RU2684264C1 - High-strength concrete - Google Patents

Abstract

FIELD: construction materials.SUBSTANCE: invention relates to construction materials and can be used to make high-strength concrete articles in civil and industrial construction, as well as during erection of special purpose structures. High-strength concrete prepared from a mixture comprising a complex additive, consisting of the following components, wt. %: 20 % polycarboxylate polymer solution (CP-WRM), having a pH value pH = 6 and a density of 1.029 g/cc 60–65; high-molecular polymer compound with a molecular weight of more than 600 g/mol, a density of 0.98 g/cc and a pH value of 6.5 to 16–18; colloidal solution (sol) of silicic acid with a density of 1.014 g/cc and pH = 3.5 19–22; in the following ratio of components of the raw mix, wt. %: portland cement – 19.9–21.9; said sand – 27.8–28.2; said gravel – 42.3–43.5; said additive – 0.18–0.2; water – 7.82–8.2.EFFECT: technical result is the production of high-strength concrete with high frost resistance and high water 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 engineering, as well as in the construction of structures for special purposes.

A known mixture for the manufacture of high-strength concrete (RU, patent No. 2256629, IPC С04В 28/04. Date of publication 07/20/2009) containing Portland cement, sand, gravel, a silicon-containing component represented by H ₂ SiO ₃ sol with a density of p = 1.014 g / cubic cm, pH = 5-6, the addition of “DEYA-M” and water in the following ratio of components, wt. %: Portland cement 44.4-48.0; sand 20.0-22.2; crushed stone 20.0-22.2; the specified silicon-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 insufficient frost resistance and water resistance.

A known mixture for the manufacture of high-strength concrete (RU, patent No. 2323910, IPC С04В 28/04; СВВ 22/06 С04В 111/20. Publication date 05/10/2008), which contains wt. %: Portland cement 23.6-26.9; sand 23.7-25.2; crushed stone 36.8-38.4; Sol Fe (OH) ₃ with a density ρ = 1.018 g / cc, pH = 4.5 ... 5.5 0.7-0.76; water 11.9-12.04. The disadvantage of this technical solution is insufficient frost resistance and water resistance.

The closest in technical essence to the claimed invention is a mixture for high-strength concrete (RU, patent No. 2256630, IPC SOIV 28/04. Date of publication 20.07.2005) containing: Portland cement, sand, gravel, silica-containing component represented by H ₂ SiO sol ₃ s ρ = 1.014 g / cc pH = 5 ... 6 additive - potassium ferruginous 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 H ₂ SiO ₃ sol with a density ρ = 1.014 g / cc, pH = 5 ... 6 0.25-0.27 Additive - potassium ferruginous K ₄ Fe (CN) ₆ 0.44-0.47 Water 12,1-12,15

The disadvantage of this technical solution is insufficient frost resistance and water resistance.

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

The task is achieved in that high-strength concrete contains Portland cement, sand, gravel, additive and water.

New in comparison with high-strength concrete, adopted as a prototype, is that sand with a particle size modulus of 2.26, crushed stone of a fraction of 10-20 mm and a complex additive consisting of the following components, wt. %:

20% solution of polycarboxylant polymer (CP-WRM), having a pH value of pH = 6 and density ρ = 1,029 g / cc 60.0-65.0 High molecular weight polymer compound with molecular weight more than 600 g / mol, density ρ = 0.98 g / cc and pH = 6.5 16.0-18.0 Colloidal solution (sol) of silicic acid with density ρ = 1.014 g / cc and pH = 3.5 19.0-22.0

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

- portland cement 19.9-21.9 - specified sand 27.8-28.2 - specified crushed stone 42.3-43.5 - indicated complex additive 0.18-0.2 - water 7.82-8.2

The use of this additive significantly enhances the hydration activity of the mixture for high-strength concrete, which contributes to the release of a large amount of heat inside the hardening system, which is stored in an increased amount inside the hardening system due to the presence of high molecular weight compounds with a high molecular weight in the recommended additive and, as a result, having a lower value coefficient of thermal conductivity and with heat-insulating properties.

Thus, the use of an additive with high reactivity, as well as the energy effect on the hardening system in the form of heat released during hydration reactions, has a positive effect on increasing hydration processes, which contributes to the involvement in hydration processes at an early age, up to 28 days, inactive minerals Portland cement, such as dicalcium silicate, 2CaO⋅SiO ₂ are just beginning generally at 28 days of hydration reaction to awaken and processes for jected individual minerals. An increase in the degree of hydration contributes to the formation of a denser structure of high-strength concrete and, as a consequence, to an increase in its durability, which is assessed by an increase in the parameters of frost resistance and water resistance.

