JP2009046336A - Repairing material and repairing method of concrete - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a repairing material of concrete which has excellent adhesion strength to concrete to be repaired without performing a curing in water, and to provide a repairing method using the repairing material. <P>SOLUTION: The repairing material of concrete comprises cement, aggregate and water, wherein the aggregate is an artificial lightweight aggregate which has pores in its inside and the 24 hr water absorption rate of which is >3.5%. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a repair material for repairing a concrete portion such as a building structure and a concrete repair method.

Concrete is used in various structures (hereinafter referred to as concrete structures) such as building structures, but cracks and cracks may occur due to various factors during the period of use. Such cracks and cracks degrade the structural performance that concrete should have and may have an important impact on safety.
Therefore, it is necessary to repair concrete that has cracks or cracks. By repairing the concrete, the functional properties of the concrete can be improved and the durability can be improved.

As a concrete repair method, a method using a repair material containing cement, aggregate, and water can be cited (for example, see Patent Document 1 below). Specifically, the repair material is applied to the surface of the portion of the concrete to be repaired (hereinafter referred to as the concrete to be repaired) to be repaired or is injected into the cracks or cracks and then cured. By doing.
Examples of the aggregate include natural aggregates such as sand, crushed sand, gravel, and crushed stone.

  Further, when repairing concrete to be repaired using a repair material, it is important to improve the adhesion strength between the repaired concrete and the repair material. This is because by improving the adhesion strength between the concrete to be repaired and the repair material, the repair material can be made difficult to peel from the concrete to be repaired, and the durability of the concrete structure after repair can be improved.

  Here, in order to improve the adhesion strength, it is necessary to supply moisture to the interface between the repair material and the concrete to be repaired. By supplying moisture, a hydration reaction of the cement occurs at the interface, and the adhesion strength between the repair material and the concrete to be repaired is improved.

Examples of a method for supplying moisture to the interface between the repair material and the concrete to be repaired include a method of using moisture in the aggregate of the repair material. Specifically, before the cement and water are mixed with the aggregate, the aggregate is preliminarily mixed with water by immersing the aggregate in water. Here, the natural aggregate is defined in the JIS standard as having a 24-hour water absorption of 3.5% or less. This is because when the water absorption rate for 24 hours exceeds 3.5%, the strength of the repair material itself decreases.
However, if the water absorption rate for 24 hours is 3.5% or less, even if the natural aggregate is immersed in water, sufficient moisture cannot be contained inside the natural aggregate. The material cannot supply sufficient water to the interface with the concrete to be repaired. Therefore, the effect of improving the adhesion strength with the concrete to be repaired cannot be sufficiently achieved, and the durability of the concrete structure after repair cannot be improved.
The 24-hour water absorption is the ratio of the mass of the total water contained in the aggregate after being immersed in water for 24 hours from the absolutely dry state to the mass of the aggregate in the absolutely dry state. Is a value measured by the method defined in JIS A 1134 and coarse aggregate is defined in JIS A 1135.

On the other hand, a method of supplying moisture to the interface between the repair material and the concrete to be repaired by performing curing after applying and injecting the repair material in water can also be mentioned.
However, some concrete structures cannot be immersed in water in many cases, and in such a case, curing in water cannot be performed.
For concrete structures that cannot be cured in this way, it is difficult to supply moisture to the interface between the repair material and the concrete to be repaired. The effect of improvement could not be fully achieved.

JP 2000-327392 A

  The present invention has been made in view of the above problems, and provides a concrete repair material excellent in adhesion strength with repaired concrete and a repair method using the repair material without performing curing in water. This is the solution issue.

  The invention according to claim 1 is an artificial lightweight aggregate in which a cement, aggregate, and water-containing concrete repair material, wherein the aggregate has voids therein and has a water absorption rate of over 3.5% for 24 hours. The present invention relates to a concrete repair material characterized by being.

  The invention according to claim 2 relates to a concrete repair material according to claim 1, wherein the aggregate has a 24-hour water absorption rate of 7% or more.

  The invention according to claim 3 relates to the concrete repair material according to claim 1 or 2, wherein the aggregate is a fine aggregate.

  In the invention according to claim 4, the aggregate has a 24-hour water absorption of 7 to 13%, an absolutely dry density of 1.60 to 1.75 kg / L, and a coarse particle ratio of 2.50 to 2. 90. The concrete repair material according to claim 3, wherein the actual volume ratio is 52 to 58%.

