KR20160073757A - Method for monitering chloride penetration into reinforced concrete with high conductive cement composite - Google Patents

Abstract

The purpose of the present invention is to provide a method for detecting the penetration of chloride into reinforced concrete using a high-conductive cement composite capable of accurately detecting the penetration of chloride into the concrete and measuring the content of the chloride by using the high-conductive cement composite having properties of which conductance is charged only by a change in moisture containing chloride such as seawater without being influenced by a change in normal moisture. To achieve this, the method for detecting the penetration of chloride into the reinforced concrete using the high-conductive cement composite includes: a step of preparing the high-conductive cement composite wherein conductive materials, cement, and water are mixed at a predetermined mixing rate and metallic electrode plates are inserted and installed in both sides: a step of arranging the high-conductive cement composite at a position adjacent to rebar arranged inside a concrete structure; a step of electrically connecting measuring equipment to the electrode plates inserted and installed in both sides of the high-conductive cement composite; and a step of monitoring a conductive change of the high-conductive cement composite caused by the penetration of chloride into the concrete structure using the measuring equipment.

Description

[0001] METHOD FOR MONITORING CHLORIDE PENETRATION INTO REINFORCED CONCRETE WITH HIGH CONDUCTIVE CEMENT COMPOSITE [0002]

The present invention relates to a method of detecting chlorine penetration in a reinforced concrete using a high-conductivity cement composite material, and more particularly, to a method of detecting chlorine penetration in a reinforced concrete using a highly conductive cement composite material, And the like.

Chlorine infiltration promotes the corrosion of reinforcing bars in reinforced concrete and is pointed out as the main cause of decrease of durability of reinforced concrete. Especially, in the case of concrete structures such as bridges and breakwaters at the coast, if the salinity of seawater penetrates into the concrete cracks, the rebar is easily corroded and adversely affects the structural stability. Since the volume of iron oxide is larger than that of iron, the reinforcing steel is expanded when the reinforcing steel is corroded. If cracks are further generated around the reinforcing steel due to the expansion pressure, the concrete structure itself can not be used.

Therefore, in order to maintain the structural stability of concrete, it is important to quickly identify the extent of chlorine penetration in the concrete structure and maintain its position appropriately. However, it is very difficult to monitor the chlorine content penetrated into concrete in real time. One method is to crush concrete structures and spray an aqueous solution of nitric acid to observe changes in color.

This method has a disadvantage that it can not be applied to all structures because it needs to destroy a part of the existing concrete structure. Even if it can be applied, there is a problem that only the penetration depth of chlorine can be confirmed and it is difficult to confirm the concentration of chlorine.

As another method for measuring the degree of corrosion of concrete, "Investigation on the Development of Embedded Mini Sensor for Non-destructive Reinforced Corrosion Diagnosis" (Non-Patent Document 1) is described in Structural Diagnosis Journal Vol. 14, No. 6 This is briefly described with reference to FIG.

The mini sensor 4 is previously embedded so as to be adjacent to the reinforcing bar 2 before the concrete structure specimen 1 in which the reinforcing bars 2 are installed is manufactured. Thereafter, concrete having a certain proportion of cement, aggregate, and water is placed to produce a concrete structure specimen (1). The reinforcing bars 2 and the mini-sensors 4 are electrically connected to the measuring instrument 5, respectively. Corrosion meter 3, which was installed on the concrete surface to measure the electrochemical characteristics (natural potential, polarization resistance, resistivity) of the concrete, was also electrically connected to the meter 5 for comparison with the mini sensor 4 .

As a result of the experiment, the difference between the measurement value by the corrosion meter 3 and the measurement value by the mini sensor 4 tends to decrease as the corrosion of the reinforcing bar progresses. Therefore, even with the nondestructive measurement method using the buried minisensor 4, It was confirmed that the infiltration of chlorine could be monitored.

