RU2593404C1 - High-strength concrete - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: high-strength concrete relates to construction materials, and can be applied to make concrete articles in civil and industrial construction, as well as for erection of special purpose. High-strength concrete prepared from mixture containing Portland cement, sand, crushed rock, water, and complex additive, contains quartz sand with fineness modulus of 2.7 as sand, contains crushed stone of 5-10 mm fraction as crushed stone and complex additive with density of 1.07 g/cm³ and pH 6.5±0.5, consisting of iron (III) hydroxide sol with density of 1.021 g/cm³ and pH 5±0.5, and plasticiser from mixture of polycarboxylate polymers: polycarboxylate polymer on basis of methacrylic acid with density of 0.95 g/cm³ and pH 7±0.5, polycarboxylate polymer based on allyl ester and maleic anhydride with density of 1.03 g/cm³ and pH 7±0.5, and water in following proportions, wt.%: polycarboxylate polymer on basis of methacrylic acid with density of 0.95 g/cm³ and pH 7±0.5 - 10.5-11.5; polycarboxylate polymer based on allyl ester and maleic anhydride with density of 1.03 g/cm³ and pH 7±0.5 - 11.5-11.8; iron (III) hydroxide sol with density of 1.021 g/cm³ and pH 5.0±0.5 - 8.0-8.5; water 69.0-69.2, with following ratio of components, wt.%: Portland cement 17.7-18.4; above sand 41.62-42.0; above crushed stone 32.8-33.0; above additive 0.18-0.2; water 7.0-7.1.

EFFECT: technical result consists in reduction of shrinkage of high-strength concrete.

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 engineering, as well as in the construction of structures for special purposes.

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

The disadvantage of this technical solution is the increased shrinkage of concrete.

Known raw material mixture for the manufacture of high-strength concrete (RU No. 2256629, С04В 28/04, published July 20, 2005), containing: Portland cement, sand, gravel, a silica-containing component represented by orthosilicic acid sol with a density of 1.014 g / cm ³ , hydrogen indicator 5-6, the addition of "DEYA-M" and water.

The disadvantage of this technical solution is the increased shrinkage of concrete.

The closest in technical essence to the claimed invention is high-strength concrete (RU, No. 2425814, С04В 28/04, 22/06, 24/24, 111/20, publ. 08/10/2011), containing: Portland cement, sand, gravel , additive and water, the additive is complex and consists of an iron (III) hydroxide sol with a density of 1.021 g / cm ³ , a hydrogen index of 4.5-5.5 and a Peramin SMF-10 hyperplasticizer based on polycarboxylic polymers of the Swedish company Perstorp "(ASTM C494 type F, DIN 1045, BS 5075 parts 1 and 3, EN 934-2), with the following ratio of components, wt.%:

Sol of iron (III) hydroxide with a density of 1.021 g / cm ³ , pH 4.5-5.5 85.50-86.00 Peramin hyperplasticizer SMF-10 14.00-14.50

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

Portland cement 20.60-27.40 Sand 21.80-24.70 Crushed stone 42.40-44.50 Specified Additive 1.00-1.45 Water 7.40-8.75

The disadvantage of this technical solution is the increased value of concrete shrinkage.

The problem to which the invention is directed, is to reduce the shrinkage of high-strength concrete.

The technical result is achieved by the fact that high-strength concrete obtained from a mixture containing Portland cement, sand, crushed stone, water and a complex additive contains quartz sand with a fineness modulus of 2.7 as sand, crushed stone of granite fractions of 5-10 mm as crushed stone , and a complex additive with a density of 1.017 g / cm and a hydrogen index of 6.5 ± 0.5, consisting of a sol of iron hydroxide (III) with a density of 1.021 g / cm ³ and a hydrogen index of 5.0 ± 0.5 and a plasticizer from the mixture polycarboxylate polymers: meth-based polycarboxylate polymer krilovoy acid with a density of 0.95 g / cm ³ and a pH value 7,0 ± 0.5, polycarboxylate polymer based on allyl ether and maleic acid anhydrite with a density of 1.03 g / cm ³ and a pH value of 7,0 ± 0 5, and water in the following ratio of components, wt.%:

Polycarboxylate polymer based on methacrylic acid with a density of 0.95 g / cm ³ and hydrogen indicator 7.0 ± 0.5 10.5-11.5 Polycarboxylate polymer based on allyl ether and maleic anhydrite with a density of 1.03 g / cm ³ and a hydrogen index of 7 ± 0.5 11.5-11.8 Sol of iron (III) hydroxide with a density of 1.021 g / cm ³ , a hydrogen index of 5.0 ± 0.5 8.0-8.5 Water 69.0-69.2

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

Portland cement 17.7-18.4 Indicated sand 41.62-42.0 Specified crushed stone 32.8-33.0 Specified Additive 0.18-0.2 Water 7.0-7.1

The sol of iron (III) hydroxide in combination with polycarboxylates of various nature having side chains of different lengths contribute to the creation of a uniformly reinforced concrete structure, providing enhanced hydration processes in the entire volume of concrete and the sol of iron (III) hydroxide passes into the gel, contributing to the compaction of the structure concrete and, as a result, reduce its shrinkage by more than 3 times at the age of 120 days.

