JP7276756B1 - Manufacturing method of concrete using carbon dioxide nanobubble water - Google Patents

Abstract

A method for producing concrete using CO2 nanobubble water, which is highly effective in reducing carbon dioxide and densifying concrete, is provided. In a method for producing concrete using carbon dioxide nanobubble water, concrete is produced using carbon dioxide nanobubble water containing fine carbon dioxide gas bubbles with a diameter of 1 μm or less in kneading water for producing concrete. . A mixture of carbon dioxide nanobubble water and a calcium hydroxide solution is used as kneading water. [Selection figure] None

Description

The present invention relates to a method for producing concrete using carbon dioxide nanobubble water ( _CO2 nanobubble water).

In recent years, the reduction of carbon dioxide, which is considered to be a cause of global warming, has been called out on a global scale. On the other hand, in the global trend of specifying the performance of concrete structures, there is a growing interest in extending the life (high durability) of structures. As such, densification is required. For this reason, research is being conducted to fix carbon dioxide as calcium carbonate in concrete to make the concrete denser and of higher quality.

Therefore, the inventors of the present application have found that it is possible to produce _CO2 nanobubble water (NBW) by enclosing _CO2 in a microbubble device, so that _CO2 nanobubble water can be used to produce concrete structures. I came to think that it might be possible to solve both the problem of carbon dioxide reduction and the densification of concrete structures by doing so.

For example, Patent Document 1 has a step of preparing carbonated bubble water and a first carbonated bubble water introduction step of introducing the carbonated bubble water into a substance having a hardened cement body, thereby improving the quality of the hardened cement body. (See claim 1 of Patent Document 1, paragraphs [0019] to [0038] of the specification, etc.).

Further, Patent Document 2 discloses a carbonation curing method for a concrete water storage structure 1 having a water storage area 11 capable of storing water, the inner wall surface of the water storage area 11 being composed of a cement-based hardening body, wherein the water storage area 11 is a closed space, and a water injection step of pouring carbon dioxide-dissolved water 2A into the water storage area 11 is disclosed. 2 claim 1, paragraphs [0025] to [0034] of the specification, etc.).

However, the method for improving the quality of the cement hardened body described in Patent Document 1 and the carbonation curing method for the concrete water storage structure described in Patent Document 2 both of the already hardened cement hardened body and the concrete water storage structure. Carbonated bubble water was used as curing water. For this reason, since carbonated water is supplied after the hydration reaction has already progressed, although it is said that densification can be achieved, not only is it not sufficient, but also the effect of reducing carbon dioxide is not sufficient. As will be described later, according to experiments conducted by the inventors of the present application, it was not possible to confirm a remarkable effect of densifying concrete even when carbon dioxide nanobubble water (NBW) was used as the curing water.

JP 2014-214030 A JP 2015-54806 A

Therefore, the present invention has been devised in view of the above-mentioned problems, and the purpose thereof is to produce concrete using CO ₂ nanobubble water, which has a high effect of reducing carbon dioxide and densifying concrete. It is to provide a manufacturing method.

A method for producing concrete using carbon dioxide nanobubble water according to claim 1 is a method for producing concrete using carbon dioxide nanobubble water, and is a method of pressurizing and dissolving in one direction in kneading water when producing concrete. At least 5 minutes at least 5 minutes Concrete is produced using a mixture of carbon dioxide nanobubble water containing fine carbon dioxide gas bubbles having a diameter of 100 nm or less and a calcium hydroxide solution .

The method for producing concrete using carbon dioxide nanobubble water according to claim 2 is the method for producing concrete using carbon dioxide nanobubble water according to claim 1, wherein a calcium hydroxide solution is used as curing water for the concrete. Characterized by

ADVANTAGE OF THE INVENTION According to the invention which concerns on Claim 1 and 2 , while being able to make concrete dense and quality-improving, emission of a carbon dioxide can be reduced.

