RU2592318C1 - High-strength concrete - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction materials and can be used to make concrete articles in civil and industrial construction, as well as for erection of special purpose, for example hydraulic structures. High-strength concrete prepared from mixture containing Portland cement, sand, crushed stone, silica-containing component represented by silicic acid sol H₂SiO₃ with density of 1.014 g/cm³, additive and water, additionally contains filler, which is floured electrostatic filter ash from burning coal shale with specific surface equal to 360 m²/kg, and value of pH of silica-containing component is 4±0.5, and additive consists of aqueous solution of polycarboxylate polymer with density of 1.035 g/cm³ and pH value of pH = 6±0.5, sodium formate and water in following proportions, wt%: polycarboxylate polymer water solution with density 1.035 g/cm³ and pH value of pH = 6±0.5-20-21; sodium formate - 1.5-1.6; water - 77.5-78.4; at following ratio of components of crude mixture of high-strength concrete, wt%: Portland cement - 16-19; sand - 33-34; crushed stone - 39-40; silica-containing component represented by silicic acid sol H₂SiO₃ with density ρ= 1.014 g/cm³ and pH = 4±0.5-0.16-0.20; said filler - 0.94-1.00; said additive - 0.19-0.20; water - 7.71-8.60.

EFFECT: technical result is higher water impermeability of high-strength concrete.

1 cl, 2 tbl

Description

The invention relates to building materials and can be used for the manufacture of concrete products in civil and industrial construction, as well as in the construction of structures for special purposes, such as hydraulic structures.

A known raw material mixture for the manufacture of high-strength concrete (Yu.M. Bazhenov. Concrete technology. Publishing House of the Association of Building Universities (DIA), Moscow, 2002, p. 377), containing Portland cement, silica-containing component, sand, gravel, silicate flour, additive and water.

The disadvantage of this technical solution is the insufficient value of water resistance of concrete.

Known raw mix for the manufacture of high-strength concrete (RU, No. 2256629, С04В 111: 20, 07/20/2005), containing: Portland cement, sand, gravel, a silica-containing component represented by H ₂ SiO ₃ sol with a density ρ = 1,014 g / cm ³ , the addition of "DEYA-M" and water.

The disadvantage of this technical solution is the insufficient value of water resistance of concrete.

The closest in technical essence to the claimed invention is high-strength concrete (RU, No. 2256630, С04В 28/04, 04В 111: 20, 07/20/2005), containing: Portland cement, sand, gravel, silica-containing component represented by H ₂ SiO sol ₃ with a density ρ = 1.014 g / cm ³ , pH = 5-6, additive: potassium ferruginous-synergy K ₄ Fe (CN) ₆ and water in the following ratio of components, wt.%:

The disadvantage of this technical solution is the insufficient value of water resistance of concrete.

The problem to which the invention is directed, is the creation of high-strength concrete with an increased value of water resistance.

The problem is achieved in that high-strength concrete obtained from a mixture containing Portland cement, sand, gravel, a silica-containing component represented by H ₂ SiO ₃ sol with a density of ρ = 1.014 g / cm ³ , additive and water. New in comparison with the high-strength concrete selected for the prototype is that the raw material mixture additionally contains a filler represented by fine-ground electro-filter ash from the combustion of shale coals with a specific surface area of 360 m ² / kg, and the value of the hydrogen index of the silica-containing component is 4 ± 0.5, and the additive consists of an aqueous solution of a polycarboxylate polymer with a density of 1.035 g / cm ³ and a pH value of pH = 6 ± 0.5, sodium formate and water in the following ratio of components tov, wt.%:

in the following ratio of components of the raw mix, wt.%:

The specified additive increases the hydration activity of cement, which results in increased formation of hydrolytic lime, which enters the synthesis reaction with H ₂ SiO ₃ sol and, in addition, low-basic calcium hydrosilicates are formed, in addition, the silica sol H ₂ SiO ₃ additionally enters the synthesis reaction and with reactive free calcium oxide CaO, which is part of the ash, forming additional tobermorite-like hydrosilicates.

Thus, the formation of an increased amount of calcium hydrosilicates of different basicities during the hardening of the concrete mixture contributes to the formation of a denser concrete structure, which ensures the creation of a high-density structure of high-strength concrete and, as a result, increased water resistance.

The specified additive in combination with silica sol H ₂ SiO ₃ with a density ρ = 1.014 g / cm ³ and a pH value of pH = 4 ± 0.5 in combination with the specified filler forms a denser structure of high-strength concrete and, as a result, increase waterproof at 4 atm.

At the filing date, according to the authors and the applicant, the claimed high-strength concrete is not known and this technical solution has world novelty.

The claimed combination of essential features exhibits a new property in the presence of a sol of silicic acid H ₂ SiO ₃ with a density ρ = 1.014 g / cm ³ and pH = 4 ± 0.5, an additive consisting of a polycarboxylate polymer with a density of 1.035 g / cm ³ and a hydrogen index pH = 6 ± 0.5, sodium formate and water; and a filler represented by fine-ground electro-filter ash from the burning of shale coals with a specific surface area of 360 m ² / kg, namely, it increases the hydration activity of the concrete mixture, which is accompanied by a parallel synthesis reaction with the formation of an increased amount of hydrosilicates of different basicities, ensuring the formation of a denser structure of high-strength concrete, the consequence of which is to increase the water resistance of high-strength concrete.

According to the authors and the applicant, the claimed invention meets the eligibility criteria - inventive step.

The claimed invention is industrially applicable and can be used in civil engineering and in the construction of critical structures for special purposes.

An example of a specific implementation.

1. The preparation of the sol of silicic acid H ₂ SiO ₃ :

1.1. Sodium liquid glass is dosed.

1.2. Dose water.

1.3. The metered-dose components according to paragraph 1.1 and paragraph 1.2 are mixed to obtain a solution with a density ρ = 1.016 g / cm ³ .

1.4. The solution prepared according to p. 1.3 is passed through a cation exchange column containing KU-2-8 cation exchange resin.

1.5. At the column outlet, a sol solution of H ₂ SiO _{3 is} obtained, which has a density ρ = 1.014 g / cm ³ and a pH value of 4 ± 0.5, which is the finished product representing a silica sol of H ₂ SiO ₃ with a density ρ = 1.014 g / cm ³ and pH = 4 ± 0.5.

2. Preparation of additives based on polycarboxylate polymer:

2.1. A polycarboxylate polymer is dosed, the weight concentration of which is C = 45%.

2.2. Dose water.

2.3. The dosage components according to paragraph 2.1 and paragraph 2.2 are mixed until a homogeneous solution is obtained with a density ρ = 1,035 g / cm ³ and a pH value of pH = 6 ± 0.5.

2.4. Dose sodium formate.

2.5. The components prepared according to clause 2.3 and dispensed according to clause 2.4 are thoroughly mixed until a homogeneous solution is obtained.

3. Dose the components of the raw mix of high-strength concrete: Portland cement, sand, gravel, aggregate.

3.1. The dispensed components according to claim 3 are transported to a concrete mixer of any modern design used at the factory.

3.2. Dose water.

3.3. Dose a sol of silicic acid H ₂ SiO ₃ prepared according to p. 1.5.

3.4. A polycarboxylate polymer-based additive prepared according to claim 2.5 is dosed.

3.5. Components dispensed in accordance with clause 3.3 and clause 3.4 are transported into dispensed water.

3.6. The mixture prepared according to clause 3.5 is transported to a concrete mixer.

3.7. All components in the concrete mixer are thoroughly mixed for 3 minutes.

3.8. The prepared concrete mixture is tested according to GOST 12730.5 in terms of water resistance, for this, cylinder samples with a diameter of 15 cm and a height of 15 cm are made.

3.9. Samples for water resistance control are stored under normal conditions, at a temperature of 20 ± 2 and a humidity of at least 95%. The determination of water resistance is carried out according to GOST 12730.5 at the age of 28 days.

3.10. The finished concrete mixture is transported to the place of manufacture of the products.

The chemical composition of the filler, represented by fine-ground electro-filter ash from the combustion of shale coal with a specific surface area of 360 m ² / kg, is presented in table 1.

The investigated concrete mixes and the results on water resistance are presented in table 2.

Studies have shown that the water resistance of high-strength concrete is increased by 2 steps or 4 atm.

Claims (1)

High-strength concrete obtained from a mixture comprising Portland cement, sand, gravel, a silica-containing component represented by a silica sol H ₂ SiO ₃ with a density ρ = 1,014 g / cm ³ , an additive and water, characterized in that it further contains a filler represented by a fine electrostatic precipitator shale ash from burning coal with a specific surface area equal to 360 m ² / kg, the value of the hydrogen index of silica-containing component is 4 ± 0,5, the additive consists of an aqueous solution of a polycarboxylate polymer density 1.035 g / cm ³ and a pH value pH = 6 ± 0,5, sodium formate and water in the following ratio, wt.%:
Polycarboxylate aqueous solution polymer with a density of 1,035 g / cm ³ and 20-21 pH value pH = 6 ± 0.5 Sodium formate 1.5-1.6 Water 77.5-78.4
in the following ratio of components of the raw mix, wt.%:
Portland cement 16-19 Sand 33-34 Crushed stone 39-40 Silica-containing component represented by a silicon sol 0.16-0.20 acids H ₂ SiO ₃ with a density ρ = 1.014 g / cm ³ , pH = 4 ± 0.5 Specified Filler 0.94-1.00 Specified Additive 0.19-0.20 Water 7.71-8.60