JP2019214863A - Protection method of reinforced concrete structure - Google Patents

Abstract

To provide a protection method of a reinforced concrete structure capable of forming a protective layer on the reinforced concrete structure while maintaining an existing finishing material.SOLUTION: The protection method of the reinforced concrete structure comprising a reinforced concrete part in which a reinforcing bar is disposed inside concrete and a finishing part provided in the reinforced concrete part, includes: an injection hole forming process of providing an injection hole which penetrates the finishing part and reaches the reinforced concrete part; and a protective layer forming process of forming a protective layer on the reinforced concrete part by injecting an anti-water-absorbing agent into the injection hole.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for protecting a reinforced concrete structure.

  In a reinforced concrete structure in which a reinforcing bar is disposed inside concrete, the strength of the entire reinforced concrete structure may decrease due to deterioration of the reinforcing bar. Such deterioration of the reinforcing bars is caused by corrosion of the reinforcing bars as a result of the deterioration factors such as moisture entering the inside of the reinforced concrete structure and reacting the reinforcing bars with the deterioration factors. Therefore, it has been practiced to apply a water-absorbing agent to a reinforced concrete structure to form a protective layer, thereby suppressing corrosion of the reinforcing steel. As a method of suppressing such corrosion of a reinforcing bar, for example, Patent Literature 1 discloses that a protective layer is formed by applying an internal penetration type water absorbing agent (rust inhibitor) to the surface of a reinforced concrete structure. It is disclosed that corrosion of a reinforcing bar inside a structure is suppressed.

JP 2006-144313 A

  Patent Literature 1 describes that after forming a protective layer on a reinforced concrete structure, surface finishing such as painting can be performed. However, when an attempt is made to form a protective layer on a reinforced concrete structure having a finishing material already applied to its surface, it is necessary to temporarily remove such an existing finishing material. Then, it is necessary to apply a finishing material again after the formation of the protective layer, and there has been a problem of an increase in cost and construction period. In addition, when a water-absorbing agent is applied to the surface of the existing finishing material, the appearance of the existing finishing material, such as color and surface shape, may be changed.

  The present invention provides a method for forming a protective layer on a reinforced concrete structure while maintaining an existing finishing material, or when the construction cannot be performed from the back side of the reinforced concrete structure. It is an object of the present invention to provide a method for protecting a reinforced concrete structure capable of forming a protective layer on the outdoor side of a building.

  Some embodiments of the present invention provide a method for protecting a reinforced concrete structure comprising: a reinforced concrete portion in which a reinforcing bar is disposed inside concrete; and a finishing portion provided in the reinforced concrete portion. An injection hole forming step of providing an injection hole that penetrates to the reinforced concrete portion, and a protective layer forming step of injecting a water absorption inhibitor into the injection hole to form a protective layer on the reinforced concrete portion. This is a method for protecting reinforced concrete structures.

  Other characteristics of the present invention will be made clear by the description and drawings described later.

  According to some embodiments of the present invention, a protective layer can be formed on a reinforced concrete structure while maintaining an existing finish.

FIG. 1 is a schematic sectional view showing a method for protecting a reinforced concrete structure 1 according to the first embodiment. FIG. 2A is a front view of the reinforced concrete structure 1 of the first embodiment. FIG. 2B is a cross-sectional view around the injection hole 30 in the reinforced concrete structure 1 of the first embodiment. FIG. 3A is a diagram illustrating an example of a non-pressurized injector 90. FIG. 3B is a diagram illustrating an example of a non-pressurized injector 90 (air venting type). FIG. 3C is a diagram illustrating an example of a pressurized injector 90. FIG. 4 is a diagram showing how the water absorbing agent 60 permeates in the surface direction of the reinforced concrete structure 1 when the injection depth of the water absorbing agent 60 is 50 mm. FIG. 5 is a diagram showing how the water absorbing agent 60 permeates in the surface direction of the reinforced concrete structure 1 when the injection depth of the water absorbing agent 60 is 100 mm. FIG. 6 is a diagram showing a state of penetration of the water absorbing agent 60 in the depth direction of the reinforced concrete structure 1 when the water absorbing agent 60 is applied to the surface of the concrete 12 separately from the injection of the water absorbing agent 60. FIG. 7 is a diagram illustrating a method of protecting the reinforced concrete structure 1 according to the second embodiment.

At least the following matters will be apparent from the description and drawings described below.

  A method for protecting a reinforced concrete structure comprising: a reinforced concrete part in which a reinforcing bar is disposed inside concrete; and a finishing part provided in the reinforced concrete part, wherein the injection hole penetrates the finishing part and reaches the reinforced concrete part. And a protective layer forming step of injecting a water-absorbing agent into the injection hole to form a protective layer on the reinforced concrete portion, thereby providing a method of protecting a reinforced concrete structure. . According to such a method for protecting a reinforced concrete structure, a protective layer can be formed on the reinforced concrete structure while maintaining the existing finishing material. In the present invention, the protective layer means a layer in which the water-absorbing agent penetrates into concrete and has an effect of suppressing moisture transfer.

