RU2365556C2 - Granulated pearlite-based compositional filler for silicate wall products, composition of raw material mixture for silicate wall products manufacturing, method of obtaining silicate wall products and silicate wall product - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to building materials production and can be used for obtaining silicate wall products - silicate bricks, tiles, blocks, wall panels, hardening during autoclave processing. Granulated compositional filler for silicate wall products, made from composition including silica-containing and lime-containing components, is made in form of granules with size 0.5-10.0 mm, consisting of core and envelope, where core is obtained by granulation of mixture of milled together until specific surface is 150-250 m²/kg silica-containing component - pearlite and alkali metal hydroxide with their weight ratio 0.70-0.95:0.05-0.30 with binding agent - water solution of sodium silicate with 1.2-1.3 g/cm³ density in amount 0.1-7.0% of mixture, and envelope is formed on core surface by rolling it with dry dust-like mixture of milled together live lime and sodium hexafluorosilicate with their weight ratio 0.85-0.95:0.05-0.15, with further hardening to strength not less than 2.1 MPa. Raw material mixture for wall products manufacturing, including, wt %: said filler 5.0-40.0, live lime 10.0-12.5, quartz sand 50.0-82.5. Method of obtaining silicate wall products, including obtaining of said raw material mixture by mixing its components, moistening mixture till humidity of formation, formation of products under pressure and their autoclave processing. Silicate wall product, characterised by being obtained by said method.

EFFECT: increase of water- and frost- resistance, reduction of heat conductivity with preservation of strength indices of silicate wall products, hardening during autoclave processing, reduction of energy consumption.

4 cl, 1 ex, 2 tbl

Description

The invention relates to the production of building materials and can be used to obtain silicate wall products - silicate brick, tiles, blocks, wall panels, etc., subjected to autoclaving during hardening.

A known method of producing silicate wall products, subjected to autoclaving during hardening, including the composition of the silicate mixture and aggregate in the form of expanded clay gravel. A method of producing silicate wall products, in particular silicate brick, involves mixing slaked lime (10.2-12.2 wt.%), Sand (39.8-47.8 wt.%), Aggregate in the form of expanded clay gravel with grain size 5-10 mm (40-50 wt.%), Wetting the mixture to molding moisture, molding building products that are subjected to autoclave hydrothermal treatment with hot steam [RF Patent No. 2243180, class 7 С04В 28/22, 2002].

The disadvantages of this method, the silicate mixture and the aggregate is that the aggregate used does not increase the water resistance and frost resistance of the silicate wall products, as well as the high energy consumption when obtaining a calcining aggregate - expanded clay gravel.

Closest to the proposed solution are a method of producing silicate wall products, for example, silicate brick, the composition of the silicate mixture, a composite aggregate for it in the form of clay-siliceous rock burnt at 1180 ° C and crushed to a fraction of 0.4-1.2 mm impregnated with lime suspension , and silicate wall product. The prototype method includes mixing two components - lime-containing and aggregate, consisting of a silica-containing component (expanded clay clay), impregnated with a lime-containing component (lime suspension), wetting the mixture to molding moisture, molding products and steaming in an autoclave at a pressure of 1 MPa at a temperature 178 ° C for 12 hours [RF Patent No. 2142440, class 6 С04В 28/18, 1998].

The disadvantages of this method, silicate mixture, aggregate and silicate wall product is that the aggregate used does not increase the water resistance and frost resistance of silicate wall products, it does not significantly reduce their thermal conductivity, as well as high energy consumption when receiving a calcined aggregate and, as a result, upon receipt wall products.

The present invention solves the problem of increasing water resistance and frost resistance, reducing heat conductivity while maintaining the strength characteristics of silicate wall products subjected to autoclaving during hardening, and also reduces energy consumption when receiving wall products by reducing energy consumption when receiving aggregate.