  The invention according to claim 5 relates to a concrete repair material according to any one of claims 1 to 4, characterized in that it contains steel fibers or synthetic resin fibers.

  The invention according to claim 6 includes a step of adding cement and water to an artificial lightweight aggregate having a void and having a water absorption rate of more than 3.5% for 24 hours and mixing the mixture into a repair material, and repairing the repair material. The present invention relates to a method for repairing concrete, characterized by sequentially performing a step of applying or pouring the target concrete and a step of curing the concrete applied or injected with the repair material.

  The invention according to claim 7 is a method for repairing concrete according to claim 6, wherein in the step of curing the concrete, curing is performed by covering a portion where the repair material is applied or injected with a curing sheet. About.

  The invention according to claim 8 relates to the concrete repairing method according to claim 6, wherein in the step of curing the concrete, curing is performed in water.

  According to the first aspect of the present invention, the aggregate is an artificial lightweight aggregate having voids inside and having a water absorption rate of more than 3.5% for 24 hours, so that a large amount of moisture is contained in the voids. It becomes. Therefore, moisture inside the artificial lightweight aggregate is supplied to the interface between the repair material and the concrete to be repaired (repair concrete), and a hydration reaction of the cement occurs. Therefore, the adhesion strength between the repair material and the concrete to be repaired can be increased without performing curing in water.

  According to the invention of claim 2, the aggregate has a 24-hour water absorption rate of 7% or more, so that more water can be contained inside the artificial aggregate, and only a cement hydration reaction occurs. Can be reliably supplied to the interface between the repair material and the concrete to be repaired.

  According to the third aspect of the invention, since the aggregate is a fine aggregate, the artificial lightweight aggregate can contain a large amount of moisture, so that the adhesion strength with concrete can be further improved.

  According to the invention according to claim 4, when the aggregate is a fine aggregate, the 24-hour water absorption rate of the aggregate is 7 to 13%, the absolute dry density is 1.60 to 1.75 kg / L, The coarse grain ratio is 2.50 to 2.90, and the actual volume ratio is 52 to 58%, so that the moisture in the artificial lightweight aggregate is easily supplied to the interface between the repair material and the concrete to be repaired. And the hydration reaction of cement is likely to occur. Therefore, the adhesion strength between the repair material and the concrete to be repaired can be reliably improved.

  According to the invention which concerns on Claim 5, the intensity | strength of repair material itself can be improved by containing a steel fiber or a synthetic resin fiber. That is, it is possible to compensate for a decrease in strength of the repair material itself due to having the artificial lightweight aggregate.

  According to the invention of claim 6, a step of adding cement and water to an artificial lightweight aggregate having a void and having a water absorption rate of more than 3.5% for 24 hours and mixing it into a repair material; Since the process of applying or injecting to the concrete to be repaired and the step of curing the concrete to which the repair material has been applied or injected are sequentially performed, the artificial aggregate can contain a large amount of water, so repair Moisture inside the artificial lightweight aggregate is supplied to the interface between the material and the concrete, and a hydration reaction of the cement can be caused. Thereby, in the concrete after repair, the adhesion strength of a repair material and repaired concrete can be improved.

  According to the invention which concerns on Claim 7, even when it cannot cure in water by performing curing by covering the part by which the repair material was apply | coated or inject | poured with a curing sheet, it can cure easily. . Moreover, even if it repairs using a curing sheet because repair material contains an artificial lightweight aggregate, the adhesive strength with to-be-repaired concrete can be made high.

  According to the invention which concerns on Claim 8, much moisture can be supplied to the interface of repair material and to-be-repaired concrete by performing curing in water, and it can produce the hydration reaction of cement reliably. it can. Thereby, the adhesion strength between the repair material and the concrete to be repaired can be further improved.

  Hereinafter, a concrete repair material according to an embodiment of the present invention will be described. However, the following embodiment does not limit the present invention.

  The concrete repair material according to the present embodiment is cement, aggregate, water-containing concrete or mortar, and an artificial lightweight aggregate is used as the aggregate.

As cement, ordinary Portland cement, early strong Portland cement, super early strong Portland cement, moderate heat Portland cement, low heat Portland cement, sulfate-resistant Portland cement and other various Portland cements, blast furnace cement, fly ash cement, silica cement, etc. Mention may be made of cement. Among them, early-strength Portland cement and super-early-strength Portland cement are preferable because large strength can be obtained in a short time after applying or injecting a repair material.
However, the cement used for the repair material according to the present embodiment is not limited to the exemplified one.

