JP6653779B2 - Moist curing water for concrete and mortar, and method for curing concrete and mortar using the same - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a wet curing water for concrete and mortar, and a method for curing concrete and mortar using the same.

  Conventionally, wet curing of concrete and mortar is generally performed using tap water or river water.

Further, in this type of concrete curing method, prior art using a reagent has been proposed in Patent Documents 1-4 for the purpose of densification of concrete and the like, in which microorganisms are used as an admixture for concrete. Prior art is proposed by US Pat.
Patent Document 1 relates to a method of wet curing of concrete. In the method of Patent Document 1, hardened concrete is formed by driving fresh concrete into a mold, and after removing the mold, the concrete is removed together with moisture. A fiber material is sprayed to cover the outer surface of the concrete with the wet fiber material, and the fiber material is removed from the concrete after a aging period. As the water to be contained in the fibrous material, alkaline water having a pH of 7 or more containing at least one selected from the group consisting of calcium hydroxide, potassium hydroxide, lithium hydroxide, sodium hydroxide, potassium carbonate, lithium carbonate and sodium carbonate is used. Use an aqueous solution. In this way, the voids formed near the inner surface layer of the concrete are reduced, and the concrete is densified.
Patent Document 2 relates to a coating curing agent for mortar or concrete, and the coating curing agent of Patent Document 2 includes at least one selected from polyvinyl alcohols, vinyl acetates, and acrylic copolymers. It is an aqueous solution of at least one selected from acid compounds and at least one selected from fluorinated silicon compounds, and further comprises at least one selected from glycerin, urea, ethylene glycol, and celluloses. This strengthening agent suppresses water evaporation in mortar and concrete and enhances moisture retention in a simple manner, reduces initial cracking during drying, improves water resistance, suppresses neutralization, and reduces surface wear. Improvement and surface strength.
Patent Document 3 relates to concrete and a concrete curing method. In the method of Patent Document 3, curing is performed while supplying bicarbonate ions to the concrete surface. In this way, the leaching of the cement hydrate and the increase in pH around the concrete due to components eluted from the concrete are suppressed without requiring any material or labor completely different from the production of concrete.
Patent Document 4 relates to a method for producing a highly durable concrete structural material. In the method of Patent Document 4, an alkaline aqueous solution is sprayed on an uncured molded body extruded from an extruder. In this case, examples of the alkaline component include caustic soda, caustic potash, lime (quick lime to slaked lime), sodium carbonate, sodium bicarbonate, magnesium hydroxide, and aluminum hydroxide. Of these, particularly preferred is lime, a saturated aqueous solution of lime, the component of which is calcium hydroxide. After spraying the alkaline aqueous solution on the uncured molded body, a curing selected from aerial curing, steam curing and autoclave curing is performed. In this way, a sufficient amount of an alkaline component is supplied to the micropores of the hardened cement to delay the generation of rust on the reinforcing bar in the structural material, thereby maintaining long-term durability.
Patent Literature 5 relates to a concrete plate for water purification, and the concrete plate of this Literature 5 has a mixing ratio of Bacillus subtilis, Bacillus sulgenaises and Bacillus spalicas in a mass ratio of 0.1 to 50: Cement paste containing a mixture of microbial bacteria of 0.1-50: 0.1-50 was used. Thus, the water is purified.

JP 2015-27923 A JP 2008-285367 A JP 2008-56538 A JP-A-8-81285 Japanese Patent No. 4065402