FIG. 1 is a bar graph showing the cumulative water permeability for 7 days using functional water as kneading water in a W/C=65% water permeability test. FIG. 2 is a bar graph showing the cumulative water permeability for 6 days using a 28-day-old specimen using functional water as kneading water in the water permeability test. FIG. 3 is a bar graph showing the cumulative water permeability for 7 days of a 28-day-old specimen cured with tap water using functional water as kneading water for the water permeability test. Fig. 4 shows the cumulative water permeability of a 28-day-old specimen that was cured with pure water until 7 days of material age, and cured with functional water from 7 days of material age, using pure water as the kneading water for the same water permeability test. 2 is a bar graph showing amounts; FIG. 5 is a bar graph showing the cumulative water permeability for 7 days of a 28-day-old specimen cured with tap water using functional water as kneading water for a W/C=35% water permeability test. Fig. 6 shows the cumulative water permeability for 7 days using a 28-day-old specimen cured with tap water until 7 days old using pure water as the kneading water for the water permeability test, and then cured with functional water from 7 days old. 2 is a bar graph showing amounts; FIG. 7 is a bar graph showing the cumulative water permeability over 7 days of a 28-day-old specimen cured with pure water using functional water as kneading water for a W/C=35% water permeability test. FIG. 8 is a bar graph showing the cumulative water permeability for 7 days of a 28-day-old specimen cured with functional water using pure water as kneading water in the water permeability test. FIG. 9 is a bar graph showing the cumulative water permeability for 7 days of a 28-day-old test piece cured with calcium hydroxide Ca(OH) ₂ saturated supernatant using functional water as kneading water in the water permeability test. Fig. 10 shows a 28-day-old test specimen that was cured with pure water until 7 days of material age using functional water as the kneading water for the same water permeability test, and then sprayed with functional water from 7 days of material age. is a bar graph showing the cumulative water permeation amount.

An embodiment of a concrete manufacturing method using carbon dioxide nanobubble water according to the present invention will be described below.

<Method for producing concrete using carbon dioxide nanobubble water>
In the concrete manufacturing method using carbon dioxide nanobubble water according to the embodiment of the present invention (hereinafter also simply referred to as the present concrete manufacturing method), first, a predetermined unit water amount (W), A mixture is determined so as to achieve a predetermined water/cement ratio (W/C), a predetermined fine aggregate ratio (S/A), and a predetermined air content (a), and the required amount of each material is calculated.

Then, in the concrete manufacturing method of the present invention, the amount of cement, coarse aggregate, fine aggregate, various admixtures and admixtures according to the determined composition is added as kneading water to a predetermined unit water amount (W) of carbon dioxide Concrete is produced using nanobubble water (CO ₂ NBW).

Here, carbon dioxide nanobubble water refers to water containing fine bubbles of carbon dioxide gas with a diameter of nano-order (1 μm or less). The concept includes macro-nanobubble water containing fine carbon dioxide gas (1 to 100 μm).

In addition, as a method for generating carbon dioxide nanobubbles, there is a "swirling flow method" in which carbon dioxide gas and water are mixed and swirled at high speed to create carbon dioxide bubbles. The "pressurized dissolution method" that creates carbon dioxide bubbles by releasing them all at once, the "microporous method" that creates carbon dioxide bubbles by applying pressure to carbon dioxide gas through fine holes such as orifices, and the super Examples include the “ultrasonic method,” which causes cavitation with sound waves to expand carbon dioxide gas in water to form carbon dioxide bubbles. However, the method for generating carbon dioxide nanobubble water is not particularly limited, and any method may be used as long as it can generate macro-nanobubble water containing fine carbon dioxide gas of micro order (1 to 100 μm).

However, in the present concrete manufacturing method, carbon dioxide nanobubble water is generated by the 1-pass method or the 2-minute loop method of the above-mentioned “pressure dissolution method” using a manufacturing apparatus manufactured by Dan-Takuma. This is because a large amount of carbon dioxide nanobubble water can be produced easily and inexpensively in a short time.

It should be noted that the carbon dioxide nanobubble water exerts a predetermined effect by using the water that has been produced by the production apparatus for at least 5 minutes. In the meantime, it may be left open or stored in a container for a long period of time. When used as kneading water or as water for mixing with a saturated calcium hydroxide solution, the effect does not change even if several months have passed since the production.

