JP2019015594A - Porous medium evaluation method - Google Patents

Abstract

To provide a porous medium evaluation method for evaluating the durability of a porous medium easily in a short period.SOLUTION: Provided is a porous medium evaluation method for evaluating the durability of a porous medium such as a concrete body consisting of hardened concrete. The method comprises the steps of: finding, as a penetration-durability relationship, the relationship between a penetration depth when the concrete body is permeated with a coloring liquid and a neutralization speed ratio that is a barometer of durability; permeating the concrete body to be evaluated with a coloring liquid; and evaluating the durability from the penetration depth in the concrete body to be evaluated and the penetration-durability relationship.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a porous body evaluation method for evaluating durability such as neutralization, salt damage, water permeability, and air permeability of a porous body such as a concrete body obtained by curing concrete.

  It is known that when a concrete body obtained by hardening concrete is insufficient in density (solidity), deterioration factors such as carbon dioxide and salt are liable to invade and deterioration proceeds at an early stage. Therefore, in order to evaluate the density of the molded concrete body, a mercury intrusion method, a gas permeability test, a water permeability test, and the like are performed (see Patent Documents 1-3).

Patent Documents 1 and 2 disclose a method of measuring a characteristic value such as a color difference as a method for evaluating the density of a concrete structure without taking a sample. For the measurement of the color difference, a fluorescent X-ray apparatus, a color measurement apparatus, an analysis apparatus, or the like is used.
Further, Patent Document 3 describes deterioration by detecting a decrease in durability caused by salt damage, neutralization, alkali aggregate reaction, etc. by performing a test by mercury intrusion on a core collected from a concrete member. A detection method is disclosed.

JP 2012-26883 A JP 2014-44173 A JP 2011-215209 A

However, there is a demand for simply evaluating the durability of a concrete body in a short period of time because it is possible to perform a simple evaluation without using a special measuring device or time.
Accordingly, an object of the present invention is to provide a porous body evaluation method for evaluating the durability of a porous body that can be easily implemented in a short period of time.

  In order to achieve the above object, the porous body evaluation method of the present invention is a porous body evaluation method for evaluating the durability of a porous body, and can be visualized for the porous body to be evaluated. A permeation-durability relationship, which is a relationship between a permeation liquid permeation step, a permeation depth when the permeation liquid is permeated into the porous body, and a durability index, and permeation of the porous body to be evaluated And a step of evaluating durability from the depth.

  Further, another porous body evaluation method invention is a porous body evaluation method for evaluating the durability of a porous body, and the penetration depth when a visible penetrant is permeated into the porous body. And a process for obtaining the relationship between the durability index and the permeation-durability relationship, a process for allowing the permeate to permeate the porous body to be evaluated, and a penetration depth of the porous body to be evaluated And a step of evaluating durability from the permeation-durability relationship.

  Further, another porous body evaluation method invention is a porous body evaluation method for evaluating the durability of a cement-based cured body obtained by curing a cement-based material, wherein the cement-based material has a water-cement ratio changed. A process of determining the relationship between penetration depth and water cement ratio-penetration relationship by infiltrating a visible penetrant liquid into a cement-based hardened body formed of a material, the relationship between the durability index and the water cement ratio; From the water cement ratio-penetration relationship, a step of obtaining the relationship between the penetration depth and the durability index as a permeation-durability relationship, a step of penetrating the permeate into the cement-based cured body to be evaluated, And a step of evaluating durability from the penetration depth of the cement-based cured body to be evaluated and the penetration-durability relationship.

  Here, a neutralization rate ratio or a chloride ion diffusion coefficient can be used as the durability index. Moreover, it is preferable that the penetration of the penetrating liquid is performed after the drying step.

The porous body evaluation method of the present invention configured as described above allows a visible penetrant to permeate the porous body to be evaluated, and the permeation is a relationship between the penetration depth and the durability index. The durability of the porous body is evaluated by the durability relationship.
The permeation of the permeate into a porous body such as a concrete body can be performed in a short period of time such as 1 to 3 days, and the durability of the porous body can be evaluated by a simple method of measuring the penetration depth.

  In addition, when determining the relationship between the penetration depth and the durability index when penetrating the porous material into the porous body as the penetration-durability relationship, match the type and composition of the cement with the material actually used. Therefore, it becomes possible to perform more accurate evaluation.

  Furthermore, when penetrating liquid is infiltrated into a cement-based cured body obtained by curing a cement-based material with a changed water-cement ratio and the relationship between the penetration depth and the water-cement ratio-penetration relationship is obtained, If there is a known relationship with the durability index, a penetration-durability relationship can be created using this relationship.