However, in the conventional method of curing concrete and mortar using tap water and river water as wet curing water, the effect of wet curing is limited because the concrete and mortar are densified by the hydration reaction of cement. There is a problem that there is.
Further, as a result of studying each technique of Patent Documents 1-5 in relation to the present invention, the following conclusions can be made.
In the wet curing method for concrete disclosed in Patent Document 1, the moisture contained in the fiber material is selected from the group consisting of calcium hydroxide, potassium hydroxide, lithium hydroxide, sodium hydroxide, potassium carbonate, lithium carbonate, and sodium carbonate. An alkaline aqueous solution containing at least one kind and having a pH of 7 or more is used, and the method of using the alkaline aqueous solution is limited to a method of including it in a fiber material. In particular, it does not focus on wet curing using an aqueous solution containing magnesium.
Patent Document 2 discloses a mortar or concrete coating curing enhancer for at least one selected from polyvinyl alcohols, vinyl acetates, acrylic copolymers, at least one selected from silicate compounds, and a fluorosilicone compound. And an aqueous solution of at least one selected from the group consisting of a water-curing method in which the protective film is formed by coating on concrete instead of a wet curing method in which it is in contact with concrete for a certain period. In particular, it does not focus on wet curing using an aqueous solution containing magnesium.
In the concrete and concrete curing method of Patent Document 3, curing is performed while supplying bicarbonate ions to the concrete surface. In particular, it does not focus on wet curing using an aqueous solution containing magnesium.
The method for producing a highly durable concrete structural material disclosed in Patent Document 4 is to spray an alkaline aqueous solution on an uncured molded body extruded from an extrusion molding machine, and this alkaline component contains magnesium hydroxide. After spraying the alkaline aqueous solution on the uncured molded body, a curing selected from aerial curing, steam curing and autoclave curing is performed. In particular, it does not focus on wet curing using an aqueous solution containing magnesium.
In the concrete plate for water purification of Patent Document 5, Bacillus subtilis is mixed into a material for producing a concrete plate for water purification. In particular, it does not focus on wet curing using an aqueous solution containing Bacillus subtilis.

  The present invention solves the above-mentioned conventional problems. Concrete, moist curing water for mortar, and concrete using the same, in a method for curing mortar, an aqueous solution containing a magnesium-containing easily soluble compound or an aerobic microorganism. The purpose of the present invention is to densify the surface properties of concrete and mortar by using, to suppress moisture dissipation of concrete and mortar, to reduce drying shrinkage, and to delay the progress of deterioration such as neutralization and salt damage.

  In order to achieve the above object, the concrete and mortar wet curing water of the present invention (1) comprises a magnesium-containing readily soluble compound, and the magnesium-containing readily soluble compound includes magnesium acetate, magnesium nitrate, thiol, and the like. The gist of the present invention is to include at least one selected from magnesium sulfate and magnesium bromide.

  In order to achieve the above object, the present invention (2) provides a method for curing concrete and mortar in which concrete is moist-cured using moist curing water, wherein the concrete and mortar-moist curing water are added to the moist curing water. To use it.

  According to the concrete and wet curing water for mortar of the present invention (1) and (2), and the method for curing concrete and mortar using the same, selected from magnesium acetate, magnesium nitrate, magnesium thiosulfate and magnesium bromide. A protective layer is formed on the surface of concrete or mortar by a reaction between magnesium ions in wet curing water containing at least one readily soluble compound and hydroxide ions in concrete or mortar. The present invention is unique in that the surface properties can be densified, thereby suppressing the loss of water in concrete and mortar, reducing drying shrinkage, and delaying the progress of deterioration such as neutralization and salt damage. It has a special effect.

SEM image of mortar cross-section showing the effect of the concrete and mortar wet curing water of the present invention and the method of curing concrete and mortar using the same. The figure which shows the result of the surface water absorption test of the mortar which shows the effect of the curing method of the concrete and mortar, and the curing method of the concrete and mortar.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.
(Embodiment 1)
Moist curing water for concrete and mortar consists of an aqueous solution containing a magnesium-containing readily soluble compound.
In this case, the readily soluble compound containing magnesium is magnesium acetate (Mg (CH ₃ COO) ₂ ), magnesium nitrate (Mg (NO ₃ ) ₂ ), magnesium chloride (MgCl ₂ ), magnesium thiosulfate (MgS ₂ O ₃₎ ), Magnesium sulfate (MgSO ₄ ), and magnesium bromide (MgBr ₂ ).

  The concrete is wet-cured using the wet curing water. In this case, after the concrete and the mortar are hardened, the exposed surface of the concrete and the mortar are wet-cured with the above-mentioned wet curing water for a certain period. After removing the mold, the mold surface is wet-cured with the above-mentioned wet curing water for a certain period. In this way, magnesium ions in the wet curing water react with hydroxide ions in the concrete and mortar to precipitate magnesium hydroxide, and this magnesium hydroxide forms a protective layer on the surface of the concrete and mortar. The surface properties of concrete, mortar and concrete are densified.