However, even if this nondestructive measurement method is used, since the change of the polarization resistance is measured only after the corrosion of the reinforcing bar starts, the corrosion of the reinforcing bar itself can not be prevented in advance, The change in electrical conductivity of the mini sensor 4 has a problem in that it can not accurately measure the chlorine permeability and the chlorine content because it changes not only with the chlorine content but also with the water content in the concrete, the boundary condition and the structure shape.

 "A Fundamental Study on Development of Embedded Mini Sensor for Nondestructive Steel Corrosion Diagnosis", Journal of Structural Diagnostics, Vol. 14, No. 6 (2010. 11. Open), 179 ~ 187 pp.

The present invention has been developed in order to solve such a conventional problem, and it is an object of the present invention to provide a high conductivity cement composite material which is not affected by a change in general moisture and has a characteristic that electric conductivity changes only in a change of moisture including chlorine The present invention provides a method of detecting a chlorine permeation in a reinforced concrete using a high-conductivity cement composite material which can precisely measure chlorine content and its chlorine content in concrete.

In order to accomplish the above object, there is provided a method of detecting chlorine permeation in a reinforced concrete using a high-conductivity cement composite material according to the present invention, comprising the steps of mixing a conductive material, cement and water at a predetermined mixing ratio, A step of preparing the installed high-conductivity cement composite material; Disposing the highly conductive cementitious composite material at a position adjacent to the reinforcing bars laid in the concrete structure; Casting the concrete to produce the concrete structure; Electrically connecting measurement equipment to the electrode plate inserted on both sides of the high-conductivity cement composite material; And monitoring a change in electrical conductivity of the highly conductive cementitious composite material due to chlorine penetration through the concrete structure through the measurement equipment.

In addition, the conductive material is preferably at least one conductive material selected from the group consisting of carbon nanotubes, carbon fibers, graphite, and coke.

Also, the conductive material is carbon nanotubes, and it is preferable to mix the carbon nanotubes in an amount of 0.4 to 0.6 wt% based on the weight of the cement.

Further, it is preferable that the high-conductivity cement composite material is produced by further blending the fine aggregate.

In addition, it is preferable that the step of arranging the high-conductivity cement composite material is to place the high-conductivity cement composite material between the reinforcing bars and the concrete surface of the concrete structure to which chlorine is to be infiltrated.

In addition, the monitoring of the electrical conductivity change preferably measures the change in electrical conductivity of the highly conductive cementitious composite material due to chlorine penetration in real time or periodically.

According to another aspect of the present invention, there is provided a method of manufacturing a high-conductivity cement composite material, comprising: mixing a conductive material, cement, and water at a predetermined mixing ratio; Forming a cut groove having a predetermined length on a surface of a previously installed concrete structure; Inserting the highly conductive cement composite material into the cut groove and inserting an electrode plate made of a metal material on both sides of the highly conductive cement composite material; Electrically connecting measurement equipment to the electrode plate inserted on both sides of the high-conductivity cement composite material; And monitoring a change in electrical conductivity of the highly conductive cementitious composite material due to chlorine penetration through the concrete structure through the measurement equipment.

In addition, the conductive material is preferably at least one conductive material selected from the group consisting of carbon nanotubes, carbon fibers, graphite, and coke.

Also, the conductive material is carbon nanotubes, and it is preferable to mix the carbon nanotubes in an amount of 0.4 to 0.6 wt% based on the weight of the cement.

Further, it is preferable that the high-conductivity cement composite material is produced by further blending the fine aggregate.

It is preferable that the cutting grooves are formed so that the high-conductivity cement composite material is disposed between the reinforcing bars laid in the concrete structure provided with the base and the concrete surface on which the chlorine is to be infiltrated.

The step of injecting the highly conductive cement composite material into the cut groove may further include finishing the concrete by placing the concrete in the cut groove.

In addition, the monitoring of the electrical conductivity change preferably measures the change in electrical conductivity of the highly conductive cementitious composite material due to chlorine penetration in real time or periodically.

