KR101332620B1 - Corrosion inhibitor injection method - Google Patents

Abstract

The present invention is a rust preventive indentation method for drilling the rust preventive indentation hole in the reinforced concrete structure by using the rust preventive indentation device to inject the rust inhibitor into the concrete at a high time for a certain time to the position where the reinforcement is reinforced In related to the step of diagnosing the corrosion of the reinforced concrete structure to investigate the location of the corroded reinforcing bar and to select a location to inject the rust inhibitor to form a hole for drilling; Installing a fixed anchor in the drilling hole; Connecting the rust inhibitor injection cylinder to one end of the fixed anchor exposed to the inlet of the drilling hole through a connection pipe; And injecting the anti-rust agent into the periphery of the perforation hole and the perforation hole through the pumping pressure of the anti-corrosive injection cylinder, and installing the fixed anchor in the perforation hole includes a front end side of the body part having a predetermined length. Inserting a fixed anchor provided in the drill hole provided in the reinforced concrete wall or the ceiling and fixed to the drill hole, the front end side of which is fixed to the drill hole; And an anchor fixing nut provided at the distal side of the body portion and screwed to the outer circumferential surface of the body portion to close the perforation hole and having a through hole communicating at the distal end of the screw engaging portion to the outside. And firmly fixing; connecting the anti-corrosive injection cylinder to one end of the fixing anchor through a connection pipe, the housing having a predetermined inner space, and the inner space of the housing as a rust-preventing filling space and an elastic space. A piston which is hermetically partitioned and moves in the longitudinal direction, a rust inhibitor inlet for communicating the rust preventive filling space with a connecting pipe, a separating disc for partitioning the elastic space into first and second elastic spaces, and filled in the first elastic space. And an elastic spring mounted to the elastic ball and the second elastic space to express elastic force in a longitudinal direction. Filling the corrosion inhibitor in the corrosion inhibitor of the filling space input cylinder; And connecting the injection cylinder filled with the rust preventive agent to the fixed anchor via a connection pipe.

Description

Corrosion inhibitor injection method

The present invention relates to a rust preventive indentation method, and more particularly, to the rust-proof concrete by using a rust preventive injector after drilling the rust preventive indentation hole in the reinforced concrete structure to a position where the reinforcement is reinforced The present invention relates to a rust preventive indentation method that allows the infiltration and diffusion.

Concrete is a porous material that is exposed to various environments during the years of use immediately after pouring and is subject to physical or chemical effects. In particular, harmful components such as sulfates, chloride ions, and carbon dioxide, which are present outside, penetrate into the concrete in solution or gaseous state over a long period of time, causing physical or chemical interactions with the concrete components, causing corrosion of the steel embedded in the concrete. This will reduce the durability and strength of concrete.

 In addition, due to the shortage of high-quality river aggregates due to the increasing demand for construction materials, which have soared in recent years, a considerable amount of sea sand has been used as concrete aggregates. Durability is greatly reduced, and the overlapping phenomenon, such as lack of concrete coating thickness, has become a major factor in the deterioration of concrete structures due to reinforcing bars.

Most of the metals react with water or air to corrode. In other words, the metal is thermodynamically unstable in contact with the environment in which water or oxygen is present and thus tends to release energy as it is converted into oxide or hydrous oxide. Therefore, the metal itself is reduced by supplying energy to a naturally occurring compound, that is, ore, so that the process of returning to the oxide of its original state is corrosion.

In the case of reinforcement, or reinforcing steel, which is used to compensate for the weaknesses of concrete vulnerable to tension, when concrete loses alkalinity or the concentration of chloride reaches the threshold due to penetration diffusion, corrosion is caused by the destruction of the passivity film, which is a protective film of reinforcing steel. Corrosion is inevitable by exposure to the environment.

 The effect of chloride on reinforced concrete structures is not only due to corrosion of the steel in the concrete, but also to chemical degradation of the concrete structure itself, leading to performance degradation and shortening its lifespan. When harmful ions reach the position of the reinforcing bar, corrosion begins as follows. Reinforcing bars reduce the cross-sectional area and hence mechanical performance, and concrete cracks due to expansion of corrosion byproducts. Their combined deterioration affects the safety and lifespan of concrete structures.

Corrosive corrosion in concrete is caused by electrochemical reactions, and corrosion reactions are similar to the oxidation and reduction reactions in batteries. Corrosion system of reinforcing steel in concrete is composed of anode, electrochemical oxidation and cathode, electroconductor, and cement paste pore solution in concrete, which acts as an electrolyte. . Reinforcing bars in concrete are oxidized at the anode by one of several half-cell reactions.

(Equation ^{1) Fe -> Fe 2 +} + 2e -

Electrons emitted from the anode travel through the rebar to the cathode region as shown in Figure 1, where they are consumed by the cathode half-cell reaction. In ordinary concrete structures where the pore solution is alkaline and already exposed to air, this is the reduction of dissolved oxygen.

(Equation _{2) 2H 2 O + O 2} + 4e - -> 4OH -

These anode and cathode reactions cannot occur alone and always react simultaneously. Corrosion reaction of reinforcing steel is a reaction combining both reactions of Equations 1 and 2, and ferrous hydroxide (Fe (OH) ₂ ) is formed on the iron surface as in Equation 3.

(Equation _{3) 2Fe + O 2 + 2H} 2 O -> 2Fe 2 + + 4OH - -> 2Fe (OH) 2

This compound is oxidized by dissolved oxygen dissolved in the concrete pore solution to become ferric hydroxide (Fe (OH) ₃ ). Moreover, the compound loses water to form red rust (FeOOH) and black rust (Fe ₂ O ₄ ), forming a rust layer on the iron surface.

 Corrosion is caused by the heterogeneous nature of the corrosion system. These heterogeneous properties can be seen in two different metals that are connected and immersed in the same electrolyte, and can also exist on a single metal surface, localized due to metallic separation, different grain orientations, or changes in concentration in the electrolyte. Because of the difference. Corrosion reactions also depend on the distribution of the cathode and anode and their relative area. Therefore, anodes and cathodes are irregularly distributed on the surface of the rebar, and if there are changes in these areas during the corrosion reaction, the erosion will be somewhat uniform. On the other hand, if the anode is located at a fixed point and the anode / cathode area ratio is small, local erosion occurs.

[Figure 1]

Pourbaix summarizes the thermodynamic data on the corrosion of various metals in a pH-potential diagram, which provides useful information on the electrochemical corrosion of all metals, although the rate of corrosion is unknown. Figure 2 Cl ^- if that does not contain an ion, Figure 3 is Cl ^- is a potential -pH of iron placed in an aqueous solution containing ions 355ppm. Considering these figures, iron in an aqueous solution containing no Cl ⁻ ions has a broad passivation region ② in the positive potential region, as shown in Figure 2. However, in the case of iron in an aqueous solution containing Cl ⁻ ions, as shown in Fig. 3, no passivation occurs at pH <6, and only the front corrosion zone ① exists, but at pH> 6, the official zone ②, incomplete passivation zone ③, and complete passivation. Area ④ appears. If the Cl ^- ion concentration is less than 355ppm, the formula area ② shrinks to the upper left of the figure, and the passivation area ④ expands in the same direction.