  It is preferable that the protective layer has a reinforcing-bar coating layer formed on the surface of the reinforcing bar when the water-absorbing agent permeates the concrete around the reinforcing bar. Thereby, it is possible to suppress the progress of corrosion of the reinforcing steel due to a deterioration factor such as moisture. In the present invention, the reinforcing-bar coating layer means a layer that constitutes a part of a protective layer that replaces a passivation film on a reinforcing bar and has an effect of suppressing corrosion of the reinforcing bar.

  It is preferable that the protective layer has a high-concentration water-absorbing prevention layer formed on the concrete when the water-absorbing agent permeates the concrete. Thereby, it is possible to suppress deterioration factors such as moisture from entering the position of the reinforcing bar inside the concrete. In the present invention, the high-concentration water-absorption preventing layer means a layer that forms a part of the protective layer, has a high concentration of the water-absorbing agent, does not give a wet color, and has a strong hydrophobic effect.

  The water absorption inhibitor is preferably a silane-based impregnating material. This allows the water-absorbing agent to permeate the concrete, thereby forming a protective layer having a reinforcing-bar coating layer formed on the surface of the reinforcing bar and a high-concentration water-absorbing layer formed on the concrete.

  It is desirable that the viscosity of the water absorption preventing agent is 0.8 mPa · s to 800 mPa · s. This allows the water-absorbing agent to permeate the concrete, thereby forming a protective layer having a reinforcing-bar coating layer formed on the surface of the reinforcing bar and a high-concentration water-absorbing layer formed on the concrete. In the present invention, the viscosity means a value measured by a B-type rotational viscometer at 20 ° C.

  It is desirable that the viscosity of the water absorption inhibitor is 10 mPa · s or less. Thereby, the range of penetration of the water absorption preventing agent into the concrete can be widened.

  It is desirable to inject the water absorption inhibitor into the injection hole without applying pressure. Thereby, the water absorption preventing agent can be injected into the injection hole by a simple method.

  It is preferable that the injection hole is provided so as to face obliquely downward with respect to the horizontal direction from the surface side of the reinforced concrete structure toward the inside. Accordingly, even when the water-absorbing agent is injected without applying pressure, the water-absorbing agent can be injected without being left in the middle of the injection hole.

  The reinforced concrete structure is provided with a plurality of the injection holes, and an interval between the plurality of injection holes in a surface direction of the reinforced concrete structure is a size of a penetration range of the water absorption preventing agent in a surface direction of the reinforced concrete structure. It is desirable to be less than or equal to Thereby, the reinforced concrete portion can be covered with the protective layer.

  It is preferable that a vertical interval between the plurality of injection holes is larger than a horizontal interval between the plurality of injection holes. Thereby, the reinforced concrete portion can be covered with the protective layer.

When the compressive strength of the concrete of the reinforced concrete structure is 50 N / mm ² , a vertical interval between the plurality of injection holes is 300 mm or less, and a horizontal interval between the plurality of injection holes is 200 mm or less. Is desirable. Thereby, the reinforced concrete portion can be covered with the protective layer.

When the compressive strength of the concrete of the reinforced concrete structure is 18 to 50 N / mm ² , the vertical interval between the plurality of injection holes is 300 mm or more, and the horizontal interval between the plurality of injection holes is 200 mm or more. Desirably. Thereby, the reinforced concrete portion can be covered with the protective layer.

  When the compressive strength of the concrete of the second reinforced concrete structure is larger than the compressive strength of the concrete of the first reinforced concrete structure, the water absorption preventing agent in the surface direction of the second reinforced concrete structure is The permeation range is desirably smaller than the permeation range of the water-absorbing agent in the surface direction of the first reinforced concrete structure. Thereby, the reinforced concrete portion can be covered with the protective layer.

  Preferably, the injection hole is provided in the reinforced concrete portion so as to avoid the reinforcing bar. Thereby, the water-absorbing agent penetrates only around the reinforcing bar, so that only the reinforcing-bar coating layer formed on the surface of the reinforcing bar is formed, and the high-concentration water-absorbing preventing layer formed on the concrete is prevented from being hardly formed. be able to.

  It is preferable that an injection depth of the injection hole is equal to or less than a distance from a surface of the reinforced concrete structure to the reinforcing bar. Thereby, the high concentration water absorption prevention layer formed on the concrete can be formed on the surface side of the reinforced concrete structure.

  It is preferable that an injection depth of the injection hole is larger than a distance from a surface of the reinforced concrete structure to the reinforcing bar. Thereby, the high concentration water absorption prevention layer formed on the concrete can be formed on the back side of the reinforced concrete structure.

  The protective layer forming step desirably includes applying the water absorption preventing agent to a surface of the reinforced concrete portion. Thereby, it is possible to further suppress the deterioration factor such as moisture from entering the position of the reinforcing bar inside the concrete.

