RU2511245C2 - Production of all-purpose construction boards - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to production of construction materials and can be used for production of boards for internal and external facing of whatever buildings, spandrel panels, stair boards and small architectural structures. Proposed method comprises mixing of magnesite binder, organic filler, mineral filler and aqueous solution of magnesium chloride, forming of the articles, their curing and drying. Mineral filler consists of two or more components one of which being a co-precipitated calcium-magnesium component and another one being the perlite. Aqueous solution of magnesium chloride is mixed with corrosion inhibitor before addition to the mix. Note here that ratio of components in common mix is as follows, in wt %: magnesite binder - 10-40, aqueous solution of magnesium chloride with density of 1.1-1.3 g/cm³ - 40-70, organic filler - 4-15, mineral filler - 2-20, and corrosion inhibitor - 0.015-0.025. Plasticiser can be added in amount of 0.01-0.50%, in terms of dry mass, of total weight.

EFFECT: lower corrosion activity, optimum operating properties, non-polluting boards.

11 cl

Description

The invention relates to the field of production of building materials and products and can be used in the manufacture of plates and panels intended for internal and external cladding of industrial and civil buildings, window sills, stair steps and small architectural forms.

The basis of many building materials (flooring, wall partitions, panels, etc.) are magnesia cements.

Magnesia cement is a material containing active magnesium oxide (caustic magnesite, caustic dolomite or synthetic magnesium oxide), sealed with a solution of magnesium salt. As a solution of magnesium salt, solutions of magnesium chloride or magnesium sulfate are most often used. Magnesia binder, sealed with a solution of magnesium chloride, is called Sorel cement. Sorel cement consists of magnesium oxychlorides, the composition of which depends on the conditions of preparation and storage [Nanazashvili I.Kh. Building materials from wood-cement composition. L .: Stroyizdat, 1990, 415 p.]. During hardening of magnesia cement, magnesium hydroxide is formed along with magnesium oxychlorides [Volzhensky A.V. Mineral binders. M .: Stroyizdat, 1986.464 p.].

Magnesium hydroxide has fire-resistant properties, which leads to its use as a filler - flame retardant in the production of polymer compositions (PVC, PA, PE, PP, ABS and other thermoplastics, thermosets, elastomers), in rubber compounds and coatings, in the paper industry (Pozin M .E. Mineral salts technology, part 1, ed. 4. L .: Chemistry, 1974; Polyvinyl chloride / Salmers J., Wilkie C., Daniele C. St. Petersburg: profession, 2007). In addition, magnesium hydroxide has a very low solubility and poorly expressed basic properties.

Fillers for magnesia cements are sawdust, shavings, bonfires, etc. (Pozin M.E. Technology of mineral salts (fertilizers, pesticides, industrial salts, oxides and acids), part I.L .: Chemistry, 1974, 792 p., Volzhensky A.V. Mineral binders. M .: Stroyizdat , 1986, 464 pp., Nanazashvili I.Kh. Building materials from wood-cement composition. L .: Stroyizdat, 1990, 415 pp.].

The solution of magnesium chloride is an excellent flame retardant impregnation for organic fillers, and also prevents the development of microorganisms and mycelium in organic fillers [Nanazashvili I.Kh. Building materials from wood-cement composition. L .: Stroyizdat, 1990, 415 p.].

All this makes building materials based on magnesia cements antibacterial, fire resistant and environmentally friendly.

The known method [RF Patent No. 2276117] for obtaining a raw mixture, including mixing caustic magnesite with sawdust, followed by moistening the mass with an aqueous solution of bischofite, which is pre-mixed with 0.3-0.6 vol.h. iodinol. The addition of iodinol to bischofite allows you to achieve the balneological effect of the raw mix. However, the material obtained by this method does not have high strength and can only be used as a decoration: in the form of facing tiles, wall panels and elements of lattice partitions.

There is also known a method of manufacturing building materials on a magnesian binder [RF Patent No. 2121987], comprising mixing a caustic magnesite powder, a mineral filler and an aqueous solution of magnesium chloride, molding the products and curing them, in which the mineral filler is pre-activated by co-grinding with chemical and / or mineral additives. The mineral additive is electrothermophosphoric slag or pyrite cinders or a mixture thereof, and the chemical additive is a superplasticizer or organosilicon liquid, or a mixture thereof. The introduction of a superplasticizer (preferably grade C-3) provides an increase in the mobility of the magnesia mixture, which allows the use of injection molding technology. This method allows the disposal of industrial waste, such as electrothermophosphorus slag and pyrite cinder, however, the strength characteristics of the obtained building material are not high enough: the tensile strength at bending at the age of 28 days for different compositions is from 4.4 to 11.8 MPa and environmental safety of such material raises certain concerns.