The artificial lightweight aggregate which is the aggregate of the present embodiment is obtained by using natural rock minerals such as expansive shale, expansive viscosity, expansive slate, and calcined fly ash as raw materials, and artificially calcining and foaming them. It is an aggregate and has voids inside the aggregate. And the 24-hour water absorption exceeds 3.5%. In addition, it is lighter and stronger than natural aggregates.
In addition, the artificial lightweight aggregate is mixed with cement and water with moisture inside. Here, since the artificial lightweight aggregate has voids inside and the water absorption rate exceeds 3.5% for 24 hours, it can contain a large amount of moisture inside. That is, a high water absorption rate can be obtained as compared with natural aggregate (24-hour water absorption rate of 3.5% or less).
When repairing concrete (repair concrete) to be repaired using such a repair material containing artificial lightweight aggregate, the moisture of the repair material is sufficiently supplied to the interface between the repair material and the concrete to be repaired. Will be. Therefore, a cement hydration reaction occurs at the interface, and the adhesion strength between the repair material and the concrete to be repaired can be improved. Thereby, it can prevent that repair material peels from to-be-repaired concrete, and can make durability of the concrete after repair sufficiently high.

In addition, since the artificial lightweight aggregate contains a lot of moisture, it is possible to prevent the repair material from drying during curing, and to prevent the repair material from shrinking.
Furthermore, even if a long time elapses after repairing concrete, water is released from the inside of the artificial lightweight aggregate, so that a decrease in humidity inside the concrete can be suppressed. Thereby, it can also prevent that a crack and a crack arise newly.

  Further, the artificial lightweight aggregate preferably has a 24-hour absorption rate of 7% or more, and more preferably 9% or more. As a result, more moisture can be contained inside the artificial aggregate, and sufficient moisture can be supplied to the interface between the repair material and the concrete to be repaired to cause a cement hydration reaction. It is.

In addition, the relationship between the 24-hour water absorption rate of the artificial lightweight aggregate and other physical properties will be described. When the artificial lightweight aggregate is a fine aggregate, when the 24-hour water absorption rate is 7 to 13%, the absolute dry density is 1.60 to 1.75 kg / L, coarse particle ratio is preferably 2.50 to 2.90, and actual volume ratio is preferably 52 to 58%, especially when the 24-hour water absorption is 9 to 11%. The absolute dry density is preferably 1.65 to 1.75 kg / L, the coarse particle ratio is 2.50 to 2.80, and the actual volume ratio is 52 to 54%. Further, when the artificial lightweight aggregate is a coarse aggregate, when the water absorption rate for 24 hours is 7 to 13%, the absolute dry density is 1.20 to 1.34 kg / L, and the coarse grain ratio is 6.05 to 6. 65, the actual volume ratio is preferably 60 to 65%, and particularly when the 24-hour water absorption is 9 to 11%, the absolute dry density is 1.20 to 1.30 kg / L and the coarse particle ratio is 6. It is preferable that it is 05 to 6.65 and the actual volume ratio is 63 to 65%. Since the artificial lightweight aggregate is in the range as described above, the moisture inside the artificial lightweight aggregate is easily supplied to the interface between the repair material and the concrete to be repaired. This is because the adhesion strength between the repair material and the concrete to be repaired can be reliably improved.
The absolute dry density is a value obtained by dividing the absolute dry mass by the absolute volume of the aggregate. The fine aggregate is measured by the method defined in JIS A 1109 for fine aggregate and JIS A 1110 for coarse aggregate. Value. In addition, the grain ratio is 80, 40, 20, 10, 5, 2.5, 1.2, 0.6, 0.3, and 0.15mm. The value obtained by dividing the sum of the weight percentages of the quantity by 100. The actual volume ratio is the ratio of the volume actually occupied by the artificial lightweight aggregate, that is, the ratio of the volume excluding the void portion, and is a value measured by the method defined in JIS A 1104.

Artificial lightweight aggregates can be classified into fine aggregates (particle size range 0.05 mm or more and less than 4 mm) and coarse aggregates (particle size range 4 mm or more), but fine aggregates are coarser. It is preferable because it has a higher water absorption rate than the aggregate and significantly improves the adhesion strength with the concrete to be repaired. Moreover, since the fine aggregate has a high absorption rate, the effects of suppressing shrinkage due to drying during curing and reducing the occurrence of cracks and cracks due to a decrease in humidity inside the concrete can be remarkably exhibited.
Examples of commercially available artificial lightweight aggregates include mesalite manufactured by Nippon Mesalite Industry Co., Ltd. and asanolite manufactured by Taiheiyo Material Co., Ltd.