As the main hydration products, in addition to CSH (I) type silicates, according to the X-ray phase analysis, low-base hydrate compounds, such as 3CaO⋅SiO ₂ ⋅ 8H ₂ O nekoite, for which the interplanar distance d / n = (9.25; 3, 36; 2.82) nm. Nekoite crystals are represented by elongated fibers, which have a positive effect on increasing tensile strength during bending, as well as increasing the density of the concrete structure. A hydrosilicate of complex composition was also found, such as 3CaO⋅SiO ₂ ⋅ 3H ₂ O afvillite for which the interplanar distance d / n = (6.46; 5.74; 4.73; 3.19; 2.84) nm. The formation of these complex hydrated compounds is confirmed by differential thermal studies. For hydrosilicate CSH (I), a uniform release of water is observed in the temperature range 180 to 460 ° C, which is confirmed by the wide endothermic effect in the temperature range 180 ° C to 460 ° C.

The formation of necoite is confirmed by the presence of an endothermic effect at a temperature of ≈727 ° С and the presence of an exothermic effect at a temperature of ≈770 ° С. The presence of afvillite is evidenced by a wide endothermic effect in the temperature range 385 ° С-395 ° С, as well as a small exothermic effect at a temperature of 815 ° С.

In addition, in the hardened stone, regardless of the hardening conditions, hydrolysis lime, Ca (OH) ₂ , which, as a rule, is formed upon hydration of tricalcium silicate, the main mineral of Portland cement, is almost completely absent. This is due to the fact that there is an interaction of Ca (OH) ₂ with colloidal particles of SiO ₂ nH ₂ O, which are part of the proposed chemical additives, which leads to the additional formation of complex hydrated compounds.

All of the above shows that during the hardening process, in the presence of the proposed additive, an increased amount of hydrated compounds is formed, which contributes to the formation of the most dense structure of high-strength concrete, which positively affects the increase in frost resistance and water resistance, which results in an increase in the durability of high-strength concrete.

At the filing date, in the opinion of the author and 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, namely, it increases the hydration activity of the mixture for high-strength concrete, resulting in the formation of the most dense structure of high-strength concrete and, as a result, an increase in frost resistance by 2.7 times and an increase in water resistance by 2 times.

A mixture including Portland cement, sand with a particle size modulus of 2.26, crushed stone of a fraction of 10-20 mm, an additive represented by a complex consisting of a 20% solution of polycarboxylate polymer CP-WRM having a pH value of 6.0 and a density of ρ = 1,029 g / cc; a high molecular weight polymer compound with a molecular weight of more than 600 g / mol, density ρ = 0.98 g / cc and pH = 6.5; a colloidal solution (sol) of silicic acid with a density of ρ = 1.014 g / cc and pH = 3.5 ensured the production of high-strength concrete, characterized by increased frost resistance and increased water resistance.

According to the authors and the applicant, the invention meets the eligibility criterion - 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.

An example of a specific implementation.

1. Preparation of the proposed complex additives.

1.1. Dose a 20% solution of the polycarboxylate polymer CP-WRM, having a pH value of 6.0 and a density of p = 1.029 g / cc;

1.2. Dose high molecular weight polymer compounds with a molecular weight of more than 600 g / mol, density, ρ = 0.98 g / cc and a pH value of 6.5;

1.3. The colloidal solution (sol) of silicic acid with a density of ρ = 1.014 g / cc and a pH value of 3.5 is dosed.

1.4. The metered-dose components according to clause 1.1, clauses 1.2 and 1.3 are thoroughly mixed with a slow-moving mixer until a homogeneous solution is formed.

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

2.1. Sand is dosed with a particle size modulus of 2.26.

2.2. Crushed stone fractions of 10-20 mm are dosed.

2.3. Dose the proposed complex supplement prepared according to p. 1.4.

2.4. Dose water.

2.5. The dispensed components according to paragraph 2.1, paragraph 2.2, 2.3 and 2.4 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 made of high-strength concrete for industrial and civil construction, as well as for special purposes.

To determine the frost resistance, cubes of 100 × 100 × 100 mm in size are made in the amount of 21 pcs., To determine the frost resistance according to GOST 10060-2012. “Concrete. Methods for determining frost resistance. "

To determine the water resistance, cylinder samples with a diameter of 150 mm and a height of 150 mm in the amount of 6 pcs are made. and the test is carried out according to GOST 12730.5-84 "Concrete. Methods for determining water resistance. ”

The results are presented in the table.

Claims (4)

High-strength concrete obtained from a mixture including Portland cement, sand, crushed stone, additive and water, characterized in that it contains sand with a particle size modulus of 2.26, crushed stone - crushed stone fraction 10-20 mm, additives - a complex additive consisting of the following components, wt. %: 20% solution of polycarboxylate polymer CP-WRM, 60.0-65.0 having a pH value of pH = 6 and density ρ = 1,029 g / cc High molecular weight polymer compound with 16.0-18.0 molecular weight more than 600 g / mol, density ρ = 0.98 g / mol and pH = 6.5 Colloidal solution (sol) of silicic acid with 19.0-22.0 density ρ = 1.014 g / cc and pH = 3.5 in the following ratio of components of the mixture, wt. %: Portland cement 19.9-21.9 specified sand 27.8-28.2 specified crushed stone 42.3-43.5 specified complex additive 0.18-0.2 water 7.82-8.2