RU84372U1 - BUILDING CONSTRUCTION FROM SILVER CONCRETE MIX - Google Patents

Abstract

A building structure, the basis of which is a monolithic body of a hardened sulfur-concrete mixture, including sulfur, an inorganic finely divided filler, aggregate and a modifying additive, characterized in that its sulfur-concrete mixture contains finely ground dolomite powder as a filler, dicyclopentadiene as a modifying additive, and aggregate are basalt screenings and sand in the following proportions, wt.%:! Basalt screenings 33,509-47,295 Sand 21,190-30,0 Dolomite powder 9,1-18,190 Technical sulfur 13,6-27,1 Dicyclopentadiene 0.005-0.011

Description

The utility model relates to building structures made of concrete, in particular, containing sulfur. Mostly such structures include foundations and foundations, as well as concrete products obtained by pouring concrete mixture into molds, formwork.

Known building construction made of concrete for protection against ionizing radiation [1], including an astringent, finely ground additive, coarse and fine aggregate and modifying additive, characterized in that this concrete contains as a finely ground additive - soot, as fine and coarse aggregates - crushed coal with a particle diameter of 0.315-0.63 mm and 5-10 mm, respectively, as a modifying additive, kerosene in the following ratio of components, wt.% sulfur 28.7-33.2, carbon black 3.4-5, 2, coal sand with a diameter rum of particles 0.315-0.63 mm 19.3-22.8. crushed stone from coal with a particle diameter of 5-10 mm 38.1-48.2, kerosene 0.4-0.7.

The disadvantage of the design is that the composition of the concrete mix used in this design includes coal, which can be used as fuel. Using it as a concrete aggregate is irrational.

A known design for protection against ionizing radiation, the basis of which is a composition for the manufacture of building products [2]. This patent describes a structure containing a composition comprising sulfur, an additive, a filler and a filler, characterized in that it contains lead shot with a particle diameter of 3-4 mm as a filler, and paraffin as an additive in the following ratio, wt. %: sulfur 7.55-9.5; paraffin 0.45-0.5; filler - a waste product of the production of optical glass with a specific surface area of 2000-2200 cm ² / g 14-17; aggregate - lead shot with a particle diameter of 3-4 mm - the rest. Products have an average density of 6690-7230 kg / m ³ , water absorption in 24 hours - 0.15-0.18%. The technical result is an increase in average density and a decrease in water absorption of the material. The material of construction is used primarily for protection against ionizing radiation.

Its disadvantage is the high cost of materials.

A known method of repairing concrete and reinforced concrete coatings [3], which includes removing the defective coating area and filling this area with building material, which is used as a mixture of sulfur binder and mineral filler in the following ratio of components in the mixture, wt.%: Sulfur binder 30-99 , mineral filler 1-70. Before filling the defective area of the coating, the building material is heated and laid at a temperature of 120-180 ° C, and the cleaned surface of the defective area is heated to a temperature of 80-120 ° C to a depth of at least 20 mm. The maximum grain diameter of the mineral filler of the building material does not exceed 30% of the depth of the defective area. The cleaned and heated surface of the defective area is primed with a sulfur binder at a temperature of 120-180 ° C.

Known designs that use concrete with a complex additive for concrete and mortar mixtures [4] containing potassium chromate, characterized in that it additionally contains sulfur and lime in the following ratio of components, dry. wt.%:

Potassium Chromate 40.0-60.0

Sulfur 26.0-39.0

Lime 21.0-14.0

Known concrete structures containing a binder [5], containing a filler, sulfur, a polymer sulfur stabilizer. A distinctive feature of it is that dolomitized limestone is used as a filler, and tetrapolysulfide is used as a stabilizer, with the following content of the starting components, wt.%:

Dolomitic limestone 50.0-66.7

Elemental sulfur 26.7-49.5

Tetrapolysulfide 0.3-10.0.

The lack of designs is that in the mixture the polymer component of sulfur requires stabilization, and the substance presented as a stabilizer, tetrapolysulfide, does not sufficiently reliably fix the polymer structure and over time, the latter turns into a crystalline one. This reduces the quality of concrete.

The task posed by the authors of the utility model is to create a building structure from building material with high physical and mechanical properties.