=== First Embodiment ===
<Outline of protection method for reinforced concrete structures>
FIG. 1 is a schematic sectional view showing a method for protecting a reinforced concrete structure 1 according to the first embodiment.

  In the following description, each direction is defined as shown in the figure. That is, as shown in FIG. 1, the direction perpendicular to the surface of the finished part 20 of the reinforced concrete structure 1 is defined as “depth direction”, the side of the surface of the finished part 20 relative to the reinforced concrete part 10 is defined as “surface”, The opposite side is referred to as “back” or “back”. In addition, as shown in FIG. 1 and FIG. 2A to be described later, a direction parallel to the surface of the finished portion 20 of the reinforced concrete structure 1 is referred to as a “surface direction”. The surface direction has a “vertical direction” and a “horizontal direction”.

・ Reinforced concrete structure 1
The reinforced concrete structure 1 of the present embodiment is, for example, a building structure constructed of reinforced concrete (RC), steel reinforced concrete (SRC), or the like. However, the reinforced concrete structure 1 of the present embodiment may be another structure. The reinforced concrete structure 1 has a reinforced concrete section 10 in which a reinforcing bar 11 is disposed inside a concrete 12, and a finishing section 20 provided in the reinforced concrete section 10.

  The reinforcing bar 11 of the reinforced concrete section 10 is disposed inside the concrete 12 to reinforce the tensile strength of the concrete 12. The reinforcing bar 11 is disposed at a position where a predetermined cover thickness is secured from the front and back surfaces of the concrete 12. The concrete 12 of the reinforced concrete part 10 is formed by casting concrete in a formwork. As the cement of the concrete 12 of the present embodiment, ordinary Portland cement can be used. However, the cement of the concrete 12 of this embodiment may use other types of cement. In the following description, the reinforced concrete part 10 may be referred to as a “concrete skeleton 10”.

  The finishing part 20 is a finishing material applied to the front surface or the back surface of the reinforced concrete part 10. The finishing unit 20 of the present embodiment can use a finishing material such as mortar, stucco, and tile. However, the finishing unit 20 of the present embodiment may use another finishing material.

-Outline of protection method of reinforced concrete structure 1 The protection method of the reinforced concrete structure 1 of the present embodiment includes an injection hole forming step and a protective layer forming step.

  The injection hole forming step is a step of providing an injection hole 30 that penetrates the finishing section 20 and reaches the reinforced concrete section 10. As shown in FIG. 1, an injection hole 30 is provided in the reinforced concrete structure 1, and an injection pipe 91 of an injector 90 is inserted. The injector 90 is filled with a water-absorbing agent 60 described later, and the water-absorbing agent 60 is injected into the injection hole 30 of the reinforced concrete structure 1 through an injection pipe 91.

  The injection hole 30 is a hole provided in the reinforced concrete structure 1 and into which a water absorption preventing agent 60 described later is injected. The injection hole 30 of the present embodiment is provided by drilling with a drill. However, the injection hole 30 of the present embodiment may be provided by another method. As shown in FIG. 1, the reinforced concrete structure 1 of the present embodiment is provided with a plurality of (here, five) injection holes 30 in the vertical direction. Tube 91 has been inserted. The arrangement direction and the number of the injection holes 30 in the present embodiment will be described later.

The size (inner diameter) of the injection hole 30 is about 10 mm in diameter. However, the size (inner diameter) of the injection hole 30 is not limited to this. In other words, the size (inner diameter) of the injection hole 30 need only be larger than the thickness (outer diameter) of the injection pipe 91 of the injector 90 and should be small enough not to impair the appearance of the finished portion 20. In addition, "the degree which does not impair the appearance of the finishing part 20" means that, for example, when a tile is used as the finishing part 20, the size (inner diameter) of the injection hole 30 is equal to or smaller than the size of the joint part of the tile. In other words, the effect on the appearance is small.

  Further, as shown in FIG. 1, the injection hole 30 penetrates the finishing part 20 and reaches the reinforced concrete part 10. In other words, the injection depth (D1 shown in FIG. 1) of the injection hole 30 is equal to or greater than the thickness (D2 shown in FIG. 1) of the finished portion 20 (D1 ≧ D2). The “injection depth of the injection hole 30” is a distance in a depth direction from an entrance on the surface side of the injection hole 30 to an end (D1 shown in FIG. 1). Moreover, as shown in FIG. 1, the injection depth of the injection hole 30 is not more than the distance (D3 shown in FIG. 1) from the surface of the reinforced concrete structure 1 to the reinforcing bar 11 (D1 ≦ D3). Thereby, the protective layer 80 formed on the concrete 12 can be formed on the surface side of the reinforced concrete structure 1. When the protective layer 80 is formed on the surface side of the reinforced concrete structure 1, it is possible to suppress the intrusion of deterioration factors such as moisture from the surface side of the reinforced concrete structure 1. The protection layer 80 will be described later.