In the method of preparing the raw material mixture [RF Patent No. 2098381], comprising mixing a magnesian binder with a filler followed by mixing with a bischofite solution, the bischofite solution is pre-treated in a magnetic field of 160-340 kA / m at a solution flow rate in the magnetic field of 0.6-1 , 5 m / s. To enhance the effect of magnetic treatment, bischofite solution is passed through the specified magnetic field several times. Preliminary processing of an aqueous solution of bischofite in a magnetic field, according to the authors, leads to its positive structural changes, which contributes to a more dense and fine-grained structure of the material. By replacing sawdust in the recipe with a mixture of sand with talc, the authors were able to reduce water absorption to 3.5% and increase the flexural strength to 15 MPa. However, the exclusion of sawdust from the recipe leads to a decrease in the soundproofing properties of the resulting boards and an increase in their thermal conductivity, which is acceptable in the manufacture of tiles, but undesirable when using a raw material mixture for the manufacture of building boards for various purposes. In addition, repeated treatment of bischofite solution with a magnetic field is an apparatus complication of the process and increases the cost of building material.

The closest to the essence, taken as a prototype, is a method of obtaining a raw material mixture for the manufacture of building products [RF Patent No. 2090535], comprising mixing caustic magnesite with cellulose-containing aggregate of plant origin, for example sawdust, followed by moistening the mass with a solution of magnesium chloride and final mixing. The expanded perlite introduced into the composition is preliminarily pollinated with caustic magnesite. Expanded perlite increases the characteristics of heat and sound insulation and fire safety of building products. However, building products obtained by this method have a very low tensile strength in bending, which is 7-8 MPa.

After hardening, magnesia cement may contain residual amounts of unreacted magnesium chloride. The presence of magnesium chloride is responsible for the corrosive activity of magnesia cement, to reduce which corrosion inhibitors are introduced.

In all of the above methods, in the resulting building products, there is no protection against the corrosive effects of salts, while it is known that in contact with metal structures, magnesium and sodium chlorides cause increased corrosion of the metal [Nanazashvili I.Kh. Building materials from wood-cement composition. L .: Stroyizdat, 1990, 415 p.]. So, for example, magnesium chloride, sodium chloride and their mixtures when used in the composition of anti-icing materials to achieve the desired value of corrosion activity on the metal must contain a corrosion inhibitor.

It is known that to reduce the corrosion of solutions containing chlorides of alkali and alkaline earth metals, corrosion inhibitors such as dihydrogen phosphates and hydrophosphates of alkali and alkaline earth metals are successfully used [A.S. USSR No. 482488, RF Patent No. 2302442, Russian Federation No. 2313553, Russian Federation No. 2314329].

The aim of the present invention is to provide a method for the manufacture of multi-purpose building boards with environmental safety and sufficient performance characteristics, such as strength, heat and sound insulation while reducing their cost and corrosion activity for equipment in contact with them.

This goal is achieved in that the method of manufacturing building boards for universal use includes mixing a magnesian binder, an organic filler, a mineral filler and an aqueous solution of magnesium chloride, followed by molding, curing and drying, the mineral filler consisting of two or more components, one of which is together precipitated calcium-magnesium component, the second - perlite, and an aqueous solution of magnesium chloride before being added to the mixture is pre-mixed with and corrosion inhibitor, while the ratio of components in the total mixture is, wt.%:

Magnesia binder 10-40 A solution of magnesium chloride with a density of 1.1-1.3 g / cm ³ 40-70 Organic filler 4-15 Mineral filler 2-20 Corrosion inhibitor 0.015-0.025

Caustic magnesite, caustic dolomite, calcined brucite and synthetic magnesium oxide can be used as magnesia binder.

To prepare an aqueous solution of magnesium chloride with a density of 1.1-1.3 g / cm ³ can be used hexahydrate magnesium chloride or a solution of magnesium chloride of natural origin (bischofite).

To reduce the corrosion of metal equipment in contact with building plates, a corrosion inhibitor in the amount of 0.015-0.025% of the mass is preliminarily introduced into the magnesium chloride solution. As a corrosion inhibitor, sodium dihydrogen phosphate and sodium hydrogen phosphate can be used.

As an organic filler, wood sawdust, wood flour, husk of rice seeds, husk of cotton seeds, husk of sunflower seeds or a mixture thereof, etc. can be used.

The unique properties of the building material are ensured, in particular, by the fact that the mineral filler consists of two or more components, one of which is a co-precipitated calcium-magnesium component, and the second is perlite.