Carbon dioxide nanobubbles according to the present invention have a diameter smaller than 200 nm and are stable for a long period of time. Since a large amount of particles smaller than 100 nm are included, measurement is difficult, but the amount of carbon dioxide included in the carbon dioxide nanobubbles is 0.03% or less with respect to the volume of the aqueous solution. This is a method using ultrasonic waves, in which ultrasonic waves are emitted to carbon dioxide nanobubble water, and the bubbles that rise from the solution are trapped in a Le Chatelier bottle or the like, and the volume and carbon dioxide concentration of the resulting gas are measured. It is required by

However, the carbon dioxide bubbles according to the present invention have nothing to do with dissolved carbon dioxide, as can be seen even after several months of production. When ultrasonic waves are emitted to an aqueous solution, some of the dissolved carbon dioxide gasifies as bubbles, so the volume of the carbon dioxide nanobubbles themselves cannot be measured accurately. As a method, a strong acid such as hydrochloric acid is added to carbon dioxide nanobubble water to lower the pH to about 4, and then a gas not containing carbon dioxide such as nitrogen gas is bubbled for about 3 hours. This allows most of the dissolved carbon dioxide to be released into the air. After that, a base such as sodium hydroxide is added to return the pH to a neutral range of about 7, and then ultrasonic waves are applied. From this, it can be seen that the amount of bubbles (the amount of carbon dioxide) contained in the carbon dioxide nanobubbles according to the present technology is 0.03% or less of the volume of the aqueous solution. Note that nanobubbles are bubbles that are nearly spherical, and exist in a state of being pressurized by the effect of surface tension. Most nanobubbles are smaller than 100 nm and the pressure inside the bubble is higher than 30 atmospheres. Therefore, the accurate volume (total amount) of carbon dioxide nanobubbles is 1/30 or less of the amount of carbon dioxide obtained under atmospheric pressure.

In addition to the carbon dioxide nanobubble water, in the method for producing the present concrete, a mixture obtained by substituting 25% to 50% by weight of the carbon dioxide nanobubble water with a calcium hydroxide saturated solution in the kneading water is used. is preferred. This is because ionized Ca ²⁺ and OH ⁻ of calcium hydroxide can penetrate into the capillary voids of the concrete and densify the concrete.

In the present method for producing concrete, as the curing water for the concrete, supernatant water saturated with calcium hydroxide (calcium hydroxide saturated solution) is used to cure the concrete until a predetermined strength is obtained. As with kneading water, ionized Ca ²⁺ and OH ⁻ of calcium hydroxide supplied as curing water can not only penetrate into the capillary voids of concrete to densify concrete, This is because it can enter cracks and suppress cracking of concrete.

According to the concrete manufacturing method using the carbon dioxide nanobubble water according to the embodiment of the present invention described above, the concrete can be densified, and the quality and durability of the concrete can be improved. In addition, carbon dioxide can be immobilized in concrete, which is used in large amounts in industry, although the amount is very small with respect to the weight of concrete, thereby suppressing the emission of carbon dioxide.

In addition, according to the concrete manufacturing method using carbon dioxide nanobubble water according to the present embodiment, since a calcium hydroxide solution is used as kneading water and curing water, ionized Ca ²⁺ and OH ⁻ are generated in the capillary voids of concrete. It can not only penetrate into the concrete and densify the concrete, but also suppress the cracking of the concrete.

The concrete manufacturing method using carbon dioxide nanobubble water according to the embodiments of the present invention has been described in detail above. It is nothing more than an indication of Therefore, the technical scope of the present invention should not be construed to be limited by these.

In particular, as concrete, cement is used as a binding material to bind aggregates, but the concrete according to the present invention refers to concrete in a broad sense, and cement is used to bind aggregates. Composite materials in which coarse aggregates and fine aggregates are solidified with binders such as lime, gypsum, asphalt, and plastics. This is because, when carbon dioxide nanobubble water is used as the kneading water, it is believed that carbon dioxide can be converted into calcium carbonate and fixed in the microscopic spaces in the concrete.