  The amount of water is preferably 80 to 100% of the cement volume. If the volume of water is less than 80% of the cement volume, the fluidity and workability of the repair material will decrease, and if the volume of water exceeds 100% of the cement volume, This is because in any case, the strength is lowered.

  Further, the repair material according to the present embodiment may include steel fiber, synthetic resin fiber, and the like in addition to cement, artificial lightweight aggregate, and water. Since the artificial lightweight aggregate contained in the repair material according to the present embodiment has voids (because of its high water absorption rate), the strength of the repair material itself may decrease, but steel fibers or synthetic resin fibers Etc., the strength of the repair material itself can be improved. Of course, the present invention includes both steel fibers and synthetic resin fibers.

  Next, a repair method using the repair material according to the embodiment of the present invention will be described.

The repair material according to the present embodiment can be obtained by mixing cement, artificial lightweight aggregate, water and the like using a mixing mixer or the like (step 1).
At this time, the artificial lightweight aggregate is immersed in water in advance, and moisture is contained therein. Artificial lightweight aggregate has voids inside and has a 24-hour water absorption rate exceeding 3.5%, so it has more moisture than natural aggregate (24-hour water absorption rate is 3.5% or less). Can be contained inside.

  Then, the repair material obtained in step 1 is applied or injected into a portion (for example, a portion where a crack or a crack is generated) of the concrete (repair concrete) to be repaired (step 2). Specifically, after removing dirt and dirt on the part of the concrete to be repaired, and removing the surrounding parts as necessary, the repair material can be applied directly to the surface or injected into cracks and cracks. Or

After applying or injecting the repair material, the concrete is cured (step 3).
Here, since the repair material has an artificial lightweight aggregate containing a lot of moisture, the moisture in the artificial lightweight aggregate can be sufficiently supplied to the interface with the concrete to be repaired. Therefore, a hydration reaction of cement can be caused at the interface, and the adhesion strength between the repair material and the concrete to be repaired can be improved. Thereby, it can prevent that repair material peels from to-be-repaired concrete, and can make durability of the concrete after repair sufficiently high.

Examples of the curing method include a method of curing in water (underwater curing) and a method of covering and curing a portion where a repair material is applied or injected with a curing sheet (sealing curing).
However, underwater curing requires that the part where the repair material is applied or injected is submerged in water, but underwater curing is often not possible with a concrete structure. In such a case, the curing in step 3 needs to be sealed. When sealing curing is performed, generally the adhesion strength with concrete is lower than underwater curing, but in this embodiment, artificial lightweight aggregate is used as the aggregate, so sealing curing is sufficient. Adhesive strength can be obtained. In other words, because the artificial lightweight aggregate contains a large amount of moisture, moisture inside the artificial lightweight aggregate is supplied to the interface between the repair material and the concrete to be repaired, causing a hydration reaction of the cement at the interface. And sufficient adhesion strength can be obtained.
However, depending on the concrete structure, it is naturally possible to perform underwater curing. In underwater curing, the part where the repair material is applied or injected is immersed in water, so more water can be supplied to the interface between the repair material and the concrete to be repaired. Can be generated. Therefore, the adhesion strength between the repair material and the concrete to be repaired can be further improved.

(Test example)
Hereinafter, the effects of the present invention will be made clearer by showing test examples. However, the following test examples do not limit the present invention.

(Test Example A)
First, as test example A, the difference in adhesion strength between when underwater curing and when sealing curing is verified.

In Test Example A, as shown in FIG. 1 (a), a test specimen (hereinafter referred to as an adhering specimen) obtained by driving a second specimen (12) of the same size into a cylindrical first specimen (11). (Referred to as (10)).
Specifically, in the first specimen (11), ordinary Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.), natural aggregate (coarse aggregate and fine aggregate in a volume ratio of 61:39, Limestone crushed stone as coarse aggregate, limestone crushed sand and sea sand mixed at a volume ratio of 8: 2 are used as fine aggregate), and water is mixed at an aggregate volume ratio of 68% and a water cement volume ratio of 143%. A thing was used. To the second specimen (12), ordinary Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.), natural aggregate (mixed limestone sand and sea sand at a volume ratio of 8: 2), water, aggregate volume ratio 45 % And a water cement volume ratio of 100% were used. Further, SP-8SB (BASF Pozzolith Co., Ltd.), which is a polycarboxylic acid-based high-performance AE water reducing agent, was contained by 1.7% with respect to the weight of the cement. The center line extending in the length direction of the specimen (10) is provided on each of the first specimen (11) and the second specimen (12) in the case of performing sealing curing and in water curing. C) The adhesion strength was measured by applying a force in the opposite direction (force in the direction of the arrow in FIG. 1A).