The co-precipitated calcium-magnesium component has the following composition,% wt: calcium carbonate 70-80, magnesium hydroxide 10-20, sodium chloride 5-9, water the rest. Calcium carbonate included in its composition reduces water absorption and, as a consequence, the swelling of the material, is an inert, non-combustible and environmentally friendly filler. Magnesium hydroxide, as mentioned above, is a widespread and also environmentally friendly flame retardant. Sodium chloride is an additive that eliminates the tendency of the material to crack due to the reduction of structural defects by incorporation into the structure of magnesia stone. Sodium chloride is also a non-combustible and environmentally friendly component. Thus, the co-precipitated calcium-magnesium component as a whole is non-combustible and environmentally friendly, having a number of properties useful for building materials. Due to co-precipitation, its constituents are a granulometrically and chemically highly homogeneous mixture.

As a co-precipitated calcium-magnesium component, in particular, soda-caustic sludge from the production of sodium hydroxide brine by the electrolysis method, which is a waste product, can be used.

To use the entire set of properties of the co-precipitated calcium-magnesium component, it is necessary that its content in the mineral filler be in the range of 1-97% wt.

Expanded perlite increases the characteristics of heat and sound insulation and fire safety of building products.

The mineral filler, in addition to these components, may additionally contain a component selected from the group of natural or synthetic silicon compounds, including sand, white soot, feldspar, serpentinite, bentonite, kaolin, wollastonite, vermiculite, etc., or a mixture thereof. Silicates and silicas of various origin are used in magnesia cements as mineral fillers and modifying additives that increase the strength, water resistance and frost resistance of products based on magnesia binders.

Additionally, to increase the mobility and viability of the molding material, it is possible to add a plasticizer in an amount of 0.01-0.50% (in terms of dry matter) of the total mass. As a plasticizer, a plasticizer based on sodium polymethylene sulfonate or on a sulfonated naphthalene formaldehyde base, or on a sulfonated melamine formaldehyde base, or on a polyethylene glycol basis, or on the basis of polycarboxylates can be used.

The molding of building boards obtained by the proposed method can be carried out by casting, casting with vibration sealing, casting by rolling, etc. When forming, it is possible to arrange the upper and lower layers of the fiberglass mesh and / or non-woven fabric. The formation and curing of building boards is carried out at a temperature of 20-40 ° C, and for curing, depending on the temperature, 16-24 hours are required.

The proposed method of manufacturing building boards for universal use is illustrated by the following examples.

In brackets are indicated wt.% Component about the total mass of the load.

Example 1

54.0 parts by weight are mixed. (21.8 wt.%) Synthetic magnesium oxide, 21.2 wt.h. (8.6 wt.%) Sawdust, 3.2 wt.h. (1.3 wt.%) Perlite, 6.0 wt.h. (2.4 wt.%) Co-precipitated calcium-magnesium component of the composition,% wt.: Calcium carbonate 72, magnesium hydroxide 19, sodium chloride 5, water - the rest. The resulting dry mixture was shut 162.8 wt.h. (65.9 wt.%) A solution of magnesium chloride with a density of 1.18 g / cm ³ pre-mixed with 0.04 wt.h. (0.016 wt.%) Sodium dihydrogen phosphate. Stir until a homogeneous mass. The resulting molding material is fed to a fiberglass layer placed on a substrate, covered with a second fiberglass layer and rolled to seal and remove voids. After curing, the samples are removed from the substrate and dried at a temperature of 20 ° C for 28 days. The obtained samples have the following characteristics: ultimate flexural strength (at the age of 28 days) - 16 MPa; frost resistance - more than 50 cycles; density - 950 kg / m; water absorption - 20%.

Example 2

70.0 parts by weight are mixed. (30.3 wt.%) Calcined brucite, 17.0 wt.h. (7.4 wt.%) Husks of rice seeds, 2.8 wt.h. (1.2 wt.%) Perlite, 17.5 wt.h. (7.6 wt.%) Sand, 22.5 wt.h. (9.7 wt.%) Co-precipitated calcium-magnesium component. As a co-precipitated calcium-magnesium component, soda-caustic sludge is used to purify the sodium hydroxide production brine using the following composition, wt%: calcium carbonate 74, magnesium hydroxide 16, sodium chloride 7, water 3. The resulting dry mixture is closed with 101.2 wt. hours (43.8 wt.%) A solution of magnesium chloride with a density of 1.24 g / cm ³ pre-mixed with 0.034 wt.h. (0.015 wt.%) Sodium dihydrogen phosphate. The molding is carried out according to example 1. The samples obtained have the following characteristics: ultimate tensile strength in bending (at the age of 28 days) - 13 MPa; frost resistance - more than 50 cycles; density - 1300 kg / m ³ ; water absorption - 8%.