  Further, as shown in FIG. 1, the injection hole 30 of the present embodiment is provided so as to face obliquely downward with respect to the horizontal direction from the surface side of the reinforced concrete structure 1 toward the inside (back side). That is, the injection hole 30 is provided such that the tip thereof faces obliquely downward with respect to the horizontal direction. Therefore, the water absorption preventing agent 60 injected into the injection hole 30 accumulates in the injection hole 30 from the tip of the injection hole 30 due to gravity. Accordingly, even when the water-absorbing agent is injected without applying pressure, the water-absorbing agent can be injected without being left in the middle of the injection hole. In addition, the injection hole 30 of this embodiment may be provided so as to face in the horizontal direction, or may be provided so as to face in other directions. In addition, the entrance of the injection hole 30 is sealed in order to prevent the water absorbing agent 60 from spilling from the entrance of the injection hole 30. However, when the viscosity of the water-absorbing agent 60 is high and the possibility of the water-absorbing agent 60 spilling from the entrance on the surface side of the injection hole 30 is small, the sealing may not be performed.

  The protection layer forming step is a step of forming the protection layer 80 on the reinforced concrete part 10. As shown in FIG. 1, the protective layer 80 is formed on the reinforced concrete part 10 by the water absorption preventing agent 60 injected into the injection hole 30 penetrating into the concrete 12 of the reinforced concrete part 10.

  The protective layer 80 is a layer having a property of making the reinforced concrete portion 10 hydrophobic. In the reinforced concrete portion 10 of the present embodiment, the protective layer 80 prevents the reinforcing bar 11 from coming into contact with the moisture and chloride ions that have entered the inside of the concrete 12, thereby suppressing the progress of corrosion of the reinforcing bar 11. Thereby, the deterioration of the reinforcing bar 11 can be suppressed. The range of the protective layer 80 (range surrounded by a broken line) illustrated in FIG. 1 is schematically illustrated for explanation, and is not limited thereto.

As described above, the method for protecting the reinforced concrete structure 1 according to the present embodiment includes the reinforced concrete portion 10 in which the reinforcing bar 11 is disposed inside the concrete 12 and the finishing portion 20 provided in the reinforced concrete portion 10. This is a method for protecting the reinforced concrete structure 1 provided. The method for protecting the reinforced concrete structure 1 according to the present embodiment includes an injection hole forming step of providing an injection hole 30 that penetrates the finishing portion 20 and reaches the reinforced concrete portion 10, and injects a water absorption inhibitor 60 into the injection hole 30. A protective layer forming step of forming the protective layer 80 on the reinforced concrete portion 10.

According to the method for protecting the reinforced concrete structure 1 of the present embodiment, the water absorbing agent 60 is not applied to the surface of the finished portion 20 of the reinforced concrete structure 1 but reaches the reinforced concrete portion 10 through the finished portion 20. The water absorption inhibitor 60 is injected into the injection hole 30 to form a protective layer 80 inside the reinforced concrete portion 10. Thus, it is not necessary to apply a finishing material further on the finishing portion 20 or to remove the finishing portion 20 once, form the protective layer 80 on the surface of the reinforced concrete portion 10, and apply the finishing material again. Thereby, the protection layer 80 can be formed on the reinforced concrete structure 1 while maintaining the existing finishing material (finishing portion 20).

  In addition, in addition to injecting the water absorbing agent 60 into the injection hole 30 that reaches the reinforced concrete part 10 through the finishing part 20 to form the protective layer 80 inside the reinforced concrete part 10, the reinforced concrete part of the reinforced concrete structure 1 The protective layer 80 may be formed on the surface side of the reinforced concrete part 10 by applying the water absorbing agent 60 to the surface of the reinforced concrete part 10.

<Protective layer of reinforced concrete part>
FIG. 2A is a front view of the reinforced concrete structure 1 of the first embodiment. In FIG. 2A, in the reinforced concrete structure 1 of the present embodiment, the position of the reinforcing bar 11 disposed inside the concrete 11 is indicated by a broken line. As shown in FIG. 2A, in the reinforced concrete structure 1 of the present embodiment, a plurality of injection holes 30 are provided in a horizontal direction and a vertical direction. Further, as shown by an elliptical broken line around the injection hole 30, a protective layer 80 is formed. In FIG. 2A, only a part of the protective layer 80 is shown. In the following description, the vertical interval (pitch) of the plurality of injection holes 30 may be referred to as PV, and the horizontal interval (pitch) of the plurality of injection holes 30 may be referred to as PH. Further, the vertical size of the protective layer 80 formed by the water absorbing agent 60 injected into each injection hole 30 may be referred to as DV, and the horizontal size may be referred to as DH.