According to the method of detecting chlorine penetration in a reinforced concrete using the highly conductive cement composite material according to the present invention, it is possible to monitor whether or not the concrete is infiltrated with chlorine in real time or periodically by a method that does not destroy the concrete structure.

Also, a highly conductive cement composite material is disposed between the surface of the concrete structure and the reinforced steel disposed in the interior of the concrete structure, and the change in electrical conductivity caused by the contact of chlorine with the highly conductive cement composite material can be detected. As a result, it is possible to monitor the penetration of chlorine before the chlorine comes into contact with the reinforcing bar, so that proper maintenance work can be performed, so that the corrosion of the reinforcing bar can be prevented in advance.

Also, since the high-conductivity cement composite material is the same material as the concrete structure, it can be used for a long period of time because the thermal expansion coefficient is the same and no dropout due to thermal expansion / thermal expansion occurs.

In addition, since a high-conductivity cement composite material can be directly used in the field, it is excellent in workability and workability.

In addition, since only the electric conductivity is measured, an expensive system for processing complicated data is not required, so that it can be implemented at a low cost.

1 is a diagram illustrating a conventional non-destructive chlorine infiltration detection method.
[0001] The present invention relates to a high-strength cementitious composite material,
Figure 3 compares the electrical conductivity range of a highly conductive cementitious composite material according to the present invention.
4 is a graph showing changes in electric conductivity of carbon nanotubes in a state where they are not mixed.
FIG. 5 is a graph showing the change in electrical conductivity of a carbon nanotube mixed with 0.3 weight%. FIG.
FIG. 6 is a graph showing changes in electric conductivity of a carbon nanotube mixed with 0.6% by weight. FIG.
7 is a flowchart showing a chlorine infiltration sensing method in a reinforced concrete using a high-conductivity cement composite material according to the present invention for a new concrete structure.
8 is a view of a highly conductive cement composite material provided with an electrode plate.
9 is a diagram illustrating a configuration in which a highly conductive cement composite material according to the present invention is disposed.
10 is a flowchart showing a chlorine infiltration sensing method in a reinforced concrete using a highly conductive cement composite material according to the present invention with respect to a previously installed concrete structure.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

The present invention provides a simple method for monitoring whether or not chlorine has penetrated into reinforced concrete by using a highly conductive cement composite material having a sensitive change in electric conductivity to chlorine, and what amount of chlorine has penetrated. For this purpose, as shown in FIG. 2, the high-conductivity cement composite material 10 is extended to a predetermined position of the concrete structure by a required length. For example, the high-conductivity cement composite material 10 may be installed vertically or horizontally on the outer wall of the high-rise concrete building 11 (upper left figure) or installed at a constant depth on the surface facing the sea in the coastal breakwater 12 (Upper right picture).

The reason for using the highly conductive cement composite material in the present invention is that it shows a change in the electric conductivity which is sensitive only to the target chlorine.

The electric conductivity value of general concrete material changes greatly depending on the shape and moisture content of the concrete. The conventional non-destructive chlorine infiltration detection method described with reference to FIG. 1 has not been able to detect whether or not the chlorine infiltration has been accurately detected because the electrical property value has been changed not only by the chlorine content but also by the water content, the boundary condition, As shown above. The present inventor has solved the problems of the conventional method described above by changing the electrical conductivity of the water containing salt (chlorine) to produce a sensitive high-conductivity cement composite material while the change of the electric conductivity according to general moisture is small .

FIG. 3 is a graph showing the variation of the electric conductivity of the highly conductive cementitious composite material according to the present invention and the variation of the electric conductivity according to the kind of water. Generally, when electrolytic ions such as chlorine are dissolved in water, electrical conductivity increases. Electrolyte solutions such as seawater have a higher electrical conductivity, about 100 to 10,000 times higher than ordinary water. Therefore, if a high conductivity cement composite has a medium conductivity between seawater and general water, penetration of ordinary water into the composite will have little effect on the change in electrical conductivity. However, if a high electrolyte solution such as seawater penetrates, Will vary greatly.