Example 3

147.5 parts by weight are mixed. (30.0 wt.%) Calcined brucite, 70.8 wt.h. (14.4 wt.%) Rice husk, 7.9 wt. (1.6 wt.%) Perlite, 1.9 wt.h. (0.4 wt.%) Co-precipitated calcium-magnesium component of the composition specified in example 2. The resulting dry mixture was shut 256.1 wt.h. (52.1 wt.%) A solution of magnesium chloride with a density of 1.24 g / cm ³ pre-mixed with 0.08 wt.h. (0.016 wt.%) Sodium dihydrogen phosphate and with 7.4 wt.h. superplasticizer C-3 in liquid form, which in terms of dry matter is 1.85 wt.h. (0.38 wt.%). The molding is carried out according to example 1. The samples obtained have the following characteristics: ultimate tensile strength (at the age of 28 days) 13.4 MPa; frost resistance more than 50 cycles, density 1120 kg / m ³ ; water absorption of 6.5%.

Example 4

70.0 parts by weight are mixed. (30.6 wt.%) Calcined brucite, 22.0 wt.h. (9.6 wt.%) Rice husks, 3.4 wt.h. (1.5 wt.%) Perlite, 1.2 wt.h. (0.5 wt.%) Vermiculite and 1.1 wt.h. (0.5 wt.%) Co-precipitated calcium-magnesium component of the composition specified in example 2. The resulting dry mixture was shut 131.3 wt.h. (57.3 wt.%) A solution of magnesium chloride with a density of 1.24 g / cm ³ pre-mixed with 0,034 wt.h. (0.015 wt.%) Sodium hydrogen phosphate. The molding is carried out according to example 1, except that the molding mass is covered not with a fiberglass mesh, but with a non-woven fabric. The obtained samples have the following characteristics: ultimate flexural strength (at the age of 28 days) - 18 MPa; frost resistance - more than 50 cycles; density - 1090 g / cm ³ ; water absorption - 14%.

The presented examples show that the use of the proposed method for the manufacture of building boards allows to obtain building boards with a sufficiently high strength characteristics.

The examples are illustrative and do not limit the scope of the claimed invention.

EFFECT: invention makes it possible to significantly reduce the cost of production of building materials on a magnesian binder by using sludge from soda-caustic brine cleaning, which is a waste product, and to reduce the corrosion activity of building boards while maintaining optimal performance characteristics.

Universal building boards manufactured by the proposed method are environmentally friendly and biologically resistant material, are not subject to decay and burning due to the antiseptic and flame retardant properties of their constituent components. They are easy to process (sawing, drilling, driving nails); have a reduced corrosion activity in relation to metal fasteners, fittings and contact equipment; can be used for housing and industrial construction.

Claims (11)

1. A method of manufacturing building boards for universal use, comprising mixing a magnesian binder, an organic filler, a mineral filler and an aqueous solution of magnesium chloride, followed by molding, curing and drying, characterized in that the mineral filler consists of two or more components, one of which is together precipitated calcium-magnesium component, perlite is the second, and an aqueous solution of magnesium chloride is mixed with a corrosion inhibitor before being added to the mixture ii, while the ratio of components in the total mixture is, wt.%:
Magnesia binder 10-40 A solution of magnesium chloride with a density of 1.1-1.3 g / cm ³ 40-70 Organic filler 4-15 Mineral filler 2-20 Corrosion inhibitor 0.015-0.025 2. The method according to claim 1, characterized in that the magnesian binder is selected from the group comprising caustic magnesite, caustic dolomite, calcined brucite and synthetic magnesium oxide. 3. The method according to claim 1, characterized in that the organic filler is selected from the group comprising sawdust, wood flour, husk of rice seeds, husk of cotton seeds, husk of sunflower seeds or a mixture thereof. 4. The method according to claim 1, characterized in that the mineral filler consists of perlite, co-precipitated calcium-magnesium component and, optionally, a filler selected from the group of natural or synthetic silicon compounds, including sand, white soot, feldspar, serpentinite, bentonite, kaolin, wollastonite, vermiculite or a mixture thereof. 5. The method according to claim 1, characterized in that the mineral filler contains 1-97 wt.% Co-precipitated calcium-magnesium component. 6. The method according to claim 1, characterized in that the co-precipitated calcium-magnesium component has the following composition, wt.%: Calcium carbonate 70-80, magnesium hydroxide 10-20, sodium chloride 5-9, water - the rest. 7. The method according to claim 1, characterized in that as a co-precipitated calcium-magnesium component, sludge is used for soda-caustic cleaning of the brine for the production of caustic soda by the electrolysis method. 8. The method according to claim 1, characterized in that the corrosion inhibitor is selected from the group comprising sodium dihydrogen phosphate and sodium hydrogen phosphate. 9. The method according to claim 1, characterized in that a plasticizer is additionally added to the molding mass in an amount of 0.01-0.50% (in terms of dry matter) of the total mass. 10. The method according to claim 1, characterized in that when forming the building boards with the lower and upper layer, the glass mesh and / or non-woven fabric are laid in one and / or two layers. 11. The method according to claim 1, characterized in that the curing of the mixture is carried out at a temperature of 20-40 ° C for 16-24 hours