  The interval (PV and PH) between the plurality of injection holes 30 in the surface direction (vertical direction and horizontal direction) of the reinforced concrete structure 1 of the present embodiment is determined to prevent water absorption in the surface direction (vertical direction and horizontal direction) of the reinforced concrete structure 1. It is equal to or smaller than the size (DV and DH) of the protective layer 80 of the agent 60 (PV <DV and PH <DH). Thereby, the reinforced concrete part 10 can be covered by the protective layer 80. The size (DV and DH) of the protective layer 80 of the water-absorbing agent 60 is set such that the size (DV) of the protective layer 80 of the water-absorbing agent 60 in the vertical direction is changed by the influence of gravity. It is larger than the size (DH) of the protective layer 80 of 60 (DV> DH). Therefore, the vertical interval (PV) between the plurality of injection holes 30 can be larger than the horizontal interval (PH) between the plurality of injection holes 30 (PV> PH).

  FIG. 2B is a cross-sectional view around the injection hole 30 in the reinforced concrete structure 1 of the first embodiment. FIG. 2B schematically illustrates a state of the protective layer 80 formed around a certain injection hole 30 among the plurality of injection holes 30 described above. In addition, FIG. 2B shows an example in which the injection hole 30 is provided so as to face in the horizontal direction from the surface side of the reinforced concrete structure 1 to the inside (rear side) for ease of explanation. Further, in FIG. 2B, illustration of the injector 90 is omitted for ease of explanation. As shown in FIG. 2B, a water absorption inhibitor 60 is injected into the injection hole 30.

The water absorption preventing agent 60 is a concrete protective material that forms a layer (protective layer 80) having a property of hydrophobizing in the reinforced concrete portion. In addition, the water absorption inhibitor 60 has a property of penetrating into concrete. In the method for protecting the reinforced concrete structure 1 of the present embodiment, the water-absorbing agent 60 injected into the injection hole 30 penetrates into the concrete 12 from the inner wall of the injection hole 30, and flows around the injection hole 30 of the reinforced concrete part 10. The protection layer 80 is formed. Since the water absorbing agent 60 penetrates from the inner wall of the injection hole 30 to the outside (the inside of the concrete 12), the concentration of the water absorbing agent 60 in the protective layer 80 gradually increases toward the outside of the injection hole 30. It becomes smaller.

  As the water absorption preventing agent 60 of the present embodiment, a silane-based impregnating material is used. The silane-based impregnating material is a type of impregnating material having a hydrophobic group (alkyl group) of silicone having a water-repellent function. However, the water absorption preventing agent 60 of the present embodiment may be an impregnating material other than the silane-based impregnating material.

  The protective layer 80 shown in FIG. 2B is a range (permeation range) where the water absorption preventing agent 60 permeates. The water absorbing agent 60 penetrates into the concrete 12 from the inner wall of the injection hole 30 toward the outside of the injection hole 30 to form the protective layer 80. In the present embodiment, the water-absorbing agent 60 penetrates into the concrete 12, and the high-concentration water-absorbing preventing layer 71 and the reinforcing-bar coating layer 72 are formed within the protective layer 80.

  The high-concentration water absorption prevention layer 71 is a layer that suppresses water from entering the concrete 12. The high-concentration water absorption preventing layer 71 is formed outside the injection hole 30 and is a portion where the concentration of the water-absorbing agent 60 permeating the concrete 12 is high. In the present embodiment, the high-concentration water-absorption preventing layer 71 is a layer that does not have a wet color even when water is sprinkled, and particularly has a high concentration of the water-absorbing agent 60. The high-concentration water absorption prevention layer 71 can suppress a deterioration factor such as moisture from entering a position of the reinforcing bar 11 inside the concrete 12. Further, a reinforcing bar coating layer 72 is formed around the reinforcing bar 11 within the range of the protective layer 80. The reinforcing bar coating layer 72 is a layer that suppresses adhesion of water to the reinforcing bar 11. The reinforcing-bar coating layer 72 is formed by coating the perimeter of the reinforcing bar 11 with the water-absorbing agent 60 that has permeated the concrete 12 and reaches the reinforcing bar 11 and travels along the surface of the reinforcing bar 11.

  In addition, as shown in FIG. 2A and FIG. 2B, the injection hole 30 is provided so as to avoid the reinforcing bar 11 in the reinforced concrete portion 10. If the injection hole 30 is provided so as to touch the reinforcing bar 11, that is, if the reinforcing bar 11 is exposed on the inner wall of the injection hole 30, the water absorbing agent 60 directly travels around the reinforcing bar 11, and the concrete 12 It becomes difficult to penetrate. Therefore, since the pouring hole 30 is provided in the reinforced concrete part 10 so as to avoid the reinforcing bar 11, only the reinforcing bar coating layer 72 formed on the surface of the reinforcing bar 11 is formed by the water absorbing agent 60 penetrating only around the reinforcing bar 11. Can be suppressed from being formed. In addition, since the injection hole 30 is provided in the reinforced concrete portion 10 so as to avoid the reinforcing bar 11, the protective layer 80 in a desired range for suppressing water from entering the concrete 12 can be formed.

<Injector>
FIG. 3A is a diagram illustrating an example of a non-pressurized injector 90. FIG. 3B is a diagram showing an example of a non-pressurized injector 90 (air venting type). The injector 90 shown in FIGS. 3A and 3B has a container 92 for filling the water-absorbing agent 60 and an injection pipe 91 for injecting the water-absorbing agent 60 into the injection hole 30. When the injection pipe 91 is inserted into the injection hole 30, the water absorption preventing agent 60 is injected into the injection hole 30 through the injection pipe 91. The lower the viscosity of the water-absorbing agent 60, the more easily the water-absorbing agent 60 permeates the concrete 12. That is, the lower the viscosity of the water absorbing agent 60, the larger the protective layer 80 of the water absorbing agent 60. Therefore, for example, when the viscosity of the water absorbing agent 60 is 10 mPa · s or less, it is advantageous to inject the water absorbing agent 60 into the injection hole 30 without applying pressure. Thereby, the water absorption preventing agent can be injected into the injection hole by a simple method.

  Further, the injector 90 shown in FIG. 3B further has an air vent tube 93. The air vent tube 93 is a tube through which the water absorption inhibitor 60 is injected from the injection hole 30 and air bubbles generated by permeating the inside of the concrete 12 are sent out. The air release pipe 93 is injected into the injection hole 30 together with the injection pipe 91, and bubbles generated by permeating the inside of the concrete 12 are sent out through the air release pipe 93.

  FIG. 3C is a diagram illustrating an example of a pressurized injector 90. In the injector 90 shown in FIG. 3C, the water absorbing agent 60 in the container 92 is added to the injection hole 30 by pressing the pressing surface 95 in the container 92 toward the injection hole 30 by the compressive force of the pressurized rubber 94. Pressed and injected. In the present embodiment, the water absorption preventing agent 60 is injected into the injection hole 30 while being pressurized to about 0.05 to 0.2 Mpa. When the viscosity of the water absorbing agent 60 is high, it is advantageous to inject the water absorbing agent 60 into the injection hole 30 under pressure. Thereby, even if the viscosity of the water absorbing agent 60 is high, the water absorbing agent 60 easily permeates the concrete 12.

<Example>
-Outline of Injection Test Regarding the method of protecting the reinforced concrete structure 1 of the present embodiment, an injection test of the water absorbing agent 60 into the reinforced concrete portion 10 was performed. In the pouring test, first, a wall-shaped test body in which a reinforcing bar was disposed inside concrete was manufactured. A plurality of injection holes were provided in the wall-shaped test body, and after a water absorption inhibitor was injected into the injection holes, a plurality of samples for component analysis were collected. Separately from the injection into the injection hole, a water absorption inhibitor was applied to the concrete surface, and after 28 days had elapsed, a plurality of samples for component analysis in the depth direction were collected. Sampling for component analysis is of two types: sampling by drilling with a drill and sampling by a concrete core.

  Sampling by drilling was performed with a 10.5 mm drill bit. A plurality of samples were taken at 50 mm intervals vertically and horizontally from the position of the injection hole. In this test, samples were collected at a total of eight points in the vertical and horizontal directions. In addition, the samples to be collected at the respective locations are as follows: when the depth of the injection hole 30 is 50 mm, the depth is 40 to 50 mm from the surface of the concrete, and when the depth of the injection hole 30 is 100 mm, the depth is from the surface of the concrete. A portion located between 90 mm and 100 mm in length was sampled and subjected to component analysis by pyrolysis gas chromatography.

  The concrete core was collected as a concrete core having a diameter of 80 mm or 100 mm including an injection hole. In addition, the sample was checked for a range in which water was not sprayed on the split surface to give a wet color, and the range was defined as a high-concentration water absorption preventing layer. Furthermore, at the place where the water absorbing agent was applied to the concrete surface, a concrete core having a diameter of 80 mm was sampled, and five discs were cut out at intervals of 20 mm to a depth of 100 mm from the application surface of the concrete core. After that, the components were analyzed by pyrolysis gas chromatography.

<Measurement conditions of pyrolysis gas chromatography>
The measurement conditions for component analysis by pyrolysis gas chromatography were as shown in Table 1 below.

  In this test, as shown in Table 2 below, the compressive strength of the concrete and the injection depth of the injection hole were changed, and the water-absorbing inhibitor A, which was a silane-based impregnating material having a viscosity of 1.2 mPa · s, was applied without pressure Was carried out in the case of injection into the injection hole. The viscosity of the anti-absorption material is a measurement result at 20 ° C. using a B-type rotational viscometer.

FIG. 4 is a diagram showing a state of penetration of the water absorbing agent 60 in the surface direction of the reinforced concrete structure 1 when the injection depth of the water absorbing agent 60 is 50 mm. . FIG. 5 is a diagram showing how the water absorbing agent 60 permeates in the surface direction of the reinforced concrete structure 1 when the injection depth of the water absorbing agent 60 is 100 mm.