<W / C = 65% water permeability test>
Next, a water permeability test performed to verify the effect of the method for producing concrete using carbon dioxide nanobubble water according to the present invention will be described. In this water permeability test, multiple types of concrete slabs were prepared as specimens, water permeability tests were performed, and the cumulative water permeability (ml) was measured.

The basic composition of the concrete of the specimen is: (1) Unit water content (W) = 175 (kg/m ³ ) (2) Water/cement ratio (W/C) = 65% (3) Fine aggregate ratio (S/ A) = 50% (4) Air content (a) = 4.5%. More specifically, they were blended as shown in Table 1 below.

(Functional water (CO ₂ NBW) in kneading water)
In addition, in the production of concrete as a specimen, functional water containing carbon dioxide nanobubble water in kneading water (hereinafter referred to as It is simply called functional water.) was used. Three types of carbon dioxide nanobubble water (CO ₂ NBW) A, B, and C with different manufacturing conditions were used as the functional water used to manufacture concrete specimens. As shown in Table 2 below, the three types A, B, and C are manufactured under the conditions of sodium chloride (NaCl), potassium chloride (KCl), and calcium sulfate dihydrate (CaSO ₄ 2H ₂ O), the components of magnesium nitrate hexahydrate water (Mg(NO ₃ )·6H ₂ O), and the manufacturing method of carbon dioxide nanobubble water are different.

For comparison, a specimen was also produced using pure water and a calcium hydroxide Ca(OH) ₂ solution as kneading water. In addition, as functional water, 25 to 50% by weight of calcium hydroxide saturated solution is added to the carbon dioxide nanobubble water by replacing the carbon dioxide nanobubble water by 25 to 50% by weight to three types of carbon dioxide nanobubble water just before kneading. Then, specimens were prepared from concrete prepared with a total of 8 types of kneading water, and a water permeability test was conducted.

In addition, 1 pass (method) of the carbon dioxide nanobubble water production method shown in Table 2 refers to simply generating carbon dioxide nanobubbles by a pressure dissolution method in one direction, and a 2-minute loop (method) is It refers to generating carbon dioxide nanobubbles by repeatedly pressurizing and dissolving by circulating for 2 minutes so as to increase the concentration.

Concrete slab specimens manufactured using the above eight different types of water for kneading were subjected to water permeability tests for 7 days from the day after the 7th day of material age, and the cumulative water permeability (ml) was measured. Fig. 2 shows the cumulative water permeability (ml) measured by conducting a water permeability test from 28 days to 6 days.

As shown in the graph in Fig. 1, the cumulative permeation amount decreased in all cases compared to the test specimens using pure water as the mixing water. It can be seen that there is an effect of densification and quality improvement. In other words, it was found that the use of carbon dioxide nanobubble water as the kneading water for concrete contributes to the densification of concrete.

Moreover, it was found that even when a calcium hydroxide solution was used as the kneading water, it contributed to the densification of the concrete at the early stage of the concrete effect of 7 days old. In addition, it was found that the use of a mixture of carbon dioxide nanobubble water substituted with 25% to 50% saturated calcium hydroxide solution as the kneading water further contributes to the densification of the concrete.

Then, as shown in FIG. 2, in the water permeability test for 6 days from the 28th, when it is considered that the concrete developed a predetermined strength, three types A, B, and C using carbon dioxide nanobubble water as kneading water were tested. It can be seen that the densification of concrete was greatly promoted in all cases. On the other hand, when the calcium hydroxide solution was mixed, the densification of the concrete was not promoted, indicating that the effect of the carbon dioxide nanobubble water was great.

(Functional water for kneading water + tap water for curing water)
Next, in the same manner as described above, a concrete slab specimen manufactured using a total of 8 different types of water for kneading was cured using tap water as curing water until the material age was 28 days, and then cured for 7 days. Fig. 3 shows the results obtained by conducting a water permeability test and measuring the cumulative water permeability (ml).

The graph in FIG. 3 shows almost the same results as those shown in FIG. 2, and the densification of concrete was greatly promoted in all three types A, B, and C using carbon dioxide nanobubble water as kneading water. I understand. On the other hand, when the calcium hydroxide solution was mixed, the densification of the concrete was not promoted, indicating that the effect of the carbon dioxide nanobubble water was great.

(pure water for kneading water + functional water for curing water)
Next, the basic composition of concrete is as described above: (1) Unit water content (W) = 175 (kg / m3) (2) Water / cement ratio (W / C) = 65% (3) Fine aggregate Ratio (S/A) = 50% (4) Air content (a) = 4.5% (composition shown in Table 1), and pure water was used as kneading water to prepare 8 samples of the same composition. A sample was manufactured. Then, three types of carbon dioxide nanobubble water (CO ₂ NBW) of A, B, and C shown in Table 2 are produced, and a total of eight different types of water are used as curing water in the same manner as the functional water described above. Fig. 4 shows the cumulative water permeation amount (ml) measured by performing a water permeability test for 7 days after curing until the material age is 28 days.

As shown in the graph of FIG. 4, even when three types of carbon dioxide nanobubble water (CO ₂ NBW), A, B, and C, are used as curing water, all are cumulative than when pure water is used as curing water. As a result, the amount of water permeation exceeded. In other words, even if carbon dioxide nanobubble water (CO ₂ NBW) was used as the curing water, no concrete densification effect was observed.

On the other hand, when calcium hydroxide Ca(OH) ₂ saturated supernatant was used as curing water, the effect of densification of concrete was confirmed. The effect of densifying concrete was confirmed even when three types of carbon dioxide nanobubble water, A, B, and C, were mixed with 25% to 50% of calcium hydroxide saturated solution.

This is probably because most of the carbon dioxide nanobubbles could not penetrate because the diameter of the capillary voids in the concrete was only about 100 nm. On the other hand, in the calcium hydroxide solution, it is considered that ionized Ca ²⁺ and OH ⁻ were able to penetrate into the capillary spaces.

<W / C = 35% water permeability test>
Next, multiple types of concrete slabs with water-cement ratios, which are mixing conditions that differ greatly from the above-mentioned test specimen, were prepared, and a water permeability test was conducted from 28 days to 7 days, and the cumulative water permeability (ml) was measured. Then, it was verified whether or not it was the same as the result of the W/C = 65% water permeability test described above.

The basic composition of concrete for this test is as follows: (1) Unit water content (W) = 165 (kg/m ³ ) (2) Water/cement ratio (W/C) = 35% (3) Fine aggregate ratio (S/A) = 43% (4) Air content (a) = 4.5%. More specifically, they were blended as shown in Table 3 below.

(Functional water (CO ₂ NBW) in kneading water)
First, in order to verify the effect of using functional water as kneading water, functional water was used as kneading water when producing concrete specimens. Three types of carbon dioxide nanobubble water (CO ₂ NBW), A, B, and C shown in Table 2, were used as the functional water, as in the W/C=65% water permeability test.

As in the W/C=65% water permeability test, pure water and calcium hydroxide Ca(OH) ₂ solution were used as kneading water for comparison. In addition, as the functional water, three types of carbon dioxide nanobubble water were added with a calcium hydroxide solution of 25 to 50% by weight based on the carbon dioxide nanobubble water immediately before kneading, and W / In the same manner as the C=65% water permeability test, a water permeability test was carried out by preparing specimens made of concrete produced with eight types of kneading water.

Concrete slab specimens manufactured using a total of eight different types of water as kneading water were cured using tap water as curing water until the age of 28 days. Fig. 5 shows the cumulative water permeation amount (ml) measured by the test.

As shown in the graph of FIG. 5, similarly to the W/C = 65% water permeability test, the cumulative water permeability decreased in all cases compared to the test specimen using pure water as the kneading water. It can be seen that the use of the above-mentioned functional water has the effect of densifying concrete and improving its quality. In other words, it was confirmed that even a concrete having a W/C ratio of 35% can be densified by using carbon dioxide nanobubble water as the concrete kneading water.

As in the W/C = 65% water permeability test, it was confirmed that even when the calcium hydroxide solution was used as the kneading water, it contributed to the densification of the concrete at the early stage of the concrete effect at the age of 7 days. . In addition, it was found that the use of a mixture of carbon dioxide nanobubble water substituted with 25% to 50% saturated calcium hydroxide solution as the kneading water further contributes to the densification of the concrete.

(pure water for kneading water + functional water for curing water)
Next, the basic composition of concrete is as described above: (1) Unit water content (W) = 165 (kg/m ³ ) (2) Water/cement ratio (W/C) = 35% (3) Fine bone Material ratio (S/A) = 43% (4) Air content (a) = 4.5%, pure water was used as kneading water, and 8 specimens with the same composition were produced. Then, three types of carbon dioxide nanobubble water (CO ₂ NBW) of A, B, and C shown in Table 2 are produced, and a total of eight different types of water are used as curing water in the same manner as the functional water described above. Fig. 6 shows the cumulative water permeation amount (ml) measured by performing a water permeability test for 7 days after curing until the material age is 28 days.

As shown in the graph of FIG. 6, even when three types of carbon dioxide nanobubble water (CO ₂ NBW) of A, B, and C are used as curing water, compared with the case of using pure water as curing water , Type B carbon dioxide nanobubble water (CO ₂ NBW) has a lower cumulative water permeation rate, but Type A and C carbon dioxide nanobubble water results in an increase in cumulative water permeation rate. In other words, even if carbon dioxide nanobubble water (CO ₂ NBW) was used as the curing water, no significant concrete densification effect was observed.

On the other hand, when a calcium hydroxide Ca(OH) ₂ solution was used as the curing water, the effect of densifying concrete was confirmed as in the W/C=65% water permeability test. The effect of densifying concrete was confirmed even when three types of carbon dioxide nanobubble water, A, B, and C, were mixed with 25% to 50% of calcium hydroxide saturated solution. This is also the same result as the W/C=65% water permeability test.

(Functional water for kneading water + Functional water for curing water)
As described above, in the results of the W/C = 65% water permeability test and the W/C = 35% water permeability test, the densification when carbon dioxide nanobubble water (CO ₂ NBW), which is functional water, is used as kneading water. The effect was confirmed, and the usefulness of using functional water as curing water could not be confirmed. Based on this result, we investigated the usefulness of using functional water for kneading water and the supernatant liquid saturated with calcium hydroxide Ca(OH) ₂ , which was confirmed to have a dense effect, and the method of supplying curing water. Verification was performed when functional water was supplied after changing to spray curing.

For comparison, as pattern 1, functional water is used again for kneading water, pure water is used for curing water, and the material is aged from 0 to 28 days, and then a water permeability test is performed for 7 days. FIG. 7 shows the measured cumulative water permeation amount (ml).

Specifically, as described above, (1) unit water content (W) = 165 (kg / m3) (2) water / cement ratio (W / C) = 35% (3) fine aggregate rate (S / A) = 43% (4) Air content (a) = 4.5%.

In addition, this time, the kneading water was (1) pure water, (2) calcium hydroxide Ca(OH) ₂ solution, (3) A type carbon dioxide nanobubble water (CO ₂ NBW), (4) B type carbon dioxide A total of five types of nanobubble water (CO ₂ NBW) and (5) C-type carbon dioxide nanobubble water (CO ₂ NBW) were used to prepare specimens, and a water permeability test was conducted.

Pattern 2 uses pure water for kneading water, uses functional water for curing water, cures from 0 days to 28 days of age, and then conducts a water permeability test for 7 days and the cumulative water permeability (ml) is shown in FIG.

However, even in the case of functional water, this time, (1) pure water, (2) calcium hydroxide Ca(OH) ₂ saturated supernatant, (3) A type carbon dioxide nanobubble water (CO ₂ NBW), (4) A water permeation test was performed by using only five types of B-type carbon dioxide nanobubble water (CO ₂ NBW) and (5) C-type carbon dioxide nanobubble water (CO ₂ NBW).

Pattern 3 is kneaded water with (1) pure water, (2) calcium hydroxide Ca(OH) ₂ solution, (3) A type carbon dioxide nanobubble water (CONBW), (4) B type carbon dioxide nanobubble water (CO ₂ NBW), and (5) C-type carbon dioxide nanobubble water (CO ₂ NBW). However, calcium hydroxide Ca(OH) ₂ solution is used for the curing water, and the material is aged from 0 to 28 days. FIG. 9 shows the measured values.

Pattern 4 is kneading water containing (1) pure water, (2) calcium hydroxide Ca(OH) ₂ solution, (3) A type carbon dioxide nanobubble water (CO ₂ NBW), (4) B type carbon dioxide nanobubble water ( CO ₂ NBW) and (5) C-type carbon dioxide nanobubble water (CO ₂ NBW).

And also for the curing water, (1) pure water, (2) calcium hydroxide Ca(OH) ₂ solution, (3) A type carbon dioxide nanobubble water (CO ₂ NBW), (4) B type carbon dioxide nanobubble water (CO ₂ NBW), (5) C-type carbon dioxide nanobubble water (CO ₂ NBW), a total of five types of functional water (including pure water for comparison) were used. However, the method of supplying the curing water was to cure with pure water until the age of 7 days, and then to spray curing by spraying the curing water from the surface of the specimen for 5 minutes a day. In this way, after curing with pure water up to 7 days of material age, a total of 5 types of functional water (including pure water for comparison) were used to cure from 8 days to 28 days of material age, and then for 7 days. Fig. 10 shows the results obtained by conducting a water permeability test and measuring the cumulative water permeability (ml).

As is clear from the graph of FIG. 7, it can be seen that the densification of concrete was significantly promoted in all three types A, B, and C using carbon dioxide nanobubble water as kneading water. On the other hand, even when a calcium hydroxide solution is mixed, the effect of densifying concrete can be confirmed.

In the graph of FIG. 8, unlike the graph of FIG. 6, even when A to C type carbon dioxide nanobubble water (CO ₂ NBW) is used as the curing water, it is different from the case where pure water is used as the curing water. The effect of densification can be confirmed by comparison. However, the densification effect was lower when carbon dioxide nanobubble water was used than when only calcium hydroxide Ca(OH) ₂ solution was used as curing water. Therefore, based on the results of FIG. 6, no significant effect of densification of concrete is observed when carbon dioxide nanobubble water is used as curing water for concrete, but calcium hydroxide Ca(OH) ₂ solution is used as curing water for concrete. A remarkable effect of densification of concrete was confirmed when it was used as

As is clear from the graph in FIG. 9, when carbon dioxide nanobubble water was used as kneading water and calcium hydroxide Ca(OH) ₂ solution was used as curing water, densification of concrete was significantly promoted. I understand. Moreover, even when a saturated solution of calcium hydroxide and carbon dioxide nanobubble water are mixed as curing water, the effect of densifying concrete can be confirmed.

In the graph of FIG. 10, even when A to C type carbon dioxide nanobubble water (CO ₂ NBW) is used as the curing water, the effect of densification can be confirmed as compared to the case where pure water is used as the curing water. However, when compared with the graph in FIG. 7, it cannot be said that the densification of concrete was promoted, and it is considered that the effect of using carbon dioxide nanobubble water as kneading water is greater than the effect of using carbon dioxide nanobubble water as curing water. be done. Therefore, when the carbon dioxide nanobubble water was used as the curing water, it was not possible to confirm the remarkable concrete densifying effect of the carbon dioxide nanobubble water even when it was supplied by spraying.

Claims (2)

A method for producing concrete using carbon dioxide nanobubble water,
1 pass (method) that generates carbon dioxide nanobubbles in the kneading water when manufacturing concrete by a pressure dissolution method in one direction, or a repeated pressure dissolution method that circulates so that the concentration increases to generate carbon dioxide nanobubbles. Concrete using a mixture of carbon dioxide nanobubble water containing fine carbon dioxide gas bubbles with a diameter of 100 nm or less that has been generated by any of the loops (methods) for at least 5 minutes or more and a calcium hydroxide solution A method for producing concrete using carbon dioxide nanobubble water, characterized by producing The method for producing concrete using carbon dioxide nanobubble water according to claim 1, wherein a calcium hydroxide solution is used as curing water for the concrete.

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