 However, the behavior of the reinforcing bars in concrete does not necessarily match that in the solutions described above.

[Figure 2]

[Figure 3]

This is because the reinforcing steel in concrete is placed in an alkaline environment with a pH of about 13 due to the strong alkalinity of the cement paste pore solution. It is known that an oxide film (γ-Fe ₂ nH ₂ O) having a thickness of about 20 to 60 kPa is formed on the surface of the reinforcing bar existing in such a strong alkali environment, and the steel is passivated, thereby protecting it from corrosion.

 Passivation occurs when the corrosion product is insoluble and adhesive, forming a super protective film on the metal surface. In the case of passivated rebars, the corrosion is not actually stopped but is strictly limited by the ohm resistance of the passivation film. Under these passivation conditions, the corrosion rate of the reinforcing bars is quite resistant to the dissolution or oxidation of about 0.1 μm / year from the surface, which is negligible in view of the life expectancy of most concrete structures. Passivation of steel in concrete requires high pH and both water and oxygen must be present.

(Equation ^{_{4) 2H 2 O + 2e -}} -> H 2 + 2OH -

If there is no oxygen and the pH is above 9, the corrosion reaction will continue, but instead of the reduction reaction of oxygen like the cathode half cell reaction, hydrogen is released as shown in Equation 4. Under these conditions, the rate of corrosion is of a higher order than passivated bars, but it is reported to be still at an acceptable low value of 1 µm / year.

 For this reason, developed countries have not only fully considered countermeasures against salt damage when constructing concrete structures affected by chloride, but have also taken measures for maintenance, durability diagnosis, and evaluation even for already constructed structures. In the case of concrete structures clad with, the repair plan is approaching the practical stage.

 Corrosion inhibiting methods of reinforcing steel in concrete structures under such salty environment include increasing coating thickness, using epoxy coating reinforcing bars, rust preventive method and electric method. Among these, rust preventive method is the most practical method of reinforcing steel in concrete. It is known as one of the means.

As a repair method using a rust preventive agent, a method of applying a rust preventive agent to a surface (surface coating method) is mainly used. However, when a rust preventive agent is applied to a concrete surface, it is difficult to reliably penetrate the rust preventive component up to the rebar position. As another repair method, a method of peeling concrete up to the reinforcement part and applying a rust preventive agent directly to the rebar (section recovery method) is used, but this has a disadvantage in that it is difficult in construction and costly and time consuming.

Recently, a method of preventing corrosion of reinforcing steel in concrete containing chloride by impregnating a rust preventive agent on the surface of concrete for repair has been developed. However, nitrous acid from the surface of concrete to the surface of reinforcing steel is used for the use of rust inhibitor for repair. It is necessary to clarify from two viewpoints: the permeability of ions and the effect of inhibiting the corrosion of reinforcing nitrite ions. In both directions, research is being conducted in addition to macrocell corrosion. However, the method of impregnating an aqueous solution of rust preventive agent on the surface of concrete often affects the moisture content of the concrete, which makes it difficult to calculate an appropriate amount. In addition, the method of injecting the anti-corrosive solution at low pressure through the crack generated by the corrosion of the steel can be directly applied to a high concentration of the anti-corrosive agent in the rebar position, it is a high effective method, but has a problem of only local maintenance.

Therefore, there is a need for a method of effectively penetrating high concentrations of rust inhibitors to reinforcing steel in concrete as a method for repairing concrete structures in a marine environment affected by salt damage.

The present invention has been made to solve the above problems, the present invention is to provide a method for simply and reliably injecting a rust preventive agent in a reinforced concrete structure. In addition, it also provides a press-fit device used in the construction method to make the construction convenient and simple.

In accordance with an embodiment of the present invention, the anti-corrosive press-fitting method includes diagnosing corrosion of a reinforced concrete structure, investigating the position of the corroded reinforcing bar, and selecting a position to inject the anti-corrosive agent to form a perforation hole; Installing a fixed anchor in the drilling hole; Connecting the rust inhibitor injection cylinder to one end of the fixed anchor exposed to the inlet of the drilling hole through a connection pipe; And injecting the anti-rust agent into the periphery of the perforation hole and the perforation hole through the pumping pressure of the anti-corrosive injection cylinder, and installing the fixed anchor in the perforation hole includes a front end side of the body part having a predetermined length. Inserting a fixed anchor provided in the drill hole provided in the reinforced concrete wall or the ceiling and fixed to the drill hole, the front end side of which is fixed to the drill hole; And an anchor fixing nut provided at the distal side of the body portion and screwed to the outer circumferential surface of the body portion to close the perforation hole and having a through hole communicating at the distal end of the screw engaging portion to the outside. And firmly fixing; connecting the anti-corrosive injection cylinder to one end of the fixing anchor through a connection pipe, the housing having a predetermined inner space, and the inner space of the housing as a rust-preventing filling space and an elastic space. A piston which is hermetically partitioned and moves in the longitudinal direction, a rust inhibitor inlet for communicating the rust preventive filling space with a connecting pipe, a separating disc for partitioning the elastic space into first and second elastic spaces, and filled in the first elastic space. And an elastic spring mounted to the elastic ball and the second elastic space to express elastic force in a longitudinal direction. Filling the corrosion inhibitor in the corrosion inhibitor of the filling space input cylinder; And connecting the injection cylinder filled with the rust preventive agent to the fixed anchor via a connection pipe.

Before connecting the rust preventive injection cylinder to the fixed anchor in the rust preventive injection method according to an embodiment of the present invention, by connecting a pump to one end of the fixed anchor exposed to the inlet of the drilling hole through a pipe of the hole and the hole The method may further include a step of preliminarily charging the rust inhibitor in the vicinity.
In the rust preventive injection method according to an embodiment of the present invention, the housing is provided with a fitting hole for communicating the elastic space with the outside, is inserted into the fitting hole is connected to the separating disk is provided to retreat the separating disk Further comprising a piston retracting means, when the rust inhibitor is filled in the rust preventive filling space may be filled with the rust inhibitor in the state in which the elastic spring is retracted by using the piston retracting means.
In the rust preventive injection method according to an embodiment of the present invention, the outer peripheral surface of the housing is provided with a latch that can be fixed after the piston retracting means retracts the separating disk, and after retracting the elastic spring to fix the piston retracting means. can do.
Magnets may be provided on the outer circumferential surface of the connection pipe in the rust preventive injection method according to an embodiment of the present invention.
In the rust preventive injection method according to an embodiment of the present invention, the outside of the rust inhibitor injection port may be provided with a cylinder valve that can control the rust inhibitor injection and outflow into the rust preventive filling space.
In the rust preventive injection method according to an embodiment of the present invention, the anchor fixing nut may be provided with an anchor valve for controlling the injection and outflow of the rust inhibitor into the through hole of the anchor fixing nut.

Using the present invention,

First, by using a conventional anti-corrosive agent to compensate for the disadvantages of the method of preventing the reinforcement of the reinforced concrete structure to ensure that the anti-corrosive agent to form a passivation film on the outer peripheral surface of the reinforcement.

Second, it is possible to provide a construction method that is simple and inexpensive while using rust inhibitors as a method of inhibiting corrosion of reinforcing steel in concrete structures.

Third, it is possible to provide the equipment to press the anti-rust agent in order to suppress the corrosion of the reinforcing steel of the concrete structure, this equipment can be semi-permanent recycling can increase the efficiency of the equipment.

Fourth, the equipment for injecting the rust preventive agent to suppress the corrosion of the reinforcing steel of the concrete structure is very simple and easy to operate because it is easy to use.

1 is a flow chart showing the process sequence of the antirust agent indentation method according to the present invention,
Figure 2a to 2g is a reference diagram for explaining the antirust agent indentation method according to the invention,
Figure 3 is a reference diagram showing the interval of the drilling holes in the rust inhibitor indentation method according to the invention,
Figure 4 is a schematic diagram of the rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the invention,
Figure 5a is a perspective view showing the inside of the cylinder of the rust inhibitor indentation device used in the rust inhibitor in accordance with the present invention,
Figure 5b is a reference diagram showing an embodiment of pulling the piston retracting means in the cylinder of the rust preventive indentation device used in the rust preventive indentation method according to the present invention to hang on the catches,
6 is a cross-sectional view of a fixed anchor of the rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the invention,
7 is a photograph of an embodiment of a rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the invention,
8 is a photograph of a fixed anchor of the embodiment of the rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed in a conventional or dictionary sense, and the inventor should appropriately define the concept of the term to describe its invention in the best possible way It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, at the time of the present application, It should be understood that there may be water and variations.

In order to carry out the anticorrosive indentation method of the present invention, a rust preventive indentation apparatus is used, and the rust preventive indentation apparatus includes a fixed anchor fixed to a drilling hole and an injection cylinder connected to the fixed anchor and injects a rust preventive agent, and further, the fixed It is connected to the anchor to prefill the rust preventive agent in the drilling hole or connected to the injection cylinder to use the rust inhibitor injection pump to fill the injection cylinder in the rust preventive solution. The rust preventive indentation apparatus will be described later after explaining the rust preventive intrusion method.

In the present invention, a method of using reinforcing bars using a rust preventive agent is used. Before explaining the rust preventive indentation method, the rust preventive mechanism of the rust preventive agent will be described.

It is important to avoid chloride incorporation into reinforced concrete, and appropriate rust preventives are recommended when chlorides are mixed due to insufficient cleaning of the sea, and infiltration of chloride such as in marine environments is unavoidable. The rust inhibitors control the corrosion rate by controlling the anode reaction or the cathode reaction. Figure 4 shows the change of dislocation and corrosion rate using the anode and cathode rust inhibitors. As shown in Fig. 4 (a), when chloride is present without the addition of rust inhibitor, the anode curve (A ₁ ) and the cathode curve (C ₁ ) meet at W.

At this time, the appended speed is I ₀ . When an anode type rust preventive agent is added, the anode curve A ₂ increases in potential E _p due to the formation of a passive film. Therefore, the intersection point of the anode curve and the cathode curve moves from W to X so that the corrosion rate becomes I _i . In other words, it is possible to reduce the corrosion rate by the difference between I ₀ and I _i .

Figure 4 (b) shows the curve when the cathode type rust inhibitor is added. The anode curve by chloride is A ₁ and the cathode curve without rust inhibitor is C ₁ . These two curves meet at W and the corrosion rate is I ₀ . However, when the cathode type rust inhibitor is added, the cathode curve C ₁ is moved to C ₂ by suppressing the cathode reaction, so that the corrosion rate decreases from I ₀ to I _i . However, most cathode type rust inhibitors are inferior to anode type rust inhibitors.

[Figure 4]

Types of rust inhibitors are anode type and cathode type as described above, and there are anode type rust inhibitors such as orthophosphates, silicates, nitrites, chromates, benzoates, and the like. And cathode type corrosion inhibitors include lime and polyphosphate.

In the present invention, the use of a nitrous acid-based rust preventive agent is taken as an example. Reinforcing bars in concrete are protected from corrosion by forming a passivation film due to the high alkalinity of the concrete (pH = 12 or more). However, once concrete is neutralized (pH = 10 or less), the passivation film may become unstable and corrosion may occur. In addition, if salt is contained in the concrete, even if the pH is not lowered, the passivation film is partially destroyed by chlorine ions, and corrosion occurs. Nitrite ions regenerate the broken passivation film and become a stable substance, thus preventing the occurrence and progress of corrosion. This antirust mechanism is well described below.

The passivation film is composed of dense iron oxide (Fe ₂ O ₃ ). Chloride ion (Cl ^-) is dissolved in the iron of the metal over the passivation film (divalent iron ions: and elute as Fe ^{2 +).} Nitrite ions (NO ₂ ⁻ ) react with the divalent iron ions (Fe ²⁺ ) to regenerate the passive film (see Equation 5 and Figure 5).

(Equation ^{5) Fe 2 + + 2OH -} + 2NO 2 - -> Fe 2 O 3 + H 2 O + 2NO

[Figure 5]

- Anti-rust agent Indentation Method

1 is a flow chart showing a process sequence of the rust inhibitor indentation method according to the present invention, Figures 2a to 2g is a reference diagram for explaining the rust inhibitor indentation method according to the present invention.

As shown in Figure 1, the present invention relates to the anti-corrosive indentation method, and more specifically to the reinforcement by injecting the anti-corrosive agent into the concrete for a certain time at high pressure by using a rust-preventing device after drilling the corrosion-resistant indentation hole in the reinforced concrete structure The present invention relates to a rust inhibitor indentation method that allows the rust inhibitor to penetrate and diffuse widely.

As shown in Figure 1 and 2, the corrosion inhibitor indentation method according to the present invention is a corrosion diagnosis step (S1) for diagnosing the corrosion of the reinforced concrete structure, the reinforcement position investigation to investigate the reinforcement position of the reinforced concrete structure that requires the injection of rust inhibitor Step (S2), indentation position drilling step (S3) for selecting and punching the hole to inject the rust inhibitor based on the irradiated reinforcement position, and installing a fixed anchor in the drilling hole drilled in the indentation position drilling step (S3) Anchor installation step (S4), pre-charging step (S5) to connect the rust preventive injection pump to the fixed anchor installed in the anchor installation step (S4) (S51) to precharge the drilling hole (S52), the anchor installation step (S4) Main injection step (S6) to connect the injection cylinder to the fixed anchor installed in the (S61) to the main hole (S62), the indentation device removal step (S7) for removing the fixed anchor and the injection cylinder installed, and the indentation device In the drilled hole It comprises a drilling hole recovery step (S8) to fill the sealing material.