  Further, when the durability index is a neutralization rate ratio or a chloride ion diffusion coefficient, neutralization and salt damage can be evaluated with high accuracy. Further, the permeation of the permeation liquid can be performed after a step of drying at a relatively low temperature (50 ° C. or less), for example, so that an evaluation close to the state of the actually used porous body can be made.

It is the figure which showed the relationship between the penetration depth and neutralization rate ratio which are used with the porous body evaluation method of this Embodiment. It is an illustration of the test result which measures the penetration depth when a colored liquid is penetrated into a concrete body. It is the figure which showed the relationship between water cement ratio and a penetration depth. It is the figure which showed the relationship between the penetration depth used with the porous body evaluation method of this Embodiment, and a chloride ion diffusion coefficient. It is the table | surface which showed the value of the penetration depth measured for every water cement ratio, the neutralization rate ratio, and the chloride ion diffusion coefficient.

Hereinafter, a porous body evaluation method according to an embodiment of the present invention will be described with reference to the drawings.
Cement-based hardened bodies made of hardened cement-based materials such as concrete and mortar are porous bodies in which deterioration factors such as carbon dioxide and salt gradually enter the interior from countless micropores formed on the surface. is there. Such a structure composed of a concrete body that is a porous body may deteriorate with the passage of time depending on the surrounding environment, resulting in a decrease in durability.

  It is known that it is possible to estimate how much deterioration will occur in a structure composed of a porous body by evaluating the density (solidity) after molding. . Below, the concrete body which is a porous body is made into an example, and the method to evaluate the durability of a concrete body is demonstrated.

  Generally, neutralization tests such as neutralization, salt damage, water permeability, and air permeability are known, but these tests are performed over at least half a year. In the porous body evaluation method of the present embodiment, when a colored liquid, which is a visible penetrating liquid, is infiltrated into a concrete body (cement-based cured body, porous body) in which concrete as a cement-based material is cured. Based on the penetration depth, the evaluation is performed in a short period.

  For the coloring liquid, for example, a red ink solution can be used. The red ink solution is prepared by mixing red ink and water at a ratio of 1: 1. The ratio of red ink to water is not limited to this, and any concentration that allows the penetration depth to be determined.

  The test for penetrating the red ink into the concrete body (hereinafter referred to as “red ink method”) is performed on a specimen that has been cured in water and then dried in a drying process. That is, in the wet specimen, the drying process is performed before the immersion in order to prevent the red ink from penetrating and to obtain a test result that is higher than the actual evaluation (for example, high solidity).

  For example, a concrete cylindrical specimen having a diameter of 10 cm and a height of 20 cm is cured in water at 20 ° C. for 28 days, then dried at a relatively low temperature of about 50 ° C. for 3 days, and immediately converted into a red ink solution. Soak.

The drying temperature and drying period in the drying step are not limited to this, and can be arbitrarily set. For example, if it is dried at a high temperature such as 105 ° C., it can be dried in a short period of time.
Whether or not the sample has been dried can be determined to be dry when the mass change of the specimen reaches 3 g in 2 days, according to JASS 5N T-601 “Method for testing the dry unit volume mass of concrete”. .

  On the other hand, when it is dried at a low temperature such as 50 ° C., the influence on the pore structure of the concrete body can be minimized. Since the penetration test by the red ink method does not necessarily have to be performed on an absolutely dry concrete body, the test is performed with a specimen that has been dried to a certain degree at a low temperature that has little effect on the pore structure of the concrete body. It can be carried out.

  The immersion period in the red ink solution is 1 day, the specimen is split, and the penetration depth of the red ink exposed in the cross section is measured as illustrated in FIG. FIG. 2 (a) shows a cross section of a split specimen of a case with a water cement ratio (W / C) of 43%, and FIG. 2 (b) shows a water cement ratio (W / C) of 67%. The cross section of the test piece which the case was split is shown. Here, a line tracing the position of the penetration depth with black ink is drawn inside the cross section.

  The penetration depth of the red ink was measured according to JIS A 1152 “Measurement method of neutralization depth of concrete”. This immersion period is not limited to one day, and can be, for example, three days.

The penetration test by the red ink method was performed on a plurality of specimens with different water cement ratios. FIG. 3 summarizes the test results. As can be seen from this figure, there is a correlation between the water cement ratio and the penetration depth.
That is, the penetration depth increases as the water cement ratio (W / C) increases (see FIGS. 2A and 2B). It can be said that the concrete body constructed with concrete having a large water-cement ratio is in a state in which red ink with low density (solidity) is likely to penetrate after hardening (after drying).

  Here, indexes for evaluating the durability of the concrete body include a neutralization rate ratio, a chloride ion diffusion coefficient, and the like. The “Concrete Engineering Handbook” (published by Asakura Shoten Co., Ltd., October 25, 2009) found that there is an almost linear relationship between water cement ratio and neutralization rate ratio (Hakusan) His proposal). In addition, test results indicating that there is a relationship between the chloride ion diffusion coefficient of concrete and the water cement ratio that the chloride ion diffusion coefficient increases remarkably as the water cement ratio increases are described.

