a reinforcing plate effective for corrosion prevention on the outer surface. Therefore, even if cracks occur in a reinforced concrete structure over a long period of time, most of the cracks will be concentrated at the joint positions of the reinforcing plates, and the open ends of the cracks will be closed with sealing material. Therefore, the outside air containing corrosive factors for reinforcing bars does not permeate through the concrete and reach the reinforcing bars, and the reinforcing bars do not corrode.

Further, since no special method is used during construction, construction can be carried out in the same manner as before, and as a corrosion prevention method, it is inexpensive and has high practical value.

[Brief explanation of drawings]

The drawings show one embodiment of the present invention; Fig. 1 is a partially cutaway front view when constructing a beam, Fig. 2 is a vertical side view of the same, and Fig. 3 is a partially enlarged view. The cross-sectional view and FIG. 4 are curve diagrams showing the relationship between tensile strength and strain of concrete.

Claims (1)

[Claims] 1. On the outer surface of a reinforced concrete structure, the width is approximately equal to or slightly wider than the crack interval calculated in advance according to the structural form of the reinforced concrete structure, and the width is such that no cracks will occur under normal service conditions. By attaching reinforcing plates with tension or bending strength, and interposing a sealing material with salt resistance, durability, alkali resistance, elasticity, etc. between adjacent reinforcing plates, cracks that occur in reinforced concrete structures can be fixed by joining the reinforcing plates. A method for constructing a reinforced concrete structure, characterized in that the cracks are caused at certain locations and the cracks are closed with a sealant to prevent the cracks from being exposed to the outside.