RU2145315C1 - Heat-insulating concrete - Google Patents

Abstract

FIELD: manufacture of products from heat-insulating concrete both in civil and industrial engineering. SUBSTANCE: heat-insulating concrete comprises cement sand, foam-forming additive, and water. Concrete further comprises finely divided metallurgical slag which has Fe (II) content of not higher than 4%, chemical additive with pH of 5.5-6, aluminium powder mixed with foam-forming sodium stearate based-additive with density of 1.15-1.17 kg/cu. cm and synthetic fibrofiber, ratios of components being as follows, wt.%: cement, 43.0-46.2; metallurgical production slag, 12.0-14.4; sand, 18.0-19.0; sodium stearate based foam-forming additive with density of 1.15-1.17 g/cu. cm, 9.5-10.3; chemical additive, 0.4- 0.6; fibrofiber, 1.4-1.8; and water, 12.0-14.4. EFFECT: greater bending strength, higher porosity and improved sound-protecting properties of concretes and products made from thereof. 1 tbl

Description

 The invention relates to the field of building materials, in particular to insulating concrete.

 Heat-insulating concrete is known, including cement, sand, water and foam concentrates [1].

 Closest to the invention is concrete, including cement, sand, a foaming additive, water [2].

 Known concretes do not have sufficient total porosity, which does not provide sufficiently high heat-shielding and sound-shielding properties.

 The objective of the invention is the creation of new heat-insulating concrete with improved soundproof and heat-shielding properties of the material while increasing bending strength and increasing the overall porosity of the material.

 The problem is solved in that the insulating concrete contains cement, sand, a foaming additive.

New is that it additionally contains finely ground slag of metallurgical production, in which the content of Fe (II) in an amount of not more than 4 wt.%, Chemical additive "DAY" with a pH of 5.5-6, aluminum powder mixed with a foaming additive on based on sodium stearate density 1.15-1.17 g / cm ³ and synthetic fiber, with the following ratio of components wt.%:
Cement - 43.0-46.2
Metallurgical slag - 12.0-14.4
Sand - 18.0-15.0
Foaming additive - 9.5-10.3
Chemical additive "DAY" - 0.4-0.5
Aluminum powder - 0.5-0.6
Fiber - 1.4-1.8
Water - 12.0-14.4
The DEYA chemical additive includes post-yeast distillery vinasse, a modifier and contains, as a modifier, an expanded porous product with a bulk density of 0.6 g / cm ³ in an amount, wt.% 3.0 ± 0.5, represented by calcium-magnesium silicates.

Calcium-magnesium silicates are mainly represented by C ₂ AS gelenite, the amount of which, wt.%, Is not less than 80.

 The grain size of the modifier is selected from 0.5-5.0 mm.

 The solids content in the post-yeast stillage, wt.% - 3.5-4.5.

The functions of the chemical additive are as follows:
the additive plasticizes the concrete mixture, while the decrease in W / C by 0.06-0.08;
the additive activates the hydration activity of the cement, acting on its minerals, increasing the degree of hydration, mainly of tricalcium silicate and dicalcium silicate C ₂ S. Moreover, not only the amount of hydration products increases, but their quality composition also changes: the number of low-basic hydrosilicates with a fibrous structure increases , the formation of which, apparently, changes the structure of concrete itself, which contributes not only to increase strength at an early and design age, but also to increase frost resistance and water resistance.

 A method of preparing a chemical additive "DAY" is as follows.

 Dosage modifier and post-yeast bard are mixed for 1 hour.

 The finished product is stored in vertical conical containers equipped with air for periodic sparging.

 At the filing date, according to the authors and the applicant, the claimed insulating concrete is unknown and this technical solution has world novelty.

 The inventive combination of essential features exhibits a new property, which allows to obtain a technical result.

 The property of finely ground slag of metallurgical production is known to increase cement hydration when combined together [3].

 It is known that the addition of “Day” with a pH of 5.5–6 enhances the activation of cement [4].

 Aluminum powder forms pores in the presence of acid.

 The authors and the applicant believe that the achievement of the technical result — an increase in the thermal insulation properties of concrete — depends on an increase in the overall porosity of the material, an improvement in sound insulation properties is due to both an increase in porosity and the presence of pores of different sizes, while improving the deformation characteristics of concrete (bending strength), which improves due to the formation of products of hydration of the fibrous structure.

 The inventive combination of essential features exhibits a new property, which allows to obtain a technical result.