Here, the pre-filling step (S5) is an arbitrary step before filling the remaining space except the space occupied by the fixed anchor installed in the drilling hole before proceeding to the main charging step (S6) injection cylinder in the main charging to be carried out later This is to minimize the pressure reduction of the injection cylinder by reducing the space to be filled. Therefore, the main charging step (S6) may proceed without passing through the preliminary charging step (S5).

In addition, after the drilling hole recovery step (S8) may further include an injection confirmation step (S9) to check whether a sufficient amount of the rust inhibitor is injected to the target position. In practice this will often not proceed at the construction site, but it is an arbitrary step that can be taken to clarify the injection of rust inhibitors.

Hereinafter, each step will be described in detail.

1) Corrosion diagnosis step S1 )

This step is a step of diagnosing corrosion of the reinforced concrete structure, and may be referred to as a pre-investigation step for implementing the rust inhibitor indentation method according to the present invention.

Metals (reinforcing bars) tend to be homing instincts to return to oxides in their original state. In fact, metals are energy unstable because they are obtained by energizing ores in the state of nature (iron ores) that exist in nature. Hence, metals have a natural tendency to return to the phase of the phase, ie, the corrosion, which is more stable than the presence of metal by releasing energy.

Corrosion, therefore, refers to a phenomenon in which a metal degrades and eventually becomes unusable through various environmental and chemical or electrochemical reactions. As such, corrosion occurs in many parts including metal structures, steel bridges, underground works, machinery, chemical apparatus, reinforced concrete structures, and so on.

Here, the corrosion of the rebar in the reinforced concrete structure associated with the present invention will be described. Corrosion of reinforcing steel may induce chlorine ions by penetrating carbonic acid in the air and chlorine ions when the reinforced concrete structure is installed on the shore.

In the case of carbonation, in general, the pH of healthy concrete is about 13 alkalinity. In this case, carbon dioxide gas penetrates from the air and the pH changes to the neutral side, which is called neutralization of concrete. Calcium carbonate is produced and eluted and neutralized. The measurement of the degree of carbonation can be checked by changing the color by spraying phenolphthalein. The reaction scheme is shown in Equation 6 below.

(Equation 6)

Ca (OH) ₂ + CO _2- > CaCO ₃ + H ₂ O

Since the reinforcing steel in the concrete is located in the passive region at pH 13, the natural potential also shows a high potential and does not corrode. However, if neutralization occurs or the salt concentration increases due to salt penetration, the passivation film is destroyed and the reinforcing steel is corroded in the presence of moisture or oxygen. The rate of concrete neutralization depends on the environmental conditions, the properties of the concrete, the thickness of the coating, etc. The corrosion of the reinforcing concrete in the chloride-containing concrete already begins before the neutralization reaches the surface of the rebar. Due to the effects of neutralization and chlorides, the surface of the reinforcing bar is activated, which lowers the natural potential of the reinforcing bar.

Although the corrosion evaluation of reinforcing steel bars is comprehensively determined from the measurement results of various factors, in general, determination of the corrosion state by natural potential is mainly performed. Table 1 below shows an example of evaluating the corrosion probability by the range of natural potential with respect to the corrosion state of reinforcing steel in concrete.

Natural potential (V) Corrosion Probability (%), ASTM C876-91 Corrosion probability (%), B8 7361 Part 1 1991 Potential higher than -0.2V 90% chance of no corrosion Less than 5% chance of corrosion -0.2 ~ -0.35V Not deterministic 50% chance of corrosion Potential lower than -0.35 V 90% chance of corrosion 95% chance of corrosion

As shown in Table 1, the probability of rebar corrosion can be judged by the measurement of natural potential.

In the present invention, before the corrosion of the reinforcing bar to intrude the anti-corrosive agent to form a reinforcing film of the rebar, so the natural potential is measured at about -0.2 ~ -0.35V, when the rebar is close to corrosion, the method according to the invention is carried out It will be desirable to re-form the passivation film on the rebar.

In addition, there are various methods for diagnosing or measuring corrosion, and representative methods include visual inspection, natural potential measurement, polarization test (positive polarization test, negative polarization test), coating thickness measurement, and non-destructive test (ultrasonic probe, X- Ray inspection), electrochemical impedance spectroscopy, and other mechanical tests (corrosion fatigue test, corrosion fatigue test, etc.) in corrosive environments.

2) Rebar location investigation S2 )

This step is determined that the corrosion of the reinforcing bar in the corrosion diagnosis step (S1) may occur sooner or later, when the indentation of the rust inhibitor is determined to determine the reinforcement state of the reinforced concrete structure to find a hole to inject the rust inhibitor in a later step It is the step of selecting the position to drill.

In this step, in order to estimate the position, direction, and cover thickness of the reinforcement in the reinforced concrete structure, the measuring instrument using the property that the electromagnetic wave transmitted inside the structure generates the reflected wave at the boundary of the reinforcing bar, which has different electrical characteristics. Rebar exploration is carried out using a phosphorus probe. The rebar probe is a non-destructive inspection device based on the principle of self-sensitization. The rebar detector detects the reinforcement status of each member by performing the slab or wall of the structure.

R.C-Radar (Radio Detection And Ranging), FERROSCAN, etc. may be used for the type of rebar detector, and these are well known and used in various fields, and thus detailed description thereof will be omitted.

3) Indentation position drilling step ( S3 )

This step is a step of performing the drilling by selecting a hole for injecting the rust inhibitor based on the position of the reinforcing bar irradiated in the step (S2).

In this step, the drilling of the drilling hole is performed by a drill or the like, and the diameter of the drilling hole is preferably equivalent to the diameter of the fixed anchor in the configuration of the anti-corrosive injection device used in the present invention. That is, the fixed anchor is fixed after being inserted into the drilling hole to be able to inject the rust inhibitor by the injection cylinder, so it must be able to be firmly fixed in the drilling hole, in order to implement such anchoring, the diameter of the drilling hole is barely fixed anchor. It is because it is preferable to be provided in the magnitude | size enough to be able to enter.

Furthermore, one or more perforation holes are provided, and are usually arranged at a predetermined interval on the reinforced concrete structure so that several are provided. Here, the arrangement of the drilling holes is not arbitrarily determined but by the method to be described below.

Moisture transfer mechanisms in concrete are classified into three types: Pressurizing Penetration Flow, Capillary Seepage Flow, and Pressurizing Seepage Flow.

In the case of pressurized permeation of concrete, water flows along the pressure gradient because concrete is a porous body, which is in accordance with Darcy's Law. Darcy's law is an empirical law derived from observation of the flow of fluid through a porous medium and is equal to Equation 7.

(Equation 7)

here,

Pressurized osmosis flow refers to the case where the flow of water in concrete is caused by pressure, and the flow of water pressurized into the concrete at high pressure is divided into infiltration diffusion flow, different infiltration flow, and capillary penetration.

As shown in Fig. 6, in the case of pressure gradient, the penetration diffusion part follows the curve of the error function, and the darsi penetrating part and the maternal penetrating part follow the linearity. Furthermore, the flow of water in the concrete according to the pressure is different from the case where the pressure is less than 0.15MPA, the infiltration flow into the diffusion diffusion flow if the pressure is more than 0.15MPA.

[Figure 6]

Since Darcy Seepage Flow is constant over time and space, the equal gradient is linear, so Equation 7 can be written as

(Expression 8)

here,

Here, when the initial condition t = 0, x = 0, the equation 8 is integrated,

(Equation 9)

The average penetration depth 'x' measured in Eq. 9 is defined as 'dm', and 'k' is rewritten as 'K'.

(Equation 10)

here,

Seepage diffusion flow is a nonlinear high pressure penetration model that considers internal deformation due to high pressure and is applied when internal deformation due to high pressure is important. In this case, the flow rate and the gradient are diversified in time and space. This is represented graphically in Figure 7.

[Figure 7]

In addition, formulating Figure 7 is the same as Equations 11 and 12.

(Expression 11)

(Expression 12)

here,

In Equations 11 and 12, the amount ΔQ of water remaining over the pressure increment dp during the time dt is equal to Equation 13.

(Expression 13)

Where E is the volume modulus when water and concrete are considered in common

Here, Equation 14 is derived by differentiating Equation 7 applying Darcy's Law again, and Equation 15 is derived by substituting Equation 14 again into Equation 13.

(Equation 14)

(Eq. 15)

을 확산계수로 정의하고, 이론치와 실험치와의 오차는 이차적인 요인에 의해서 유발되어 시간에 대한 보정계수

를 이용하여 정리하면 식 16이 도출된다.Equation 15 is the basic equation of pressure in one-dimensional high pressure infiltration, and the high pressure infiltration flow follows the differential equation of diffusion in relation to pressure in this way,

Is defined as the diffusion coefficient, and the error between the theoretical and experimental values is caused by a secondary factor,

By summarizing using Eq.

(Expression 16)

here,

는 t^{3 / 7} 로 정할 수 있다.Here,

It may be determined by t ^3/7.

In addition, through the repeated experiments, the tip water pressure of the infiltration diffusion flow is 0.15 MPa, and the portion of the water pressure less than that can be observed by shifting to the osmotic flow.

는 t^{3 / 7} 이고 침투깊이 dm은 압력 P^{1 /2.39} , 시간 t^{1 /3.5} 에 비례한다는 이론을 기반으로 단위를 환산해주면 식 17, 18, 19로 변환이 가능하다.In Equation 16

Is t ^3/7 and the penetration depth dm is capable of conversion to pressure P ^{1 /2.39,} haejumyeon time t in terms of the units based on a theory that is proportional to the expression ^{1 /3.5} 17, 18, 19.

(Equation 17)

(Expression 18)

(Expression 19)

과 압력 p, 가압시간 t를 변수로 하고 21.13이라는 비례상수를 결정하여 식 20과 같이 물시멘트비, 압력 별 확산계수와 압력, 가압시간을 대입하면 콘크리트내 방청제 침투깊이를 간편하게 예측하는 예측식을 제안한다.Equation 16 finally gives diffusion coefficient according to water cement ratio and pressure.

By estimating the proportional constant of 21.13 with overpressure p and pressurization time t as variables, we propose a prediction equation that easily predicts the penetration depth of rust inhibitor in concrete by substituting water cement ratio, diffusion coefficient, pressure and pressurization time as shown in Equation 20. do.

(Expression 20)

here,

는 표 2로 제시된다.And diffusion coefficient according to water cement ratio and water pressure

Is shown in Table 2.

[Table 2]

Using Equation 20, it is possible to calculate the average penetration depth using the water cement ratio of the concrete, the pressure of the water, and the pressurization time. If the penetration depth can be calculated, it is possible to estimate the installation interval of the rust preventive indenter in the reinforced concrete structure. For example, if the penetration depth is calculated to be 20 mm, this means that the rust inhibitor can penetrate to a radius of 20 mm around the hole, so that the gap of the hole can be selected as 40 mm.

Of course, in reality, the rust inhibitor will continue to penetrate even after removing the rust inhibitor indentation device from the drill hole (capillary infiltration, diffusion method, etc.), and there may be an error in Equation 20. In order to estimate the gap between drill holes, the estimated penetration depth (dm) is assumed to be the minimum penetration depth. Therefore, it is most preferable that the gap between the drill holes is larger than 2dm and less than 4dm considering the penetration depth of the rust inhibitor and the efficiency of construction. Judgment is made (see FIG. 3).

For reference, in order to use Equation 20, the water pressure (injection pressure of the anti-corrosive agent to be injected in the present invention) should be calculated, and the injection cylinder is prepared in advance since the anti-corrosive agent filled in the injection cylinder is the same as the pressure to be injected into the drilling hole. It is preferable to calculate the injection pressure.

4) Anchor installation step ( S4 )

This step is a step of installing a fixed anchor in the drilling hole drilled in the press-fitted position drilling step (S3). The fixed anchor is connected to the anti-corrosive injection pump or injection cylinder to inject the anti-corrosive agent into the drilling hole, and is connected to the anti-corrosive injection pump or the injection cylinder so that the anti-corrosive agent is not leaked to the outside of the drilling hole even when the anti-corrosive agent is injected by pressure. Is installed in a tightly fixed state to maintain the packed state to serve as a support.

In addition, the installation method and the detailed configuration will be described in detail in the rust-preventing device to be described below.

5) Precharge stage ( S5 )

This step is to connect the rust preventive injection pump to the fixed anchor installed in the anchor installation step (S4) (S51) to perform a pre-charge (S52) of the drilling hole. This step is an optional step, after the fixed anchor is inserted and fixed in the drilling hole before the main filling step (S6), and fill the empty space with the anti-rust agent injection pump in advance, when the anti-rust injection using the injection cylinder later This is to maintain the maximum pressure of the injection cylinder. Therefore, the main charging step (S6) may proceed immediately without the progress of this step.

6) Main charging stage ( S6 )

This step is a step of connecting the injection cylinder to the fixed anchor installed in the anchor installation step (S4) (S61) to the main filling of the drilling hole (S62). Of course, when the pre-charge step (S5) is carried out after removing the anti-corrosive injection pump from the fixed anchor proceeds, when removing the anti-corrosive injection pump locks the valve provided on the top of the fixed anchor In this state, the rust inhibitor injected into the drilling hole should not leak out. In the main filling step (S6) is not meant to fill the perforated hole, but the rust preventive agent penetrates into the interior of the reinforced concrete structure through the perforated hole so that the rust preventive agent is filled to the portion where the rebar is located.

In addition, the injection cylinder should be connected to the anti-corrosive injection pump in advance before being connected to the fixed anchor to fill the injection cylinder with a rust preventive agent, the valve should be provided at the inlet of the injection cylinder to prevent leakage of the filled anti-corrosive in this process.

In addition, the installation method and the detailed configuration will be described in detail in the rust-preventing device to be described below.

7) Indentation Device  Removal step ( S7 )

This step is to remove the installed fixed anchor and the injection cylinder. Removal of the indentation device in this step is that the installation holding time has already been estimated in the process of calculating the penetration depth (dm) assumed in the process of drilling the hole in the indentation position drilling step, so that the injection cylinder is installed for a predetermined time. You can keep it and remove it.

When removing the press-fit device, it is necessary to proceed in the opposite manner to the method in which the fixed anchor is installed in the drilling hole, and the cone nut and the expansion sleeve to be described below, which are provided at the tip of the fixed anchor and fixed to the bottom of the drilling hole, are left in the drilling hole. Therefore, the cone nut and the expansion sleeve are preferably made of a stainless material (SUS material) which does not have a risk of corrosion.

8) Recovery of punched holes ( S8 )

In this step, the sealing material is filled in the drilling hole where the press-fitting device is removed. Since the drilling hole has a fixed anchor installed, the space after removing the fixing anchor is filled with the sealing material so that the cross-section of the reinforced concrete structure before the drilling hole is drilled. Should be restored. Since the sealant may also serve as a rust preventive agent to some extent, it is preferable to use a rust preventive component used as the rust preventive agent in the present invention.

9) Injection confirmation step ( S9 )

This step is to determine whether a sufficient amount of the rust preventive agent is injected to the target position after the drilling hole recovery step (S8), after selecting a few of the plurality of drilling hole positions and collecting the core after the chloride ion and the mole ratio of nitrite ions ^{_{([NO 2 -] / [}} Cl -]) is a step of verifying whether at least 0.6. Accordingly, in order to calculate the amount of nitrite ions having a molar ratio of 0.6 to obtain excellent rust preventing performance at the rebar position when the chloride ion is at a critical amount of 1.2 kg / m ³ , the amount of nitrite ions having a molar ratio of 0.6 is x ₁ , Using the molecular weight of chloride ion (35.5 g / mol) and the nitrite ion (46 g / mol) it can be calculated by the equation (21).

(Eq. 21)

Calculation of Equation 21 shows that the amount of nitrite ion (x ₁ ) is 0.932kg / m ³ , and the unit of the nitrite ion is 77mg / l.

Therefore, in view of this, the amount of nitrite ion to ensure the rust prevention performance in the collected core should be confirmed that more than 0.932kg / m ³ or 77mg / l is collected.

- Anti-rust agent Indentation Device

The rust preventive indentation method for injecting a rust inhibitor into a reinforced concrete structure has been theoretically described as using a pressurized osmosis flow in a reinforced concrete structure. Therefore, in order to implement this, a device for injecting a rust inhibitor while continuously applying pressure must be provided. Of course, such a device is capable of injecting the rust preventive into the drilling hole provided in the reinforced concrete structure using a separate power, such as a pump, which is difficult in construction due to the high unit cost and limited equipment.

Accordingly, the present invention proposes a device that can pressurize the rust preventive agent by generating a pressure by the restoring force of the equipment itself without using a separate power.

Figure 4 is a schematic view of the rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the present invention, Figure 5a is a perspective view showing the inside of the cylinder of the rust inhibitor indentation method used in the rust inhibitor indentation method according to the invention, Figure 5b The reference figure showing an embodiment of pulling the piston retracting means from the cylinder of the rust inhibitor indentation method used in the rust inhibitor indentation method according to the present invention, Figure 6 is fixed among the rust inhibitor indentation method used in the rust inhibitor indentation method according to the present invention Figure 7 is a cross-sectional view of the anchor, Figure 7 is a photograph of an embodiment of the rust inhibitor indentation method used in the rust inhibitor indentation method according to the present invention, Figure 8 is a fixed anchor of the embodiment of the rust inhibitor indentation apparatus used in the rust inhibitor indentation method according to the present invention It is a photograph.

As shown in FIG. 4, the present invention provides a fixed anchor 100 inserted into a drilled hole 10 of a reinforced concrete structure and a rust preventive agent connected to the fixed anchor 100 and filled therein with continuous pressurization. It is configured to include an injection cylinder 300 to fill. Here, a connection pipe 200 may be additionally provided for smooth communication between the fixed anchor 100 and the injection cylinder 300.

In addition, the rust preventive injection pump is directly connected to the fixed anchor 100 fixed to the drilling hole to directly inject the rust inhibitor into the surplus space of the drilling hole, or connected to the injection cylinder 300 to fill the rust inhibitor in the injection cylinder (not shown) ) Is also incidental but is required for the practice of the present invention.

Hereinafter, each component is explained in full detail.

- Fixed anchor (100)

As shown in FIG. 6, the fixed anchor 100 is a device that is fitted and fixed in the drilling hole 10 provided in the reinforced concrete structure, and should have a means capable of being firmly fixed to the drilling hole at the front end thereof.

The fixed anchor 100 includes a body 110, an extension sleeve 120, a connut 130, a compression packing 140, a washer 150, an anchor fixing nut 160, and an anchor valve 170 And an O-ring 180 may be provided between the washer 150 and the anchor fixing nut 160.

The body 110 has a male thread on the outer circumferential surface of the distal end 111 inserted into the drilling hole 10, a flange 113 on the outer circumferential surface, and a distal end portion located at the inlet of the drilling hole 10. A male thread is provided on the outer circumferential surface of the 112, and the end portion 114 is provided in a form capable of applying rotational force by a rotating means (bolt head 115, or straight, cross groove), and the tip portion 111. And at the outer circumferential surface of the distal end 112 is formed one or more rail grooves (116, 117) in the longitudinal direction, respectively.

Here, the rotating means may be a means for applying a rotational force, such as a spanner, a wrench or a screwdriver, and the end portion 114 may be formed by a bolt head 115 so as to rotate the body portion 110 by using the rotating means. Shaped or cross-shaped groove may be provided in the end portion 114 so as to be rotatable with a screwdriver.

Further, the rail groove 116 provided in the front end portion 111 should be provided in the flange 113 as well. This is because the rust inhibitor to be injected at a later time can be easily filled into the entire interior of the perforation hole.