  As a method for applying a force for measuring the adhesion strength (force in the direction of the arrow in FIG. 1A), as shown in FIG. 2, a cylindrical jig (J) with a bottom is provided above and below the specimen. The adhesion strength was measured by fitting and pulling in the direction of the arrow and measuring the force when the first specimen (11) and the second specimen (12) were separated. The bottomed cylindrical jig (J) has a chuck function inside, and the outer peripheral surface of the specimen is fastened and fixed.

  In addition, with respect to a seamless specimen (hereinafter referred to as an integral specimen (20)) as shown in FIG. 1 (b), the tensile strength and sealing curing when the underwater curing is performed for three days are performed for three days. The tensile strength was measured. As with the second specimen (12), ordinary Portland cement (Sumitomo Osaka Cement Co., Ltd.) and natural aggregate (crushed limestone sand and sea sand) were mixed at a volume ratio of 8: 2 in the integrated specimen (20). 1) and water were mixed at an aggregate volume ratio of 45% and a water cement volume ratio of 100%. Further, SP-8SB (manufactured by BASF Pozzolith Co., Ltd.), which is a polycarboxylic acid-based high-performance AE water reducing agent, was also contained by 1.7% with respect to the weight of the cement. The measuring method was performed in accordance with JIS A 1113 “Method for testing split tensile strength of concrete”.

The results of Test Example A are shown in FIG. In FIG. 3, (10a) is the adhesion strength of the adhesion specimen subjected to sealing curing, (10b) is the adhesion strength of the adhesion specimen subjected to underwater curing, and (20a) is an integral specimen that is sealed curing. (20b) shows the tensile strength of the integrated specimen subjected to underwater curing. The vertical axis represents tensile strength or adhesion strength (unit: N / mm ² ).

As shown in FIG. 3, it can be seen that in the integrated specimen (20), there is not much difference in tensile strength between when the water curing is performed and when the sealing curing is performed. On the other hand, it can be seen that the adhesion specimen (10) has better adhesion strength when the underwater curing is performed than when the sealing curing is performed.
From the results, it can be seen that when the concrete is adhered to each other, the adhesion strength is higher in the underwater curing than in the sealing curing. The reason is that in the case of underwater curing, a hydration reaction of cement occurs due to the supply of moisture to the interface between concrete.
From this, the same can be said of the adhesion strength between the concrete to be repaired and the repairing material when the concrete to be repaired is repaired with the repairing material. That is, it can be said that the adhesion strength between the concrete to be repaired and the repair material is higher in the underwater curing than in the sealing curing.

(Test Example B)
Next, the adhesion strength of the repair material according to the present invention to the concrete to be repaired is verified.

Also in Test Example B, the adhesion strength was measured using a specimen (10) as shown in FIG.
Specifically, as Example 1, ordinary Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.) and natural aggregate (coarse aggregate and fine aggregate were mixed at a volume ratio of 61:39 to the first specimen (11). Limestone crushed stone as coarse aggregate, limestone crushed sand and sea sand mixed at 8: 2 volume ratio as fine aggregate), water, aggregate volume ratio 68%, water cement volume ratio What was blended at 143% was used.
To the second specimen (12), normal Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.), asanolite (artificial lightweight aggregate manufactured by Taiheiyo Material Co., Ltd.), which is a fine aggregate, and water, a fine aggregate volume ratio of 45 %, And a water cement volume ratio of 80%. Further, SP-8SB (BASF Pozzolith Co., Ltd.), which is a polycarboxylic acid-based high-performance AE water reducing agent, was contained by 1.7% with respect to the weight of the cement.
And the sealing strength was measured by performing sealing curing for 3 days and applying force in the arrow direction of Fig.1 (a). The method of adding force is the same as in Test Example A (see FIG. 2). In addition, the 2nd test body (12) in Example 1 corresponds to the repair material which concerns on this invention.