The combined presence of finely ground slag of metallurgical production, cement and sodium stearate enhances the hydration activity of cement and slag, forming a large number of partially crystallized tobermorite-like calcium hydrosilicates (CSH (II)), which have a fibrous structure that prevents the propagation of sound waves in concrete, and also hydrosilicates of the composition 3CaO • Al ₂ O ₃ • 1.17 SiO ₂ • 3.66H ₂ O (d / n = 3.09; 2.788; n = 1.600-1.620). Aluminum powder mixed with a foaming additive of sodium stearate with a density of 1.15-1.17 g / m ³ in the presence of a chemical additive "DEYA" with a pH of 5.5-6 promotes the formation of micropores of a certain size.

 A new foaming additive of sodium stearate forms larger pores. The presence of synthetic fiber in concrete forms an elongated pore. The presence of three types of pores of different shapes and sizes leads to the attenuation of the sound wave during its propagation in concrete, improving the soundproof properties of concrete.

 Given the foregoing, we can conclude that the invention does not explicitly follow from the prior art and the whole set of essential features exhibits a new property that allows to achieve the specified technical result, i.e. The invention meets the eligibility criteria - inventive step.

 The claimed invention meets the criterion of "industrial applicability", as it can be used in industrial and civil engineering for the manufacture of products with improved heat and sound protection properties.

 The feasibility of the invention is confirmed by examples of specific performance.

Concrete example
I. Production of heat-insulating concrete:
1. Dose cement;
2. Dose finely ground slag of metallurgical production;
3. Dose sand;
4. Dose fiber;
5. Dose water;
6. DOSE chemical additive is dosed (see TU 5743006-00353595-97) and poured into dosed water;
7. Prepare a foaming additive:
sodium stearate solution, C ₁₉ H ₂₉ COONa • 3C ₁₉ H ₂₉ COOH, densities 1.15 ... 1.17 g / cm ³ , obtained by dissolving laundry soap in warm water (t = 25 ... 30 ^o C) and thoroughly mix the solution to obtain a foaming additive;
8. Dose the resulting foaming additive;
9. Dose aluminum powder;
10. Mix the dosed aluminum powder with the dosed foaming additive;
11. Prepare the concrete mixture by mixing in the mixer the dosed cement, slag of metallurgical production, sand, fiber and water;
12. Prepare the foam by whipping in the foam generator a foaming additive mixed with aluminum powder;
13. Prepare a foam concrete mixture by adding foam containing aluminum powder to the resulting concrete mixture, mix everything thoroughly for 1.5 ... 2.0 minutes;
14. Foam concrete mixture is used for the manufacture of products of the required shape, and the manufacture of samples for physical and mechanical tests;
15. Concrete hardening was carried out under normal conditions at a temperature of 20 ± 2 ^o C and at a humidity of at least 95%, for 28 days.

 The results of physical and mechanical tests are presented in the table.

 An analysis of the data in the table shows that the proposed composition provides heat-insulating concrete, from which the sound permeability of the wall decreases by 16 ... 19%, the thermal conductivity decreases by 32%, the flexural strength increases by 47 ... 72% and the compressive strength increases by 19 ... 27%.

 Thermal insulation concrete, characterized by physical and technical characteristics indicated in the table, can be used for housing and civil engineering.

Sources of information
1. U.K. Makhambetova, T.K. Saltambekov, Z.A. Estemesov "Modern foam concrete" St. Petersburg, 1997. p. 103.

 2. Ibid., P. 142, prototype.

 3. Gerke S.G. "Obtaining and use for the construction of slag eco-materials", abstract of the dissertation for the degree of candidate of technical sciences, St. Petersburg, 1994, 24 pp.

 4. Addition to DEYA concrete TU 5743-006-00353595-97.

Claims (1)

Heat-insulating concrete, including cement, sand, a foaming additive, water, characterized in that it additionally contains finely ground slag of metallurgical production, in which the content of Fe (II) in an amount of not more than 4%, chemical additive "DEY" with a pH of 5.5 - 6, aluminum powder mixed with a foaming additive based on sodium stearate with a density of 1.15 - 1.17 g / cm ³ and synthetic fiber, in the following ratio, wt.%:
Cement - 43.0 - 46.2
Metallurgical slag - 12.0 - 14.4
Sand - 18.0 - 15.0
Foaming additive based on sodium stearate density 1.15 - 1.7 g / cm ³ - 9.5 - 10.3
Chemical additive "DAY" - 0.4 - 0.5
Aluminum powder - 0.5 - 0.6
Fiber - 1.4 - 1.8
Water - 12.0 - 14.4

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