The highly conductive cementitious composite material according to the present invention is prepared so as to have a medium conductivity between sea water and ordinary water by mixing a conductive material, cement and water at a predetermined mixing ratio. To this end, at least one conductive material selected from the group consisting of carbon nanotubes, carbon fibers, graphite, and coke is used as the conductive material.

Carbon nanotube (CNT) is one of the advanced nanomaterials. Since its discovery in 1991, CNT has been steadily researched and commercialized in various fields based on its unique structural, chemical, mechanical and electrical properties due to highly stable chemical bonding come. In other words, carbon nanotubes are as high in electrical conductivity as copper, have the same thermal conductivity as natural diamond, and have a strength 100 times higher than steel, but with an elongation of more than 15%.

However, in the course of using carbon nanotubes dispersed in various matrix materials, it is difficult to study due to low dispersion performance of carbon nanotubes, and thus, its use as a construction material has been limited. The present inventors have developed a cement composite material in which carbon nanotubes, silica fume, polycarboxylic acid-based admixture, and cement are blended to improve the dispersibility of carbon nanotubes. Korean Registered Patent No. 10-1339904 entitled "Method of producing cement composite material containing carbon nanotube and method of manufacturing carbon nanotube-cement structure using the cement composite material". The present inventors have developed a method capable of effectively detecting the infiltration of chlorine by using the technique of manufacturing a cement composite material containing such a carbon nanotube.

Carbon fiber is a fiber made by heating organic fibers (rayon, pitch, etc.) at high temperature over 1,000 ℃ to make carbon content more than 90%. Since Edison first developed Edison in 1879, It is a new material widely used in all industries such as automobile, civil engineering, architecture, electricity, electronics, sports, and leisure. The carbon fiber has properties of high electrical conductivity as well as high strength / high elasticity. Therefore, when dispersed in cement, a highly conductive cement composite material can be produced.

In addition, Graphite, which is widely used as an electrode material, and porous cokes formed by coking of coking coal at high temperature are materials having high electrical conductivity mainly composed of carbon, so when dispersed and mixed in cement, highly conductive cement A composite material can be produced.

FIGS. 4 to 6 show experimental results for making a cement composite material having optimum conductivity capable of detecting the penetration of chlorine in concrete using carbon nanotubes among the above-described conductive materials.

To prepare the high conductivity cement composites for this experiment, one kind of portland cement, silica fume, colloidal anionizer, carbon nanotube and distilled water are prepared. 0.3 wt.% And 0.6 wt.% Of the carbon nanotubes were added to the cement so that the mixing ratio (weight ratio) was 1.0, silica fume 0.2, and superfluidizer 0.005 to 0.02 (depending on the situation) 0% by weight and 5% by weight of sodium chloride (NaCl) are added to the distilled water, and uniformly mixed to prepare a high conductivity cement composite specimen.

This high - conductivity cement composite specimen is made in the form of a rectangular prism of 2 cm x 2 cm x 8 cm, and an office tack is inserted and cured at both ends of the prism as an electrode plate. The conductivity was measured (saturation specimen) after dipping for 14 days or more in the mold, and the conductivity was measured after drying for 7 days at room temperature after dipping in the moisture of the sample and sodium chloride (NaCl) (Dry specimen). The electrical conductivity was measured by using a portable measuring device with a probe attached to an electrode plate made of office tack, and then the results of a plurality of specimens were averaged.

FIG. 4 shows the result of measurement of electric conductivity of a general cement composite material having a carbon nanotube content of 0 wt%, FIG. 5 shows a result of measurement of electric conductivity of a low conductive cement composite material having an incorporated amount of carbon nanotubes of 0.3 wt% 6 is a result of measurement of electric conductivity of a highly conductive cement composite material in which the mixing amount of carbon nanotubes is 0.6% by weight.

As can be seen from comparison between FIG. 4 and FIG. 6, the electric conductivity of the high-conductivity cement composite material is about 0.09 mS / m when the electric conductivity of the general cement composite material is the highest (saturated specimen with 5% NaCl) (Saturation specimens with 5% NaCl) were found to be about 100 mS / m higher than 100 times. Since the high conductivity cement composites have a higher electrical conductivity than the general cement composites, the change in electrical conductivity is largely increased with chlorine penetration.

For example, as shown in FIG. 4, the electrical conductivity of the saturation specimen with 0% NaCl is about 0.015 mS / m and the conductivity of saturated specimen with 5% NaCl is about 0.095 mS / m. That is, the electrical conductivity increased by 0.08 mS / m when the chlorine content increased by 5%. On the other hand, as shown in FIG. 6, the electrical conductivity of the saturable specimen having a NaCl content of about 35 mS / m and the saturation specimen having a NaCl concentration of 5% showed a conductivity of about 82 mS / m. That is, when the chlorine content increased by 5%, the electrical conductivity increased as high as 47 mS / m. As described above, the conductivity of the highly conductive cement composite material according to the present invention is much more sensitive to changes in the electrical conductivity with increasing chlorine content, so that chlorine permeation can be easily monitored using the same.

On the other hand, as shown in FIG. 6, the electrical conductivity of the dried specimen of 0% NaCl was about 20 mS / m and the electrical conductivity of the dried specimen of 5% NaCl was about 38 mS / m. That is, when the chlorine content increased by 5%, the electrical conductivity increased by 18 mS / m. As described above, it can be seen that the use of the highly conductive cement composite material of the present invention increases the electrical conductivity as the content of chlorine increases regardless of changes in the water content of the concrete. Therefore, according to the present invention, chlorine infiltration can be effectively detected regardless of the moisture content of the concrete structure.

However, as shown in FIG. 5, in the case of the low-conductivity cement composite material containing only 0.3 wt% of the carbon nanotubes, irregular electrical conductivity changes such as decrease of the electric conductivity despite the increase of the chlorine content were shown. For example, the electrical conductivity of saturated specimens with 0% NaCl is about 0.88 mS / m, while the conductivity of saturated specimens with 5% NaCl is about 0.1 mS / m. That is, although the chlorine content increased by 5%, the electrical conductivity decreased to 0.78 mS / m. The same results were obtained for the dried specimens.

In the case of low conductivity cement composites, the dispersion of the conductive material is not uniformly distributed inside the cemented composite material. Therefore, the variation of the electric conductivity is irregular. On the other hand, And the change of the electric conductivity according to the temperature is stable.

Considering this point, it is preferable to mix the carbon nanotubes in an amount of 0.4 to 0.6% by weight based on the weight of the cement when carbon nanotubes are incorporated into the highly conductive cement composite material according to the present invention. If the content of carbon nanotubes is less than 0.4 wt%, irregular electrical conductivity changes are observed despite the increase of chlorine content as shown in FIG. 5, so it is difficult to accurately determine the chlorine penetration, and the content of carbon nanotubes If it exceeds 0.6% by weight, it is difficult to mix with cement, and the uniform dispersibility may be lowered.

4 to 6, when the general cement composite material having a carbon nanotube content of 0 wt% has the same electrical conductivity as that of a general concrete, it is preferable to use the shape and water content of the surrounding concrete The electrical conductivity may vary. On the other hand, the high conductivity cement composites with carbon nanotubes content of 0.6 wt% have very high electrical conductivity compared to the surrounding concrete. Therefore, the electric conductivity is not likely to change according to the shape and water content of the concrete, The electric conductivity changes only by the supercharged solution such as seawater. Therefore, it is more preferable to use a high-conductivity cement composite material to monitor the penetration of chloride into the concrete structure.

Meanwhile, the highly conductive cement composite material according to the present invention is preferably made of a cement material having basically similar physical properties to concrete. As a result, since they have the same thermal expansion coefficient, they do not fall off due to an additional heat shrinkage / expansion, and thus can be used for a long time. Therefore, a high conductivity cement composite material can be manufactured by further mixing fine aggregate in order to prepare the same composition ratio as that of the surrounding concrete and more accurately match the physical properties of the material.

Hereinafter, a method for detecting chlorine infiltration in a reinforced concrete using a highly conductive cement composite material according to the present invention will be described in detail with reference to FIGS. 7 to 10. FIG.

7 shows a process of installing a high-conductivity cement composite material according to the present invention in a new concrete structure.

First, a conductive material, cement, and water are mixed at a predetermined mixing ratio, and a high conductivity cement composite material is prepared by inserting an electrode plate made of metal on both sides (S10). At this time, it is already described that the conductive material uses at least one material selected from the group consisting of carbon nanotube, carbon fiber, graphite and coke.

FIG. 8 shows an example in which a pair of electrode plates 15 made of a metal material is provided at one end of a high-conductivity cement composite material 10 of a certain standard. Although not shown in FIG. 8, the highly conductive cementitious composite material 10 is provided with electrode plates 15 of the same shape at the other end after being formed to have a predetermined length. As the material of the electrode plate 15, a metal having a high electrical conductivity such as a copper plate is often used, but other materials having the same level can be used.

Next, the highly conductive cement composite material is disposed at a position adjacent to the reinforcing bars laid in the concrete structure (S11). More specifically, as shown in FIG. 9 (a), the highly conductive cement composite material 10 is placed between the reinforcing bars 30 and the concrete structure 20 between the concrete surface (the lower surface of the drawing) into which chlorine is to be infiltrated can do. As a result, when the chlorine is penetrated through the surface of the concrete structure 20 as shown in FIG. 9 (b), the measuring instrument 40 connected to the high-conductivity cement composite 10 before contacting the reinforcing bar 30, The change in electrical conductivity will detect the penetration of chlorine. When the penetration of chlorine is detected, an appropriate maintenance work is carried out so that chlorine can come into contact with the reinforcing bars 30 to prevent corrosion from occurring.

After the placement of the high-conductive composite material is completed, a new concrete structure is prepared by pouring the concrete (S12), and the measurement equipment is electrically connected to the electrode plate inserted into both sides of the high- Through the measurement equipment, a change in electrical conductivity of the highly conductive cement composite material due to chlorine penetration in the concrete structure is monitored in real time or periodically (S14).

The real-time monitoring is configured to automatically check the change in the electrical conductivity through data processing while continuously connecting the measuring device to the electrode plate, and automatically alert the manager through an alarm when a change over a certain range is detected . On the other hand, the periodic monitoring is configured to visit the site at predetermined intervals, connect the measuring equipment to the electrode plate to check the change in electrical conductivity, and to perform maintenance work required when an abnormality is found in comparison with the previous recording .

10 shows a process of installing a highly conductive cementitious composite material according to the present invention on a concrete structure installed.

First, a conductive material, cement, and water are mixed at a predetermined mixing ratio to produce a high-conductivity cement composite material (S20). At this time, it is already described that the conductive material uses at least one material selected from the group consisting of carbon nanotube, carbon fiber, graphite and coke.

Next, cutting grooves of a predetermined length are formed on the surface of the previously installed concrete structure using a device such as a power saw (S21). The high-conductivity cement composite material is charged into the cut-off grooves, and an electrode plate made of a metal material is inserted into both sides of the high-conductivity cement composite material (S22). As a result, as shown in Fig. 9, the high-conductivity cement composite material 10 is placed between the reinforcing bars 30 and the concrete structure 20 between the concrete surface (the lower surface of the drawing) into which chlorine is to be infiltrated.