  As described above, according to the concrete, mortar moist curing water, and concrete using the same, according to the mortar curing method, concrete, mortar curing water used for moist curing, instead of conventional tap water or river water. Just using an aqueous solution containing a magnesium-containing readily soluble compound, without affecting the normal work process of concrete and mortar curing, with magnesium ions in a wet curing water containing a magnesium-containing easily soluble compound. By reacting with hydroxide ions in concrete and mortar, a protective layer can be formed on the surface of concrete and mortar to densify the surface properties of concrete and mortar. Suppresses escape, reduces drying shrinkage, delays progress of deterioration such as neutralization and salt damage It is possible.

(Embodiment 2)
Moist curing water for concrete and mortar consists of an aqueous solution containing aerobic microorganisms.
In this case, the aerobic microorganisms include Bacillus subtilis. In this case, the aqueous solution contains at least one of glucose and glycerose, and is further supplied with air.

  The concrete is wet-cured using the wet curing water. In this case, after the concrete and the mortar are hardened, the exposed surface of the concrete and the mortar are wet-cured with the above-mentioned wet curing water for a certain period. After removing the mold, the mold surface is wet-cured with the above-mentioned wet curing water for a certain period. In this way, aerobic microorganisms (Bacillus subtilis) in the wet curing water react with carbon dioxide generated from oxygen and calcium ions in the mortar and concrete to precipitate calcium carbonate, and the calcium carbonate precipitates in the concrete and mortar. A protective layer is formed on the surface of the concrete, and the surface properties of concrete and mortar are densified.

  As described above, according to the concrete, mortar moist curing water, and concrete using the same, according to the mortar curing method, concrete, mortar curing water used for moist curing, instead of conventional tap water or river water. The use of an aqueous solution containing aerobic microorganisms (including glucose or glycerose and air) does not affect the normal work process of curing concrete and mortar, and the aerobic microorganisms in the humidified water can be oxygenated. The protective layer is formed on the surface layer of concrete and mortar by the reaction between carbon dioxide generated from concrete and calcium ions in concrete and mortar, and the surface properties of concrete and mortar can be densified. Suppresses water loss of mortar, reduces drying shrinkage, and promotes deterioration such as neutralization and salt damage. It can be delayed.

The present inventors conducted the following experiment to confirm the effects of the concrete and mortar wet curing water and the method of curing concrete and mortar using the same, and obtained the following results.
In the experiments, mortar specimens using ordinary Portland cement were prepared by using (1) conventional moist curing water (tap water), (2) moist curing water containing magnesium acetate, and (3) natto, a kind of Bacillus subtilis. The moist curing was performed for 28 days with moist curing water containing bacteria and glucose.
The result is shown in FIG. As shown in FIGS. 1 (2) and (3), in the case of (2) wet curing water containing magnesium acetate, a protective layer is formed on the surface layer of mortar with magnesium hydroxide, and (3) a kind of Bacillus subtilis. In the wet curing water containing certain natto bacteria and glucose, it was confirmed that a protective layer was formed on the surface layer of the mortar with calcium carbonate, and the properties of the surface layer were dense.
FIG. 2 shows the results of a surface water absorption test of this mortar. As shown in FIG. 2 (1), (1) in the conventional wet curing water (tap water), it was recognized that the water level continued to decrease since the water absorption continued from the completion of the water injection. As shown in FIGS. 2 (2) and 2 (3), (2) moist curing water containing magnesium acetate, (3) natto bacteria which is a kind of Bacillus subtilis, and moist curing water containing glucose, respectively. Immediately after the completion of water injection, the water level dropped due to water absorption. However, it was recognized that the water absorption stopped on the way, and the water level drop started to rise. As a result, it was confirmed that the surface properties of the mortar were densified and the escape of water was suppressed.

Claims (2)

Consisting of a magnesium-containing readily soluble compound, the magnesium-containing readily soluble compound includes at least one selected from magnesium acetate, magnesium nitrate, magnesium thiosulfate, and magnesium bromide.
Moist curing water for concrete and mortar, characterized in that: In the method for curing concrete and mortar, wherein the concrete is moist-cured using moist curing water, the concrete and moisturizing water of mortar according to claim 1 are used as the moist curing water,
A method for curing concrete and mortar, characterized in that: