RU2717021C1 - 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 during erection of special purpose structures. High-strength concrete obtained from a mixture comprising portland cement, sand, crushed stone, an additive and water, contains sand as sand with a fineness modulus of 2.4; crushed rock – particle size 10–20 mm, additionally contains shale ash with specific surface area of 900 m²/kg; as an additive contains a complex additive consisting of an aqueous solution of polycarboxylate polymer CP-WRM, represented by a copolymer of acrylic acid and ethyl ether of methacrylic acid, with density ρ=1.033 g/cm³, hydrogen pH=6.5; aqueous silicic acid sol having a density ρ=1.021 g/cm³, with pH=3.5 and polycarboxylate polymer Sika Viscocrete 225 based on allyl ether and maleic acid anhydrite in the following ratio, wt%: said aqueous solution of polycarboxylate polymer CP-WRM 88.0–91.0; said aqueous solution of silicic acid sol 6.0–0.0; said polycarboxylate polymer Sika Viscocrete 225 3.0–4.0; with following ratio of components, wt%: portland cement 20.0–22.0, said sand 26.0–26.7, said crushed stone 41.0–41.8; said ash 2.8–3.0; said complex additive 0.2–0.3; water 8.0–8.2.

EFFECT: creation of high-strength concrete with high water-resistance and high corrosion resistance.

1 cl, 1 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.

A known mixture for the manufacture of high-strength concrete (RU No. 2256629, СВВ 28/04, 07/20/2009), containing Portland cement, sand, gravel, silica-containing component represented by silica sol H ₂ SiO ₃ with a density ρ = 1,014 g / cm ³ , pH value of pH = 5-6, the addition of "DEYA-M" and water in the following ratio of components, wt. %: Portland cement 44.4-46.0; sand 20.0-22.2; crushed stone 20.0-22.2; the specified silica-containing component of 0.43-0.48; DEYA-M additive 0.43-0.48; water 10.34-11.44.

The disadvantage of this technical solution is the increased permeability and reduced corrosion resistance of concrete.

A known mixture for the manufacture of high-strength concrete (RU No. 2323910, С04В 28/04; СВВ 22/06 С04В 111/20, 05/10/2008), which contains wt. %: Portland cement 23.6-26.9; sand 23.7-25.2; crushed stone 36.8-38.4; sol of iron hydroxide Fe (OH) ₃ with a density ρ = 1.018 g / cm ³ , a hydrogen pH = 4.5-5.5 0.7-0.76; water 11.9-12.04.

The disadvantage of this technical solution is the increased permeability and reduced corrosion resistance of concrete.

The closest in technical essence to the claimed invention is a mixture of high-strength concrete (RU No. 2256630, CO4B 28/04, 07/20/2005), containing: Portland cement, sand, crushed stone, silica-containing component represented by silica sol H ₂ SiO ₃ with ρ = 1.014 g / cm ³ , a pH of pH = 5-6, the additive is potassium ferruginous-synergy K ₄ Fe (CN) ₆ and water in the following ratio of components, wt. %:

Portland cement 43.58-47.08 Sand 14.43-15.69 Crushed stone 25.7-27.84 Silica component represented by silica sol H ₂ SiO ₃ with a density ρ = 1.014 g / cm ³ , pH value pH = 5-6 0.25-0.27 Additive - potassium ferruginous-synergy K ₄ Fe (CN) ₆ 0.44-0.47 Water 12,1-12,15

The disadvantage of this technical solution is the increased permeability and reduced corrosion resistance of concrete.

The problem to which the invention is directed, is the creation of high-strength concrete with a high rate of water resistance and increased corrosion resistance.

The problem is achieved in that high-strength concrete obtained from a mixture including Portland cement, sand, gravel, additive and water contains sand - sand with a particle size of 2.4; as crushed stone - crushed stone of a fraction of 10-20 mm, additionally contains shale ash with a specific surface area of 900 m ² / kg; as an additive contains a complex additive consisting of an aqueous solution of the polycarboxylate polymer CP-WRM, represented by a copolymer of acrylic acid and ethyl methacrylic acid, with a density of ρ = 1,033 g / cm ³ , a pH value of 6.5; an aqueous solution of silica sol with a density ρ = 1.021 g / cm ³ , a pH of pH = 3.5, and a Sika Viscocrete 225 polycarboxylate polymer based on allyl ether and maleic anhydrite in the following ratio of components, wt. %:

 specified aqueous solution polycarboxylate polymer CP-WRM 88.0-91.0  specified aqueous solution silicic acid sol 6.0-8.0 specified polycarboxylate Sika Viscocrete 225 polymer 3.0-4.0,

in the following ratio of components, wt. %:

Portland cement 20.0-22.0 specified sand 26.0-26.7 specified crushed stone 41.0-41.8 specified ash 2.8-3.0 specified complex additive 0.2-0.3 water 8.0-8.2

The use of this complex additive significantly enhances the hydration activity of the mixture for high-strength concrete, while the silica sol, which is part of the additive, effectively interacts with calcium oxide, which is part of shale ash, forming complex calcium hydrosilicates with a high content of silicon dioxide , i.e. mainly low-basic hydrosilicates, such as 2CaO⋅3SiO ₂ ⋅ 2H ₂ O gyrolite, thus completely eliminating calcium oxide, CaO and calcium hydroxide, Ca (OH) ₂ from the hardened stone. The formation of an increased amount of complex hydrated compounds increases the density of the structure of hardened concrete, increasing the water resistance and thus, hardened concrete is characterized by increased corrosion resistance, due to the complete binding of calcium oxide and calcium hydroxide to complex sparingly soluble compounds.

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 the proposed complex additives and shale ash with a specific surface area of 900 m ² / kg, increases the density of the structure, both through the use of ultrafine ash, and also as a result of the formation of an increased amount of complex hydrated compounds during hardening of modified concrete, as well as the additional formation of calcium hydrosilicates in the interaction of calcium oxide and calcium hydroxide formed during the hydration of cement with the components of the additive, namely silica sol, which results in an effective increase in the water resistance and corrosion resistance of hardened concrete.

A mixture including Portland cement, sand with a particle size modulus of 2.4, crushed stone of a fraction of 10-20 mm, shale ash with a specific surface area of 900 m ² / kg, an additive represented by a complex consisting of an aqueous solution of the polycarboxylate polymer CP-WRM represented by an acrylic acid copolymer and ethyl methacrylic acid with a density ρ = 1,033 g / cm ³ and a pH of 6.5; an aqueous solution of silicic acid sol with a density ρ = 1,021 g / cm ³ , a pH of pH = 3.5; polycarboxylate polymer Sika Viscocrete 225 based on allyl ether and maleic anhydrite, provided high-strength concrete, characterized by increased water resistance and increased corrosion resistance.

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

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

Concrete example

1. Preparation of the proposed complex additives.

1.1. The aqueous solution of the polycarboxylate polymer CP-WRM, which is a copolymer of acrylic acid and ethyl methacrylic ester with a density of ρ = 1.033 g / cm ³ and a pH value of 6.5, is dosed.

1.2. Dose an aqueous solution of a sol of silicic acid with a density ρ = 1,021 g / cm ³ , a pH of pH = 3.5;

1.3. Sika Viscocrete 225 polycarboxylate polymer based on allyl ester and maleic anhydrite is dosed.

1.4. Dosage components of clause 1.1. - 1.3 is transported to the mixer and mixed thoroughly with a slow-moving mixer until a homogeneous solution of a complex additive is formed, which is transported to a storage tank.

2. Preparation of the mixture for high-strength concrete:

2.1. Portland cement is dosed;

2.2. Dose sand with a particle size of 2.4;

2.3. Dose crushed stone fractions of 10-20 mm;

2.4. Dose shale ash with a specific surface area of 900 m ² / kg;

2.5. Dose water;

2.6. The complex additive prepared according to paragraph 1.4. transported to dosed water and mixed by any mechanical method.

2.7. Dosage components according to clauses 2.1 - clause 2.6 are thoroughly mixed in a concrete mixer of any design used at the factory.

The finished mixture is used for its intended purpose for the manufacture of structures of high-strength concrete for industrial and civil construction, as well as for special purposes.

To determine the water tightness according to GOST 12730.5-84, cylinder samples with a diameter of 150 mm and a height of 150 mm are made in the amount of 6 pieces, which are stored under normal conditions for 28 days and then subjected to testing.

To determine the corrosion resistance of high-strength concrete, evaluated by the coefficient of chemical resistance, determined according to GOST 25881-83 “Concrete chemically resistant. Test Methods ”4 × 4 × 16 cm beam samples are made, which are exposed to a 5% solution of magnesium chloride, MgCl ₂ , for 360 days.

The results are presented in the table.

According to the test results presented in the table, it was found that the water resistance of high-strength concrete according to the invention increases by 33% relative to the prototype and the coefficient of chemical resistance increases by 8.0%.

Claims (4)

High-strength concrete obtained from a mixture comprising Portland cement, sand, gravel, additive and water, characterized in that the sand contains sand with a particle size of 2.4; as crushed stone - crushed stone of a fraction of 10-20 mm, additionally contains shale ash with a specific surface area of 900 m ² / kg; as an additive contains a complex additive consisting of an aqueous solution of the polycarboxylate polymer CP-WRM, represented by a copolymer of acrylic acid and ethyl methacrylic acid, with a density of ρ = 1,033 g / cm ³ , a pH value of 6.5; an aqueous solution of silica sol with a density ρ = 1.021 g / cm ³ , a pH of pH = 3.5, and a Sika Viscocrete 225 polycarboxylate polymer based on allyl ether and maleic anhydrite in the following ratio of components, wt. %: specified aqueous solution polycarboxylate polymer CP-WRM 88.0-91.0 specified aqueous solution silicic acid sol 6.0-8.0 specified polycarboxylate Sika Viscocrete 225 polymer 3.0-4.0 in the following ratio of components, wt. %: Portland cement 20.0-22.0 specified sand 26.0-26.7 specified crushed stone 41.0-41.8 specified ash 2.8-3.0 specified complex additive 0.2-0.3 water 8.0-8.2