The extension sleeve 120 is inserted into the distal end 111 of the body 110 so that the sleeve head 121 is hooked on the flange 114. The extension sleeve 120 is provided on the sleeve head 121, And a sleeve 122 whose outer diameter is expanded by the pressure of the sleeve 122.

Here, it is preferable that a reinforcing emboss is provided on the outer circumferential surface of the sleeve 122 to sufficiently secure frictional force.

Then, the outer surface of the sleeve 122 or the sleeve head 121 is provided with a ring-shaped anti-flip resin 123, the front end portion of the fixed anchor 100 first inserted into the drilling hole 10 is fitted by friction. To be fixed. The anti-idling resin 123 is preferably made of a plastic material which can be changed in shape by pressing. Furthermore, as the outer diameter of the sleeve 122 is extended and closely adhered to the inner circumferential surface of the drilling hole 10, the anti-fouling resin 123 is also compressed to increase the outer diameter, thereby providing additional frictional force.

The cone nut 130 is threadedly coupled to the inner circumferential surface of the body portion 100 such that a portion having a large diameter on a male or female surface provided on the outer peripheral surface of the distal end portion 111 of the body portion 100 faces the tip, And the sleeve 122 of the extension sleeve 120 is expanded so that the outer diameter of the sleeve 122 is expanded.

Due to the pressurization of the cone nut 130, the sleeve 122 of the expansion sleeve 120 is expanded to be tightly attached to the inner circumferential surface of the drilling hole 10, and the fixed anchor 100 is firmly fixed to the drilling hole 10. Will be.

In addition, the anchor fixing nut 160 has a through-hole 161 therein and has a female thread on the inner circumferential surface thereof so as to be screwed with a male thread provided on the outer circumferential surface of the distal end portion 112 of the body portion 110. The part 110 serves to tighten the fixed state in the drilling hole (10).

Of course, the anchor fixing nut 160 is provided with a stepped portion 164 to be hung around the inlet of the drilling hole 10, and part of the insertion part is inserted into the inlet of the drilling hole 10 because the diameter is small ( 165).

In addition, one or more rail grooves 163 may be formed in the longitudinal direction of the anchor fixing nut 160 to have a female screw thread to engage with the body 110, thereby providing an additional passage through which the rust preventive agent is injected.

In addition, the compression packing 140 is provided with a washer shape made of a rubber material is tightly injected into the outer peripheral surface of the drilling hole 10 in the process of tightening the anchor fixing nut 160 to the body portion 110 Prevents the leakage of rust inhibitors.

The washer 150 is provided in a shape capable of pressing the compression packing 140 as a whole and is provided between the compression packing 140 and the fixing nut 160 to tighten the fixing nut 160 Thereby helping the compression packing 140 to be tightened more firmly. Although the washer 150 is not necessarily provided as an optional component, it does not hinder the use of the present invention.

The O-ring 180 is used when the washer 150 is provided. The O-ring 180 is sandwiched between the washer 150 and the anchor fixing nut 160, .

In addition, the anchor valve 170 is provided so as to communicate with the through-hole 161 of the anchor fixing nut 160 is opened when injecting the rust inhibitor into the drilling hole 10, and leaking in the state where the rust inhibitor is injected It will act as a closing. Particularly, the anchor valve 170 is mainly used in the process of performing the pre-charging step (S5) described in the rustproofing agent injection method and removing the rustproofing agent injection pump (not shown) and connecting the injection cylinder 300.

In addition, the anchor valve 170 is provided with a quick coupling means 190 (both male and female) and is provided with a quick-action means (not shown) provided in the connection pipe 200, the injection cylinder 300, It is possible to quickly and simply engage with the coupling means (both male and female are provided so as to be paired with those provided in the anchor valve 170). As the quick coupling means utilized in the present invention, various known methods can be utilized, and a detailed description thereof will be omitted.

- Injection cylinder (300)

As shown in Figure 5a and 5b, the injection cylinder 300 is connected to the fixed anchor 100 to the device for injecting the rust inhibitor into the drilling hole 10 for a predetermined time while continuously applying pressure. It is important to have a means to continuously apply pressure.

The injection cylinder 300 includes a housing 310 having a hollow interior and a piston 310 disposed inside the housing 310 to divide the rustproofing material filling space 330 and the elastic spaces 340 and 350, A piston ring 321 fitted in the groove formed in the side of the piston 320 to maintain the airtightness between the piston 320 and the housing 310 and an anti- A rustproofing material injection port 311 provided at the upper end of the housing 310 for injecting the rustproofing material into the first elastic space 340 and the second elastic space 350 in the upper and lower spaces, One or more elastic balls 370 to be filled in the first elastic space 340 and one or more elastic springs 380 to be fitted in the second elastic space 350 .

The lower end of the housing 310 is provided with a fitting hole 312 and is fitted into the fitting hole 312 to be fixed to the lower end of the separating disc 360 to return the separating disc 360 by an external force. Retraction means 314 may further be provided.

In the present invention, the rust inhibitor is injected through the rustproofing agent inlet 311. The rust inhibitor is injected by pressing the piston 320 of the injection cylinder 300 by a rust preventive injection pump (not shown) (330). However, in this case, since the rust prevention agent must be filled while pressing the piston 320, the pumping force of the rust inhibitor injection pump (not shown) must be very strong, which may be inefficient.

Accordingly, in the present invention, the piston retracting means 314 that is thermally coupled to the separating disk 360 is provided, and the piston retracting means 314 is used to remove the rustproofing agent from the separating disk (not shown) 360 to retract the elastic spring 380 of the second elastic space 350 to relieve the pressure exerted by the rust preventive injection pump (not shown). The piston retracting means 314 can be used for various purposes such as a string, a rod and a rod. The housing 310 is provided with a piston retracting means 314 for retracting the separating disk 360, Preferably, a latch is provided to secure the means 314. Of course, since it is also possible to rapidly inject the rust inhibitor into the injection cylinder 300 in a pulled state, the provision of the latch is not essential.

5B, the piston retracting means 314 is provided as a string and the end thereof is formed in a T shape as shown in FIG. 5B. The piston retracting means 314 is retracted, It is possible to adopt a method of catching the latch 313 provided on the outer circumferential surface of the housing 310 while enclosing the outer circumferential surface.

The injection cylinder 300 uses at least one of two types of elastic bodies, that is, the elastic balls 370 and the elastic springs 380, in order to reinforce the elastic force. Because, in the present invention, it is most ideal to inject the rust preventive agent into the drilling hole 10 at the predetermined pressure as much as possible, in the case of injecting the rust preventive agent by generating a pressure by itself without an external force as in the present invention, Since it is difficult to continuously apply, it is to minimize the pressure reduction due to the reduction of the elastic force by allowing the elastic force to be supplied by a certain amount by applying the elastic force using as many elastic bodies as possible.

