JP2002021338A - Method for reparing cross section of reinforced concrete structure, and filler used therein - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for repairing a cross section of a reinforced concrete structure capable of reducing chloride ion quantity at positions of reinforcements to be lower than a rust generating limit value by providing a permanent from on an outer surface where a part damaged by salt is chipped to a position where the reinforcement are not exposed, and filling filler in it for chloride ions left in existing concrete to be diffused to penetrate the filler. SOLUTION: A reinforced concrete structure damaged by salt is chipped to a position where reinforcement 2 are not exposed, a permanent form 3 to shield salt and water is installed corresponding to the shape of a cross section to be repaired, and filler 4 in which chloride ions left in the existing reinforced concrete structure is diffused to penetrate is filled between the permanent form 3 and the existing reinforced concrete structure.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for repairing a cross section of a reinforced concrete structure which has been damaged by salt and has penetrated into concrete from the surface thereof, and a filler used therein.

[0002]

2. Description of the Related Art Salt penetrates from the reinforced concrete surface into the interior due to salt damage, and when it reaches the reinforcing steel, the reinforcing steel is corroded and its function as a reinforced concrete structure is reduced. No.

[0003] Therefore, in the conventional section repairing method, an unhealthy portion is removed, rust removal and rust prevention treatment of a reinforcing bar is performed, and a concrete missing portion is backfilled. The performance required for the repair materials used there is protection performance,
There are three types of durability and construction performance, including adhesion, crack followability, deterioration / corrosion factor infiltration suppression performance, fresh properties, hardening properties, and the like.

In other words, the conventional method uses a dense and weather-resistant cross-section restoration material and further coats the surface to extend the life of the structure.

[0005] Generally, in the section repairing method for repairing a salt-damaged concrete structure, in order to prevent the recurrence of deterioration, it is premised that all concrete containing a harmful amount of chloride ion is removed. In addition, it has been required to hang up to the underside of the rebar.

[0006] In such a section repairing method, there is a problem that the time taken for demolishing the concrete increases in the construction, and as a result, the cost is increased, and the existing structure is removed. The problem is that the amount of destruction is increased, and there is a problem that mechanical uncertainty is left. Even if it is re-installed, there is a problem that if the chloride remains, it is corroded again.

[0007]

SUMMARY OF THE INVENTION According to the present invention, a permanent form for shielding salt and moisture is provided on the outer surface of a portion damaged by salt, which is suspended to a position where a reinforcing bar is not exposed, and a filler is filled. With the entry of new chloride ions blocked,
A method for repairing a cross section of a reinforced concrete structure capable of lowering the chloride ion amount at the position of a reinforcing bar below a rust limit value by diffusing and penetrating chloride ions remaining in existing concrete toward a filler, and Provide the filler used.

[0008]

SUMMARY OF THE INVENTION According to the present invention, a salt-damaged reinforced concrete structure is suspended to a position where the reinforcing bar is not exposed, and a permanent form for blocking salt and moisture is installed in accordance with the recovery sectional shape. The method comprises a method for repairing a cross section of a reinforced concrete structure, which comprises filling a filler between the permanent form and the existing reinforced concrete structure with a filler for diffusing and infiltrating chloride ions left in the existing reinforced concrete structure. In the method, cement, sand,
The method for repairing a cross section of a reinforced concrete structure using a filler containing water, a rust inhibitor, an expanding agent, and a bleeding inhibitor, and the method for repairing a cross section of a reinforced concrete structure according to the present invention further comprises the above-mentioned water-to-cement ratio of the filler. The above-mentioned filler is 400 or more after 6 hours after the above-mentioned filler is used for a salt accelerated permeability test method (AASHTO (U.S.A.
0 coulombs or more, and the use of ordinary cement as the cement of the filler.

Further, the filler used in the method for repairing a cross section of a reinforced concrete structure of the present invention is cement, cement,
The filler containing sand, water, a rust inhibitor, a swelling agent, a bleeding inhibitor, and a filler used in the method of the present invention has a water-cement ratio of 55 or more, and has a salt promoting property based on an electric method. After 6 hours, the permeability test method (AASHTO (U.S.A.
000 coulombs or more, and use of ordinary cement for cement.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A method for repairing a cross section of a reinforced concrete structure and an embodiment of a filler used in the present invention will be described below with reference to the drawings. First, the inside of concrete 1 shown in FIG. If a reinforced concrete structure reinforced with
The structure is suspended to the position of the dashed line B where the reinforcing bar 2 is not exposed.

Next, as shown in FIG. 2, after installing a permanent mold 3 made of FRP or the like for blocking salt and moisture according to the sectional shape to be restored, the permanent mold 3 and the permanent mold 3 are suspended. The filler 4 is filled between the existing concrete and the reinforced concrete structure 1 as shown in FIG. FIG. 12 shows a cross-sectional view when applied to a slab and a beam.

As the filler 4 to be filled, a filler which diffuses and infiltrates chloride ions remaining in the existing reinforced concrete structure is used. As the filler 4, cement, sand, water, rust inhibitor , A swelling agent, a bleeding inhibitor may be used, and limestone fine powder may be used to suppress bleeding. Countermeasures may be taken.