  Therefore, FIG. 1 shows the result of obtaining the relationship between the penetration depth and the neutralization rate ratio as the penetration-durability relationship. That is, a test for measuring the neutralization rate was performed on a specimen having the same blending conditions as the specimen whose penetration depth was measured by the red ink method described above. As a result, it was confirmed that there was a high linear correlation between the penetration depth and the neutralization rate ratio.

  FIG. 4 shows the results of determining the relationship between the penetration depth and the chloride ion diffusion coefficient as the penetration-durability relationship. That is, the test which measures a chloride ion diffusion coefficient was implemented with respect to the test piece of the same mixing | blending condition as the test sample by which the penetration depth was measured by the red ink method mentioned above. As a result, it was confirmed that there was a high correlation between the penetration depth and the chloride ion diffusion coefficient so that a relationship curve could be drawn.

  FIG. 5 shows the results of tabulating the penetration depth, the neutralization rate ratio, and the chloride ion diffusion coefficient measured for each water cement ratio. In short, if the water cement ratio or the penetration depth of the concrete body to be evaluated is measured, the neutralization rate ratio and the chloride ion diffusion coefficient, which are durability evaluation indexes, can be obtained.

  Next, the porous body evaluation method of the present embodiment developed based on the knowledge thus obtained will be described. In the following, the neutralization rate ratio, which is an index of durability, the case where the relationship between the chloride ion diffusion coefficient and the penetration depth is determined by experiment, and the known relationship between the water cement ratio and the durability index Two cases in the case of using will be described.

  When the first penetration-durability relationship is obtained by experiment, a test for measuring the penetration depth by the above-described red ink method is performed on a plurality of concrete specimens whose water-cement ratio is changed in advance. .

  On the other hand, the neutralization rate ratio, chloride ion diffusion coefficient, etc. of the specimen with the same composition (same cement type, aggregate, water cement ratio, etc.) as the specimen subjected to the penetration depth test were used. Conduct tests to determine durability indicators. As a result, the graph showing the relationship between the penetration depth and the neutralization rate ratio shown in FIG. 1, the graph showing the relationship between the penetration depth and the chloride ion diffusion coefficient shown in FIG. 4, or both are obtained. Become.

On the other hand, when the known relationship between the second water cement ratio and the durability index is used, the permeation-durability relationship as shown in FIGS.
First, the test which measures the penetration depth by the red ink method mentioned above is implemented with respect to the test piece of the concrete which changed water cement ratio. As a result, a water cement ratio-penetration relationship that is a relationship between the water cement ratio and the penetration depth as shown in FIG. 3 is required.

On the other hand, as for the relationship between the water cement ratio and the neutralization rate ratio, a known relationship is disclosed in the “Concrete Engineering Handbook” as described above.
y = 0.05x-2.0
Here, y represents a neutralization rate ratio, and x represents a water cement ratio.

  That is, since the neutralization rate ratio can be estimated uniquely with the above equation for a certain water cement ratio, based on the water cement ratio-penetration relationship of FIG. 3, the penetration depth as shown in FIG. A graph showing the relationship with the neutralization rate ratio can be created.

As for the relationship between the water cement ratio and the chloride ion diffusion coefficient, a known relationship is disclosed in the “Concrete Engineering Handbook” as described above.
z = 10 ^∧ (-3.9x ² + 7.2x-2.5)
Here, z represents a chloride ion diffusion coefficient, and x represents a water cement ratio.

  That is, since the chloride ion diffusion coefficient can be estimated uniquely with the above equation for a certain water cement ratio, based on the water cement ratio-penetration relationship of FIG. 3, the penetration depth as shown in FIG. A graph showing the relationship with the chloride ion diffusion coefficient can be created.

  After preparing to obtain an index of durability from the penetration depth by the penetration-durability relationship as shown in FIGS. 1 and 4 by any of the methods described above, for the porous body to be evaluated, The penetration test is performed by the red ink method.

  The porous body to be evaluated is a specimen (concrete body, cement-based hardened body) manufactured with the same composition as the concrete actually used. The specimen after finishing the curing and drying process after curing is immersed in the red ink solution for 1 day.

  After immersion, the specimen is taken out from the red ink solution, the specimen is split, and the penetration depth of the red ink exposed on the cross section is measured. Then, based on the measured penetration depth, the neutralization rate ratio is read from the relationship between the penetration depth and the neutralization rate ratio shown in FIG. If the neutralization speed ratio of the concrete used for construction can be estimated, the durability regarding the neutralization of concrete can be evaluated.