As shown in FIG. 4 and FIG. 5, at each point from the center of the injection hole, the example of the reinforced concrete structure 1 (Example 3) in which the compressive strength of the concrete is 18 N / mm ² has the compressive strength of the concrete of 50 N. The component of the water absorption preventing agent 60 is higher than that of the example of the reinforced concrete structure 1 (Example 1) of / mm ² . This indicates that the smaller the compressive strength of the concrete, the more easily the water absorption preventing agent 60 permeates the concrete. As described above, since the water-absorbing agent 60 penetrates from the inner wall of the injection hole 30 to the outside (the inside of the concrete 12), the water-absorbing agent 60 in the protective layer 80 is directed toward the outside of the injection hole 30. The concentration gradually decreases. In consideration of the above, the lower the compressive strength of concrete, the wider the protective layer 80 of the water-absorbing agent 60. Accordingly, the protection layer 80 of the water-absorption inhibitor 60 in the surface direction of the compressive strength of the concrete is reinforced concrete structures 18N / mm ² 1 (Example 3), the compressive strength of the concrete is 50 N / mm ² of reinforced concrete structures 1 ( It is larger than the protective layer 80 of the water absorption preventing agent 60 in the surface direction in Example 1).

FIG. 6 shows the prevention of water absorption in the depth direction of the reinforced concrete structure 1 when the water absorbing agent 60 is applied to the surface of the concrete 12 separately from the injection of the water absorbing agent 60. It is a figure showing a situation of penetration of agent 60.

  As shown in FIG. 6, in the case of the reinforced concrete structure 1 in which the compressive strength of the concrete is 18 N / mm 2, the concentration of the water-absorbing agent 60 rapidly decreases when the distance from the surface is in a range of 30 mm to 50 mm. In the case of the reinforced concrete structure 1 having a concrete compressive strength of 50 N / mm 2, the concentration of the water absorption preventing agent 60 decreases rapidly when the distance from the surface is in a range of 10 mm to 30 mm. The above range is the boundary of the high concentration water absorption prevention layer 71.

-Viscosity of water absorption preventing agent 60 In Table 3 below, the result of confirming the range where the wet color does not become wet when water is sprayed on the split surface in sampling with a concrete core and the result of sampling with a drill hole are shown. The result of having confirmed the penetration range of the component of the inhibitor 60 is shown. In addition, the range which does not become a wet color when water is sprayed on the split surface was confirmed with a water absorption inhibitor A having a viscosity of 1.2 mPa · s and a water absorption inhibitor B which is a silane-based impregnating material having a viscosity of 762 mPa · s.

・ Summary Table 4 below shows the applicable range of the method for protecting the reinforced concrete structure 1 using the water absorbing agent A (1.2 mPa · s) and the water absorbing agent B (762 mPa · s).

  The viscosity of the water absorption inhibitor 60 may be any viscosity between 0.8 mPa · s and 800 mPa · s. In addition, it is particularly advantageous that the viscosity of the water absorption preventing agent 60 is 10 mPa · s or less. Thereby, the range of penetration of the water absorption preventing agent 60 into the concrete 12 can be widened. As described above, when the viscosity of the water-absorbing agent 60 is 10 mPa · s or less, the water-absorbing agent 60 can be injected into the injection hole 30 without pressure.

Compressive strength of the concrete can be any compressive strength between 18~50N / mm ^2. However, compression strength compressive strength from reinforced concrete structures 1 of 50 N / mm @ 2 is subjected to reinforced concrete structures 1 of 18N / mm ^2, penetration range of water-absorption inhibitor 60 gradually increases.

When the compressive strength of the concrete is 50 N / mm ² , the vertical interval (PV) of the plurality of injection holes 30 is 300 mm or less (100 mm upward + 200 mm downward), and the horizontal interval (PH) ) Is preferably 200 mm or less (100 mm leftward + 100 mm rightward). When the compressive strength of the concrete is 18 to 50 N / mm ² , the above interval can be set. Thereby, the reinforced concrete part 10 can be covered by the protective layer 80. In addition, the injection | pouring interval of the injection hole 30 at the time of using the water absorption inhibitor B is calculated by the ratio of the range which does not become the wet color of the water absorption inhibitor A and the water absorption inhibitor B.

=== Second Embodiment ===
FIG. 7 is a diagram illustrating a method of protecting the reinforced concrete structure 1 according to the second embodiment.

  In the first embodiment described above, as shown in FIG. 1, the injection depth of the injection hole 30 was equal to or less than the distance from the surface of the reinforced concrete structure 1 to the reinforcing bar 11. However, in the present embodiment, as shown in FIG. 7, the injection depth of the injection hole 30 is larger than the distance from the surface of the reinforced concrete structure 1 to the reinforcing bar 11. Thereby, the protective layer 80 formed on the concrete 12 can be formed on the back side of the reinforced concrete structure 1. When the protective layer 80 is formed on the back side of the reinforced concrete structure 1, it is possible to suppress the intrusion of deterioration factors such as moisture from the back side of the reinforced concrete structure 1.