The elastic ball 370 filled in the first elastic space 340 may be an elastic ball made of various materials. There is no limitation on the gas filled in the elastic ball 370, but the elastic ball 370, which can provide an appropriate pressure for the purpose of the present invention Any gas is irrelevant. The gas may be a pure gas, a mixed gas, or the like.

In addition, a pressure gauge 391 is provided in the rustproofing agent inlet 311 of the injection cylinder 300 to measure the pressure generated by the injection cylinder 300 in real time.

In addition, a cylinder valve 392 is provided in the rustproofing agent inlet 311 of the injection cylinder 300 to control injection and release of the rust inhibitor. In particular, when the rust preventive agent injection pump (not shown) is connected to the injection cylinder 300 to charge the rust preventive agent and the rust preventive injection pump (not shown) is disassembled, the cylinder valve 392 must be essentially locked, It is possible to prevent the rust inhibitor from leaking due to the self-pressure of the gasket 300. Of course, when the injection cylinder 300 is connected to the fixed anchor 100 and the rustproofing agent is injected, the cylinder valve 392 must be opened.

- connecting piping (200)

The connection pipe 200 is communicated with the fixing anchor 100 at one end and communicated with the injection cylinder 300 at the other end to guide the injection of the rustproofing agent and includes an optional component to be.

The fixed anchor 100 is usually inserted into the drilling hole 10 provided in the outer wall of the vertical reinforced concrete structure vertically inserted into the outer wall is fixed and then connected to the injection cylinder 300 to indent the rust inhibitor. When the injection cylinder 300 is connected to the fixed anchor 100 in a state perpendicular to the outer wall of the structure, excessive moment is applied to the connection portion between the fixed anchor 100 and the injection cylinder 300 by its own weight. The rust inhibitor can be broken.

The connection between the fixed anchor 100 and the injection cylinder 300 may be connected using a bendable pipe so that the injection cylinder 300 is suspended from the outer wall of the reinforced concrete structure.

Further, a magnet 210 surrounding the outer circumferential surface of the connection pipe 200 is provided to smoothly guide the flow of the rust inhibitor guided to the connection pipe 200.

Any object is made up of a collection of units called molecules, each of which has a natural vibration. One molecule consists of several atoms, which are not bonded together, but continue to move, and this movement causes molecular vibration (Brownian motion effect). Magnets wrapped around the outer circumference of the pipe give 'interference vibration' to this fundamental vibration, and vibration generated from the magnet suppresses and removes the generation of rust and scale, and this effect spreads evenly in a very short time in the pipe. With this principle, the inner diameter of the pipe can be restored at a high speed, thereby facilitating the flow of the fluid into the pipe.

As a result, the vibration generated by the magnet gives the effect of interference, so that the magnitude of the vibration of the scale components dissolved in the fluid becomes smaller, so that the scale does not reach the saturated state and the scale is not precipitated. Melted and discharged quickly. Figure 8 is a conceptual diagram showing the effect of the magnet ring.

[Figure 8]

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: drilling hole
100: Fixed anchor 110: Body part
111: distal end 112: distal end
113: flange 114:
115: bolt head 116, 117: rail groove (leading end, end in order)
120: Extension sleeve 121: Sleeve head
122: Sleeve 123: Anti-rotation resin
130: Connut 140: Crimp packing
150: Washer 160: Anchor fixing nut
161: through hole 163: rail groove
164: step
165: insertion portion 170: anchor valve
180: O-ring 190: Quick coupling means
200: Connection piping 210: Magnet
300: injection cylinder 310: housing
311: rustproofing material inlet 312:
313: Catch 314: Piston retraction means
320: Piston 321: Piston ring
330: rustproofing material filling space 340: first elastic space
350: second elastic space 360: separation disk
370: Elastic ball 380: Elastic spring
391: Pressure gauge 392: Cylinder valve

Claims (9)

Diagnosing corrosion of the reinforced concrete structure to investigate the location of the corroded reinforcing bar, and selecting a location to inject the rust inhibitor to form a hole;
Installing a fixed anchor in the drilling hole;
Connecting the rust inhibitor injection cylinder to one end of the fixed anchor exposed to the inlet of the drilling hole through a connection pipe; And
And injecting the anti-corrosive agent into the periphery of the perforation hole and the perforation hole through the pumping pressure of the anti-corrosive injection cylinder;
Installing a fixed anchor in the drilling hole,
Inserting a fixed anchor which is provided on the front end of the body portion having a predetermined length and is inserted into and fixed in the drilling hole provided in the reinforced concrete wall or ceiling, so that the front end side inwards into the drilling hole and firmly fixed to the drilling hole. ; And
Anchor fixing nut provided at the distal side of the body portion and screwed to the outer circumferential surface of the body portion to close the perforation hole and having a through hole communicating with the outside of the distal end of the screw engaging portion at the distal end at the inlet of the perforation hole. Comprising;
Connecting the anti-corrosive injection cylinder to the one end of the fixed anchor through a connection pipe,
A housing having a predetermined internal space, an airtight compartment partitioning the inner space of the housing into a rust preventive filling space and an elastic space, a piston moving in a longitudinal direction, a rust preventive injection hole for communicating the rust preventive filling space with a connecting pipe, and the elastic space Filling the anti-corrosive agent of the injection cylinder comprising a separating disk partitioning into the first and second elastic space, the elastic ball is filled in the first elastic space and the elastic spring is mounted to express the elastic force in the longitudinal direction in the second elastic space Filling the space with rust inhibitor; And
And connecting the injection cylinder filled with the rust preventive agent to the fixed anchor via a connection pipe.
The method of claim 1,
Before connecting the rust inhibitor injection cylinder to the fixed anchor,
And connecting a pump to one end of the fixed anchor exposed at the inlet of the drilling hole through a pipe to prefill a rust inhibitor in the periphery of the drilling hole and the drilling hole.
delete delete The method of claim 1,
The housing is provided with a fitting hole for communicating the elastic space with the outside, and is further provided with a piston retracting means which is inserted into the fitting hole and connected to the separating disc to retract the separating disc,
When the rust inhibitor is filled in the rust preventive filling space by using the piston retracting means anticorrosive agent filling method to fill the rust inhibitor in the state in which the elastic spring is retracted.
The method of claim 5,
The outer circumferential surface of the housing is provided with a latch that can be fixed after the piston retracting means retracts the separating disk,
A rust preventive injection method for fixing the piston retracting means after retracting the elastic spring.
The method of claim 1,
Anticorrosive pressure injection method is provided with a magnet on the outer peripheral surface of the connection pipe.
The method of claim 1,
Anti-corrosive agent injection method is provided on the outside of the anti-corrosive injection port is provided with a cylinder valve for controlling the injection and discharge of the anti-corrosive agent to the rust-preventing filling space.
The method of claim 1,
Anti-corrosive agent injection method is provided on the outside of the anchor fixing nut is provided with an anchor valve for controlling the injection and outflow of the rust inhibitor into the through hole of the anchor fixing nut.

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