  Further, based on the measured penetration depth, the chloride ion diffusion coefficient can be read from the relationship between the penetration depth and the chloride ion diffusion coefficient shown in FIG. If the chloride ion diffusion coefficient of concrete used for construction can be estimated, the durability of concrete against salt damage can be evaluated.

Next, the effect | action of the porous body evaluation method of this Embodiment is demonstrated.
In the porous body evaluation method of the present embodiment configured as described above, the red ink solution is infiltrated into the concrete body to be evaluated, and the penetration depth and durability index (neutralization rate ratio, chloride) The durability of the concrete body is evaluated by the permeation-durability relationship, which is a relationship with the material ion diffusion coefficient.

The penetration of the colored liquid into the concrete body can be carried out in a short period such as 1 to 3 days, and the durability of the concrete body can be evaluated by a simple method of measuring the penetration depth.
In other words, the conventional neutralization test took at least half a year before the test result was obtained, but the porous body evaluation method of the present embodiment can be easily and economically implemented in a short period of time. Effective quality control can be performed by increasing the evaluation frequency.

  In addition, when the relationship between the penetration depth and the durability index when the red ink solution is infiltrated into concrete is determined as the permeation-durability relationship, the type and composition of cement and the like should be matched to the concrete actually used. Therefore, more accurate evaluation can be performed.

  Furthermore, when a red ink solution is infiltrated into concrete with a changed water cement ratio and the relationship between the penetration depth is obtained as a water cement ratio-penetration relationship, a known relationship between the water cement ratio and the durability index. If there is, it can be used to create a penetration-durability relationship. That is, it is economical because the time-consuming neutralization test can be omitted.

  Further, when the durability index is a neutralization rate ratio or a chloride ion diffusion coefficient, neutralization and salt damage can be evaluated with high accuracy. Furthermore, penetration of the red ink solution is performed on a material dried at a relatively low temperature of about 50 ° C., depending on the specimen in a state in which the concreteness is equivalent or close to that of the concrete actually used. Testing and evaluation can be performed.

  The embodiment of the present invention has been described in detail above with reference to the drawings. However, the specific configuration is not limited to this embodiment, and design changes that do not depart from the gist of the present invention are not limited to this embodiment. Included in the invention.

  For example, in the above-described embodiment, the durability evaluation index has been described in detail with respect to neutralization and salt damage, but is not limited thereto, and the durability index with respect to water permeability and air permeability is also included. Can be applied.

  Moreover, in the said embodiment, although the concrete body was demonstrated to the example as a porous body, it is not limited to this, The cement-type hardened | cured material which hardened the mortar which is a cement-type material, tile, brick, or It can also be applied to the evaluation of the durability of porous materials such as stone.

  Furthermore, in the said embodiment, although the coloring liquid was demonstrated as the osmosis | permeation liquid which can be visualized, it is not limited to this. For example, a penetrating liquid containing a fluorescent substance that emits light when exposed to black light can be used. In this case, even if the permeation liquid permeates the existing structure, it can be made not conspicuous. Alternatively, the penetrant may be transparent and the depth of penetration can be confirmed by applying or spraying a visualization liquid.

Claims (5)

A porous body evaluation method for evaluating the durability of a porous body,
A step of allowing a visible penetrant to permeate a porous body to be evaluated; and
A step of evaluating the durability from the penetration-durability relationship, which is the relationship between the penetration depth and the durability index when the permeate is permeated into the porous body, and the penetration depth of the porous body to be evaluated. A porous body evaluation method comprising: A porous body evaluation method for evaluating the durability of a porous body,
A step of determining the relationship between the penetration depth and the durability index when the permeating liquid that can be visualized into the porous body is infiltrated, as the penetration-durability relationship;
Infiltrating the permeate with respect to the porous body to be evaluated;
A porous body evaluation method comprising: a step of evaluating durability from the penetration depth of the porous body to be evaluated and the penetration-durability relationship. A porous body evaluation method for evaluating the durability of a cement-based cured body obtained by curing a cement-based material,
Infiltrating a visible penetrant liquid into a cement-based cured body formed of a cement-based material with a changed water-cement ratio to obtain a relationship with the penetration depth as a water-cement ratio-penetration relationship;
From the relationship between the durability index and the water cement ratio and the water cement ratio-penetration relationship, the step of determining the relationship between the penetration depth and the durability index as the penetration-durability relationship;
A step of infiltrating the permeate with respect to the cement-based cured body to be evaluated;
A porous body evaluation method comprising: a step of evaluating durability from a penetration depth of the cement-based cured body to be evaluated and the penetration-durability relationship.   4. The porous body evaluation method according to claim 1, wherein the durability index is a neutralization rate ratio or a chloride ion diffusion coefficient. The porous body evaluation method according to any one of claims 1 to 4, wherein the permeation of the permeation liquid is performed after the drying step.