=== Others ===
The embodiments described above are intended to facilitate understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified and improved without departing from the gist thereof, and it goes without saying that the present invention includes equivalents thereof.

1 reinforced concrete structure, 10 reinforced concrete part,
11 rebar, 12 concrete, 20 finishing part, 30 injection hole,
60 water absorption inhibitor, 71 high concentration water absorption prevention layer, 72 rebar coating layer,
80 protective layer, 90 injector, 91 injection pipe, 92 container, 93 air vent pipe,
94 pressurized rubber, 95 press surface

Claims (17)

A method for protecting a reinforced concrete structure comprising a reinforced concrete portion in which a reinforcing bar is disposed inside concrete, and a finishing portion provided in the reinforced concrete portion,
An injection hole forming step of providing an injection hole that penetrates the finishing part and reaches the reinforced concrete part,
A protective layer forming step of injecting a water absorption inhibitor into the injection hole and forming a protective layer on the reinforced concrete portion. A method for protecting a reinforced concrete structure according to claim 1,
The method for protecting a reinforced concrete structure, wherein the protective layer has a rebar coating layer formed on a surface of the rebar by the water absorbing agent penetrating into the concrete around the rebar. The method for protecting a reinforced concrete structure according to claim 1, wherein
The method for protecting a reinforced concrete structure, wherein the protective layer has a high-concentration water-absorbing prevention layer formed on the concrete when the water-absorbing agent permeates the concrete. A method for protecting a reinforced concrete structure according to any one of claims 1 to 3,
The method for protecting a reinforced concrete structure, wherein the water absorption inhibitor is a silane-based impregnating material. A method for protecting a reinforced concrete structure according to any one of claims 1 to 4,
A method for protecting a reinforced concrete structure, wherein the viscosity of the water absorption inhibitor is 0.8 mPa · s to 800 mPa · s. A method for protecting a reinforced concrete structure according to claim 5,
The method for protecting a reinforced concrete structure, wherein the viscosity of the water absorption inhibitor is 0.8 mPa · s to 10 mPa · s. A method for protecting a reinforced concrete structure according to claim 6,
A method for protecting a reinforced concrete structure, wherein the water absorption inhibitor is injected into the injection hole without applying pressure. A method for protecting a reinforced concrete structure according to claim 7,
The method of protecting a reinforced concrete structure, wherein the injection hole is provided so as to face obliquely downward with respect to a horizontal direction from the surface side of the reinforced concrete structure toward the inside. A method for protecting a reinforced concrete structure according to claim 5,
The reinforced concrete structure is provided with a plurality of the injection holes,
A method of protecting a reinforced concrete structure, wherein an interval between the plurality of injection holes in a surface direction of the reinforced concrete structure is equal to or smaller than a permeation range of the water-absorbing agent in a surface direction of the reinforced concrete structure. A method for protecting a reinforced concrete structure according to claim 9,
A method of protecting a reinforced concrete structure, wherein a vertical interval between the plurality of injection holes is larger than a horizontal interval between the plurality of injection holes. A method for protecting a reinforced concrete structure according to claim 10,
When the compressive strength of the concrete of the reinforced concrete structure is 50 N / mm ² , the vertical interval between the plurality of injection holes is 300 mm or less, and the horizontal interval between the plurality of injection holes is 200 mm or less. A method for protecting a reinforced concrete structure. A method for protecting a reinforced concrete structure according to claim 10,
When the compressive strength of the concrete of the reinforced concrete structure is 18 to 50 N / mm ² , the vertical interval between the plurality of injection holes is 300 mm or more, and the horizontal interval between the plurality of injection holes is 200 mm or more. A method for protecting a reinforced concrete structure. A method for protecting a reinforced concrete structure according to any one of claims 5 to 12,
Than the compressive strength of the concrete of the first reinforced concrete structure,
When the compressive strength of the concrete of the second reinforced concrete structure is high,
The permeation range of the water-absorbing agent in the surface direction of the second reinforced concrete structure is smaller than the permeation range of the water-absorbing agent in the surface direction of the first reinforced concrete structure. Protection method. A method for protecting a reinforced concrete structure according to any one of claims 1 to 13,
The method of protecting a reinforced concrete structure, wherein the pouring hole is provided so as to avoid the reinforcing bar in the reinforced concrete portion. A method for protecting a reinforced concrete structure according to any one of claims 1 to 14,
A method of protecting a reinforced concrete structure, wherein a depth of the injection hole is less than a distance from a surface of the reinforced concrete structure to the reinforcing bar. A method for protecting a reinforced concrete structure according to any one of claims 1 to 14,
The method of protecting a reinforced concrete structure, wherein an injection depth of the injection hole is larger than a distance from a surface of the reinforced concrete structure to the reinforcing bar. A method for protecting a reinforced concrete structure according to any one of claims 1 to 16,
The method for protecting a reinforced concrete structure, wherein the step of forming a protective layer includes applying the water absorbing agent to a surface of the reinforced concrete portion.

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