When the placement of the high-conductivity cement composite material is completed, concrete is poured into the inside of the cut-off groove to protect the high-conductivity cement composite material from external temperature changes, impact, etc. (S23). However, this finishing process is not essential and may be omitted. That is, as the simplest method, the high conductive composite material may be cured and fixed while being exposed to the outside of the cut groove.

Thereafter, the measurement equipment is electrically connected to the electrode plate installed on both sides of the high-conductivity cement composite material (S24). Then, the conductivity of the high-conductivity cement composite material due to chlorine penetration through the concrete structure The change is monitored in real time or periodically (S25).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

10: High Conductivity Cement Composite 20: Concrete Structure
30: Rebar 40: Measuring equipment

Claims (13)

Preparing a high-conductivity cement composite material in which conductive material, cement and water are mixed at a predetermined mixing ratio and electrode plates made of metal are inserted into both sides;
Placing the highly conductive cementitious composite material at a position adjacent to the reinforcing bars laid in the concrete structure
Casting the concrete to produce the concrete structure;
Electrically connecting measurement equipment to the electrode plate inserted on both sides of the high-conductivity cement composite material; And
And monitoring a change in electrical conductivity of the highly conductive cement composite material due to chlorine penetration through the concrete structure through the measurement equipment. The method according to claim 1,
Wherein the conductive material is at least one conductive material selected from the group consisting of carbon nanotubes, carbon fibers, graphite, and cokes. The method of claim 2,
Wherein the conductive material is carbon nanotubes, and the conductive material is mixed with 0.4 to 0.6 wt% based on the weight of the cement, wherein the high conductivity cement composite material is used for detecting chlorine permeation in a reinforced concrete. The method according to any one of claims 1 to 3,
Wherein the high-conductivity cement composite material is manufactured by further compounding fine aggregate. The method according to claim 1,
Wherein the step of arranging the high-
Wherein the high-conductivity cement composite material is disposed between the reinforcing bars and the concrete surface to be infiltrated with chlorine in the concrete structure. The method according to claim 1,
Wherein monitoring the electrical conductivity change comprises:
Wherein the change in electrical conductivity of the highly conductive cement composite material due to chlorine penetration is measured in real time or periodically. Mixing a conductive material, cement and water at a predetermined mixing ratio to produce a high-conductivity cement composite material;
Forming a cut groove having a predetermined length on a surface of a previously installed concrete structure;
Inserting the highly conductive cement composite material into the cut groove and inserting an electrode plate made of a metal material on both sides of the highly conductive cement composite material;
Electrically connecting measurement equipment to the electrode plate inserted on both sides of the high-conductivity cement composite material; And
And monitoring a change in electrical conductivity of the highly conductive cement composite material due to chlorine penetration through the concrete structure through the measurement equipment. The method of claim 7,
Wherein the conductive material is at least one conductive material selected from the group consisting of carbon nanotubes, carbon fibers, graphite, and cokes. The method of claim 8,
Wherein the conductive material is carbon nanotubes, and the conductive material is mixed with 0.4 to 0.6 wt% based on the weight of the cement, wherein the high conductivity cement composite material is used for detecting chlorine permeation in a reinforced concrete. The method according to any one of claims 7 to 9,
Wherein the high-conductivity cement composite material is manufactured by further compounding fine aggregate. The method of claim 7,
The cutting groove forming step may include:
Wherein the cutting grooves are formed so that the cutting grooves are disposed between the reinforcing bars laid in the concrete structure provided with the high-conductivity cement composite material and the concrete surface to be infiltrated with chlorine in the concrete structure. My chlorine infiltration detection method. The method of claim 7,
The step of injecting a high-conductivity cement composite material into the cut-
The method of claim 1, further comprising the step of applying a concrete to the inside of the cut groove to finish the cementitious composition. The method of claim 7,
Wherein monitoring the electrical conductivity change comprises:
Wherein the change in electrical conductivity of the highly conductive cement composite material due to chlorine penetration is measured in real time or periodically.

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