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 an iron (III) hydroxide sol with a density of 1.021 g / cm ³ and a hydrogen index of 5.0 ± 0.5, and a plasticizer represented by a mixture of polycarboxylate polymers: a polycarboxylate polymer based on methacrylic acid with a density of 0 95 g / cm ³ and a hydrogen index of 7 ± 0.5, a polycarboxylate polymer based on allyl ether and maleic anhydrite with a density of 1.03 g / cm ³ and a hydrogen index of 7 ± 0.5, namely, uniformly throughout concrete increases g The idratational activity of cement is also formed additionally due to the transition of the iron (III) hydroxide sol into a gel, an increased amount of gel filling the pores of concrete, thus, the concrete structure is compacted, which helps to reduce the shrinkage of concrete.

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

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

An example of a specific implementation.

1. Preparation of the additive

1.1. Preparation of sol of iron (III) hydroxide:

1.1.1. Dose a saturated solution of ferric chloride

1.1.2. Dispense water

1.1.3. Boiled metered water

1.1.4. The components prepared according to p. 1.1.1 and p. 1.1.3 are mixed to obtain a cherry-brown solution, which is a sol with colloidal particles of iron (III) hydroxide. The resulting sol of iron hydroxide should have a density of 1.021 g / cm ³ and a pH of 5.0 ± 0.5.

1.2. The iron hydroxide sol prepared according to 1.1.4 is dosed.

1.3. Metered polycarboxylate polymer based on methacrylic acid with a density of 0.95 g / cm ³ and a pH value 7 ± 0,5.

1.4. The polycarboxylate polymer is metered into maleic anhydrite ester allyl with a density of 1.03 g / cm ³ and a hydrogen index of 6.5 ± 5.

1.5. Dose water.

2. The components dispensed in accordance with Clauses 1.2, 1.3, 1.4, and 1.5 are thoroughly mixed until a solution with a density of 0.17 g / cm ³ and a hydrogen index of 6.5 ± 0.5 is obtained.

3. The components of high-strength concrete are dosed: Portland cement, quartz sand with a particle size modulus of 2.7, granite crushed stone of a fraction of 5-10 mm.

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 the additive prepared according to claim 2.

3.4. The additive dosed in paragraph 3.3 is transported into dosed water.

3.5. The mixture prepared according to p. 3.4 is transported to a concrete mixer.

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

3.7. The ready-mixed concrete for high-strength concrete is transported to the place of manufacture of the products.

3.8. The concrete mixture prepared according to clause 3.7 is taken directly from the concrete mixer to control the physical and mechanical characteristics. The determination of concrete shrinkage is carried out according to GOST 24544-81.

Concrete shrinkage results are presented in the table.

Studies have shown that shrinkage of concrete at the age of 120 days is reduced by 3.16 times.

Claims (1)

High-strength concrete, obtained from a mixture containing Portland cement, sand, gravel, water and a complex additive, contains sand as quartz sand with a particle size module of 2.7, gravel contains granite fractions of 5-10 mm and complex additive with a density of 1.017 g / cm ³ and a hydrogen index of 6.5 ± 0.5, consisting of a sol of iron (III) hydroxide with a density of 1.021 g / cm ³ and a hydrogen index of 5.0 ± 0.5 and a plasticizer, characterized in that it contains a mixture of polycarboxylate polymers: polycarboxylate polymer on based on methacrylic acid with a density of 0.95 g / cm ³ and a hydrogen index of 7.0 ± 0.5, a polycarboxylate polymer based on ester of allyl and maleic anhydrite with a density of 1.03 g / cm ³ and a hydrogen index of 7.0 ± 0 , 5, and water in the following ratio of components, wt.%:
Polycarboxylate polymer based on methacrylic acid with a density of 0.95 g / cm ³ and a hydrogen index of 7 ± 0.5 10.5-11.5 Polycarboxylate polymer based on allyl ether and anhydrite maleic acid with a density of 1.03 g / cm ³ and a hydrogen index of 7 ± 0.5 11.5-11.8 Sol of iron (III) hydroxide with a density of 1.021 g / cm ³ , hydrogen indicator 7 ± 0.5 8.0-8.5 Water 69.0-69.2
in the following ratio of components of the raw mix, wt.%:
Portland cement 17.7-18.4 Indicated sand 41.62-42.0 Specified crushed stone 32.8 - 33.0 Specified Additive 0.18 - 0.2 Water 7.0-7.1