  The asanolite (artificial lightweight aggregate) used in this test example has a 24-hour water absorption of 9 to 11% or more, an absolute dry density of 1.65 to 1.75 kg / L, and a coarse particle ratio of 2.50. 2.80, real volume ratio is 52-54%.

  Furthermore, as a comparative example, normal Portland cement (manufactured by Sumitomo Osaka Cement Co., Ltd.), natural aggregate (mixed limestone crushed sand and sea sand at a volume ratio of 8: 2), water, What was blended at a fine aggregate volume ratio of 45% and a water cement volume ratio of 80% was used. Further, SP-8SB (BASF Pozzolith Co., Ltd.), which is a polycarboxylic acid-based high-performance AE water reducing agent, was contained by 1.7% with respect to the weight of the cement. And what carried out sealing curing was made into the comparative example 1, and what performed the water curing was made into the comparative example 2, and the test similar to Example 1 was done.

FIG. 4 is a diagram showing the adhesion strength for Example 1 and Comparative Examples 1 and 2, and the vertical axis shows the adhesion strength (unit: N / mm ² ). FIG. 4 also shows the standard deviation.
Specifically, the average adhesion strength of Example 1 is 3.02 N / mm ² (standard deviation 0.34 N / mm ² ), and the average adhesion strength of Comparative Example 1 is 1.16 N / mm ² (standard deviation 0.05 N). / Mm ² ) and the average adhesion strength of Comparative Example 2 was 2.19 N / mm ² (standard deviation 0.12 N / mm ² ).
4 that Example 1 has better adhesion strength than Comparative Examples 1 and 2. In other words, the repair material using artificial lightweight aggregate is better than when the conventional repair material (repair material using natural aggregate) is used for underwater curing, even if sealing curing with weak adhesive strength is performed. It can be seen that it has high adhesion strength.

From the results of Test Example B, it can be said that the repair material using the artificial lightweight aggregate can sufficiently increase the adhesion strength with the concrete to be repaired even when sealing curing is performed. When repairing concrete, there are many cases where underwater curing cannot be performed depending on the concrete structure. However, even in that case, it can be suitably used because it can have high adhesion strength by performing sealing curing.
In consideration of Test Example A, it is considered that the repair material using the artificial lightweight aggregate can obtain higher adhesion strength than that of the sealing curing when the underwater curing is performed.

  The concrete repair material and repair method according to the present invention can be suitably used even for structures that cannot be cured underwater.

It is a figure which shows the test body used in order to measure tensile strength and adhesion strength. It is explanatory drawing for demonstrating the test for measuring tensile strength and adhesion strength. It is the figure which compared the adhesion strength and tensile strength at the time of performing sealing curing and underwater curing. It is the figure which compared the adhesion strength at the time of using the case where an artificial lightweight aggregate is used as an aggregate, and a natural aggregate.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Adhesive specimen 11 1st specimen 12 2nd specimen 10a Adhesion strength of the adhesion specimen which performed sealing curing 10b Adhesion strength of the adhesion specimen which performed underwater curing 20 Integrated specimen 20a Integrated specimen which performed sealing curing Tensile strength of specimen 20b Tensile strength of integral specimen subjected to underwater curing

Claims (8)

In concrete repair materials containing cement, aggregate, water,
A concrete repair material characterized in that the aggregate is an artificial lightweight aggregate having voids inside and having a water absorption rate of more than 3.5% for 24 hours.   The concrete repair material according to claim 1, wherein the aggregate has a 24-hour water absorption of 7% or more.   The concrete repair material according to claim 1, wherein the aggregate is a fine aggregate.   The aggregate has a 24-hour water absorption of 7 to 13%, an absolute dry density of 1.60 to 1.75 kg / L, a coarse particle ratio of 2.50 to 2.90, and an actual volume ratio of The concrete repair material according to claim 3, which is 52 to 58%.   The concrete repair material according to any one of claims 1 to 4, comprising steel fiber or synthetic resin fiber. A step of adding a cement and water to an artificial lightweight aggregate having voids and a water absorption rate of more than 3.5% for 24 hours and mixing it into a repair material;
Applying or pouring the repair material into concrete to be repaired;
A method for repairing concrete, comprising sequentially performing the steps of curing the concrete to which the repair material has been applied or poured.   The method for repairing concrete according to claim 6, wherein in the step of curing the concrete, curing is performed by covering a portion where the repair material is applied or injected with a curing sheet.   The method for repairing concrete according to claim 6, wherein in the step of curing the concrete, curing is performed in water.

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