The authors of the design, in a detailed study of the temperature, chemical and mechanical methods for producing concrete during the modification of the sulfur melt, in order to obtain a sulfur binder, found that by changing the temperature of sulfur melting some of its crystals can be converted to a polymer modification, which significantly reduces the brittleness of the hardened sulfur melt and improves deformation properties. But the temperature modification requires chemical stabilization, since the polymer component of sulfur is unstable in time and reverses to crystalline over several days. Derivatives of cyclic and alicyclic compounds were considered as stabilizers: paraffin, naphthalene, anthracene, styrene, dicyclopentadiene. The last dicyclopentadiene modifier turned out to be most suitable for the filler in the form of dolomite powder and aggregates in the form of screenings of basalt and sand. Based on these components, sulfur concretes were obtained with the highest physical and mechanical characteristics, which significantly increase the strength of the building structure.

The problem was solved as follows: dolomite powder with a high degree of dispersion was used as a filler, and basalt screenings (crushed stone) and sand as a filler. High physical and mechanical properties are achieved due to the use of sulfur as a binder, and dicyclopentadiene as a modifying additive.

The inventive building structure, the basis of which is a monolithic body of hardened sulfur-concrete mixture, including sulfur, inorganic fine filler, aggregate and modifying additive. A distinctive feature of the proposed utility model is that its sulfur-concrete mixture contains finely ground dolomite powder as a filler, dicyclopentadiene as a modifying additive, and basalt screenings and sand in the following proportions, wt.%:

Basalt Screenings 47.295-33.509 Sand 30,0-21,190 Dolomite powder 9.1-18.190 Sulfur technical 13.6-27.1 Dicyclopentadiene 0.005-0.011

In this case, technical sulfur (lump or gas) is used that meets the requirements of GOST 127-76.

Sulfur concrete, which forms the basis of the claimed building structure, is obtained by mixing the above-mentioned ingredients with heating. Further, structural elements are obtained by casting this sulfur concrete into molds.

The created design based on this sulfur concrete has high strength, low water absorption, high frost, atmosphere and chemical resistance to most mineral acids and oil products, low heat conductivity.

The invention is suitable for the manufacture of both prefabricated and monolithic structures used for operation in aggressive environments, for the construction of roads and the manufacture of corrosion-resistant building structures and products for industrial and civil purposes, as well as structures that are subject to increased operational requirements.

The claimed construction of sulfur concrete differs from ordinary concrete in that it successfully resists the effects of aggressive environments (acids, salts). It has increased frost resistance, water resistance and durability. Production of sulfur concrete structures can also be successfully performed at low temperatures, where ordinary concrete requires heating.

According to the physico-mechanical parameters, the structures made of sulfur concrete comply with the following standards:

Strength, MPa:

on compression fifty, to bend 9.0 tensile 5.0, Water absorption,% (no more) 0.05 Air voids,% (within) 4-8, Chemical resistance in water with acidity pH = 3, Specific weight, kg / m ³ 2350-2700.

By their strength properties, structures created from the resulting sulfur concrete meet all the requirements for structures made of ordinary concrete, and in some cases, for example, in aggressive environments, the use of sulfur concrete in structures is more preferable.

List of used information sources.

1. Application No. 2002110088/03, Russia, Concrete for protection against ionizing radiation,

2. Application No. 99103937/04, Russia, Composition for the manufacture of building products,

3. Application No. 7842122, Ukraine, Method for repairing concrete coatings.

4. Application No. 2002103640, Method of repairing concrete and reinforced concrete coatings,

5. Application: 2002116134/03, Russia, Astringent (prototype).

Claims (1)

A building structure, the basis of which is a monolithic body of a hardened sulfur-concrete mixture, including sulfur, an inorganic finely divided filler, aggregate and a modifying additive, characterized in that its sulfur-concrete mixture contains finely ground dolomite powder as a filler, dicyclopentadiene as a modifying additive, and aggregate are basalt screenings and sand in the following proportions, wt.%: Basalt Screenings 33,509-47,295 Sand 21,190-30,0 Dolomite powder 9.1-18.190 Sulfur technical 13.6-27.1 Dicyclopentadiene 0.005-0.011