The water-cement ratio of the filler 4 is 55
The above is preferable in terms of facilitating permeation of chloride ions, and the filler 4 is further subjected to a salt-accelerated permeability test method (AASHTO (American Jonju Road Traffic Officers Association) T- 227) Six hours later, 400
It is also preferable to use one having 0 coulomb or more.
This generally reduces the permeability in general, from 1000 to 20
This is because the diffusion coefficient can be increased by setting the temperature to 4000 coulombs or more, as compared with the case of 00 coulombs or less, and the chloride ions can be easily permeated.

Further, as the cement of the filler 4,
It is also desirable to use ordinary Portland cement rather than blast furnace cement, which can facilitate chloride ion penetration. In addition, the basic physical properties of the filler 4 include a compression strength of 30 N / mm ² or more in 28 days and a non-shrinkage of 2.0 × 10 ⁻³ or less in 3 months. It is preferable to minimize the change in volume.

Next, regarding the selection of the above-mentioned stripping depth x, the target year for reducing the chloride ion amount below the rust limit value at the position of the reinforcing bar 2 of the structure is set at 1 to 2 years. Since it is a competition with the corrosion of the reinforcing steel 2, it is considered that the earlier the target year is better, depending on the reinforced concrete structure.

For this purpose, the amount of chloride ions in the present situation is measured, and the diffusion coefficient and the amount of chloride ions of the filler 4 and the already described concrete, which are cross-section restoration materials, are set, and the following diffusion simulation is performed. The depth x of the drop that satisfies the target years is selected.

Further, as for the permanent mold 3 having a surface coating, since the filler 4 as the cross-section restoration material has increased permeability, it is assumed that deterioration from the outside and penetration of corrosion factors are completely blocked. Although it can be dealt with by applying a surface coating used for countermeasures against salt damage, the surface is covered by a permanent form method with FRP having excellent weather resistance.

Next, using the chloride content data of the existing reinforced concrete structure, the diffusion of chloride is changed by the one-dimensional difference method by changing the stripping depth x and the diffusion coefficient of the filler 4 which is a cross section restoration material. The result of the simulation will be described. FIG. 4 shows a model of the one-dimensional difference method.

This diffusion and penetration prediction is carried out by repairing by a cross section repair method, coating the surface with a permanent mold 3 made of FRP,
It is assumed that chloride ions supplied from the surface are shut off, and the salt that has already penetrated and remains diffuses in concentration.

The diffusion coefficient of chloride ions in the existing concrete 1 and the filler 4 of the section repair material is set, and the filler 4
The diffusion penetration of chloride ions in the direction of the cross-section restoration material was estimated using the thickness of the steel and the number of years elapsed after repair as variables.

The equation of the one-dimensional difference method is shown below.

[0022]

(Equation 1) Here, C (x _i, t): depth x _i from the concrete surface
Chloride ion amount (%) after surface treatment (time t (sec)) at (cm) position (however, t = 0 when surface treatment is performed) Δx: In the depth direction from the concrete surface in difference calculation Division width (cm) D _D : Design value of diffusion coefficient of chloride ion (cm ² / se
c)

FIGS. 5 and 6 and FIGS. 7 and 8 show some examples of the chloride ion diffusion simulation. 5 and 6 of 2.3 × 10 ⁻⁹ assuming the diffusion coefficient of the restoration material, and FIGS. 7 and ⁸ of 2.3 × 10 ⁻⁸ assuming the diffusion coefficient of the filler 4 which is a new cross-section restoration material. In this case, repair was performed by changing the hanging depth.

The position of the reinforcing bar 2 is 9.0 cm. The effect is naturally larger as the hanging depth (8.0 cm) indicated by oblique lines is larger, but the diffusion coefficient is larger as shown in FIGS. 7 and 8. It can be seen that the chloride ion diffuses and penetrates into the filler 4 side, and the distribution becomes smoother at an early stage. It is necessary to select a hanging depth that can reduce the chloride ion amount at the position of the reinforcing bar 2 below the rust limit value in one to two years for each structure.

The concept of diffusion and infiltration of chloride ions after repair using the filler 4 according to the method for repairing a section of a reinforced concrete structure as described above will be described with reference to FIGS. 9, 10 and 11. First, FIG. In this case, the rebar 2 is not exposed, and the portion shown by oblique lines is hung up, but the chloride remains in this state.

Next, in FIG. 10, a permanent form 3 for blocking salt and moisture is provided as a surface coating, and the infiltration of salt is blocked, and a cross section restoration material is provided between the permanent form 3 and the existing concrete 1. The cross section is repaired by filling the filling material 4 which is

As a result, in FIG. 11, the remaining chloride diffuses and penetrates to form a smooth distribution, and the amount of salt at the reinforcing bar position falls below the rust limit as time passes.

[0028]

According to the method for repairing a cross section of the present invention described above, an existing concrete structure containing chloride ions is hung without exposing a reinforcing bar, and then compared with a conventional cross section repair material. As a result, a new cross-section restoration material with low solidity is filled as a filler, and the surface is coated with a permanent form made of FRP, etc. to completely prevent external deterioration and corrosion factor penetration. By shutting off, the chloride ions remaining in the existing concrete are diffused and permeated toward the new cross-section restoration material, thereby reducing the chloride ion amount at the reinforcing bar position to below the rust limit value.

That is, according to the present invention, by providing a permanent mold for blocking salt and moisture, the intrusion of new chloride ions is blocked, and the existing concrete is filled with chloride ions remaining. By diffusing and infiltrating into the material, the amount of chloride ions at the location of the reinforcing bar can be reduced to below the rust limit. Repairs can be made.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional side view of a portion of a reinforced concrete structure damaged by salt damage in an embodiment of the cross-section repair method of the present invention.

FIG. 2 is a schematic side sectional view of FIG. 1 in which a permanent form is installed on a suspended surface.

FIG. 3 is a schematic side sectional view in which a filler as a cross section repairing material is filled between the existing concrete and the permanent form shown in FIG. 2;

FIG. 4 is a model diagram in which a chloride diffusion simulation is performed by a one-dimensional difference method using the chloride content data of an existing reinforced concrete structure and changing the removal depth and the diffusion coefficient of a filler.

FIG. 5 shows an example of the chloride ion diffusion simulation of FIG. 4 for a member thickness of 4 cm, a diffusion coefficient of 2.3 × 10 ^-9.
FIG.

FIG. 6 shows a diffusion coefficient of 2.3 × for a member thickness of 8 cm in FIG.
It is a chart of the example of ^10-9 .

FIG. 7 shows a diffusion coefficient of 2.3 × in the case of a member thickness of 4 cm in FIG.
It is a chart of an example of 10 ^-8 .

FIG. 8 shows a diffusion coefficient of 2.3 × for a member thickness of 8 cm in FIG.
It is a chart of an example of 10 ^-8 .

FIG. 9 is a conceptual diagram of diffusion and penetration of chloride ions in a state where a salt-damaged portion at the time of repairing a cross section by the method of the present invention has been removed.

FIG. 10 is a conceptual diagram showing diffusion and penetration of chloride ions in which a permanent mold is installed in the state of FIG. 9 and a filler is filled.

FIG. 11 is a conceptual diagram showing diffusion and penetration of chloride ions in which chloride remaining in the state of FIG. 10 diffuses and penetrates.

FIG. 12 is a sectional view when the method of the present invention is applied to a slab and a beam.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Concrete 2 Rebar 3 Permanent formwork 4 Filler

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Akira Inukai 1-5-20 Kaigan, Minato-ku, Tokyo Tokyo Gas Co., Ltd. (72) Inventor Koichi Seki 1-5-20 Kaigan, Minato-ku, Tokyo Tokyo Gas Inside (72) Inventor Atsuro Moritabu 5 Yonbancho, Chiyoda-ku, Tokyo Toa Construction Industry Co., Ltd. (72) Inventor Michio Muramatsu 5 Yonbancho, Chiyoda-ku, Tokyo Toa Construction Industry F-term (Reference) 2E176 AA01 BB01 4G028 DA01 DB01 DC01

Claims (9)

[Claims] 1. A reinforced concrete structure damaged by salt is suspended to a position where the reinforcing bar is not exposed, and a permanent form for blocking salt and moisture is installed in accordance with the restored cross-sectional shape, and is left on the existing reinforced concrete structure. A method for repairing a cross section of a reinforced concrete structure, comprising filling a filler between the permanent form and the existing reinforced concrete structure with a filler for diffusing and infiltrating chloride ions. 2. The method for repairing a cross section of a reinforced concrete structure according to claim 1, wherein a filler containing cement, sand, water, a rust inhibitor, a swelling agent, and a bleeding inhibitor is used. 3. The method for repairing a cross-section of a reinforced concrete structure according to claim 1, wherein the water cement ratio of the filler is 55 or more. 4. The method according to claim 1, wherein the filler is 4,000 coulombs or more after 6 hours from a test method for promoting salt penetration based on an electric method (AASHTO (American Jeonju Road Traffic Administration Association) T-227). 4. The method for repairing a cross section of a reinforced concrete structure according to 3. 5. The method for repairing a cross-section of a reinforced concrete structure according to claim 1, wherein ordinary Portland cement is used as the filler cement. 6. A filler for repairing a cross section of a reinforced concrete structure, which comprises cement, sand, water, a rust inhibitor, a swelling agent, and a bleeding inhibitor. 7. A water-cement ratio of 55 or more.
A filler for use in repairing the cross-section of the reinforced concrete structure described. 8. A salt penetration promotion test method based on an electrical method (AASHTO (American Jeonju Road Traffic Administration Association)
T-227) The filler for use in repairing a cross section of a reinforced concrete structure according to claim 6 or 7, wherein after 6 hours, 4000 coulombs or more are used. 9. The filler for use in repairing a cross section of a reinforced concrete structure according to claim 6, wherein ordinary Portland cement is used as the cement.