The technical result is achieved using a granular composite aggregate for silicate wall products made from a composition comprising silica-containing and lime-containing components, in which according to the proposed solution it is made in the form of granules with a size of 0.5-10.0 mm, consisting of a core and a shell, where nucleus obtained by granulating together a mixture of ground to a specific surface of 150-250 m ² / kg siliceous component - perlite and alkali metal hydroxide at a weight ratio 0,70-0,95: 0.05-0.30 a binder - aqueous solution of sodium silicate density of 1.2-1.3 g / cm ³ in an amount of 0,1-7,0% of the mixture, and the shell is formed by rolling it on the surface of the nucleus together dry pulverulent mixture of ground quicklime and sodium silicofluoride with their mass ratio of 0.85-0.95: 0.05-0.15, followed by hardening to a strength of at least 2.1 MPa.

The technical result is achieved in that the raw material mixture for the manufacture of silicate wall products includes the specified aggregate, quicklime and silica sand in the following ratio of components, wt.%: The specified aggregate is 5-40, quicklime 10.0-12.5 and quartz sand - 50.0 - 82.5.

The technical result is achieved by the fact that the method of producing silicate wall products includes obtaining the specified raw mix by mixing its components, moistening the mixture to a molding moisture, forming under pressure of the products and their autoclaving.

The result is achieved using a silicate wall product, characterized in that it is obtained in this way.

Component Feature:

1. As quicklime component for the raw material mixture and the protective shell of the aggregate used quicklime lime production of JSC "Building materials", Belgorod in accordance with GOST 9179-77.

2. As the silica-containing component of the raw material mixture used natural quartz Volsky sand according to GOST 6139-2003.

3. A volcanic water-containing glassy rock of the Mukhor-Talinsky perlite deposit (Republic of Buryatia) was used as a silica-containing component for the manufacture of the core of the filler (dust-free perlite formed during mechanical processing and not suitable for expansion). The chemical composition of perlite, wt.%: SiO ₂ - 72.8; Al ₂ O ₃ - 12.1, Fe ₂ O ₃ - 1.1, TiO ₂ - 0.4, CaO - 0.6; MgO - 1.1; R ₂ O - 7.3; p.p.p. - 5.7.

4. As the alkali metal hydroxide used sodium hydroxide according to GOST 2263-79.

5. Sodium silicofluoride Na ₂ SiF ₆ according to TU 6-09-1461-91.

6. Tap water in accordance with GOST 23732-79.

7. When granulating the powder of co-ground perlite with sodium hydroxide on a plate granulator, an aqueous solution of sodium silicate (water glass) was used in accordance with TU 2385-001-54824507-2000 with a density of 1.2-1.3 g / cm ³ .

To obtain cores of granular aggregate, when implementing the inventive method for producing silicate wall products, perlite was dosed with sodium hydroxide by the gravimetric method. The resulting mixture was loaded into a ball mill and mixed and milled until a specific surface of 150 ... 250 m ² / kg was reached. Granulation of the obtained mixture was carried out using a plate granulator by spraying on the surface of the powder an aqueous solution of sodium silicate with a density of 1.2-1.3 g / cm ³ . The speed of rotation and the angle of inclination of the granulator plate controlled the diameter of the granular material. The obtained cores were sent to pouring lime powder, ground together with sodium silicofluoride at a ratio of 0.85-0.95: 0.05-0.15 by weight. On a sieve with a mesh size of 0.5 mm, granular material was separated and sent for storage at ambient temperature. The strength gain of the granular aggregate was controlled at ambient temperature by a cylinder test in accordance with GOST 9758.

Example. Preparation of granular aggregate cores. Perlite (8 kg) and sodium hydroxide (2 kg), i.e. in a ratio of 0.80: 0.20 by weight (table., mixture 1), ground in a mill together to a specific surface of 200 m ² / kg. The obtained powder material was fed to a plate granulator. An aqueous solution of sodium silicate with a density of 1.25 g / cm ³ was applied to the surface of the powder by spraying. The rotation speed and the angle of inclination of the granulator plate controlled the diameter of the resulting cores, which in this case was 4.4–4.5 mm.

Obtaining a protective shell on the nuclei. The resulting cores were sent for dusting with a powder of lime (9 kg), ground together with sodium silicofluoride (1 kg), i.e. in a ratio of 0.90: 0.10 to obtain granules with a size of 5.0 mm (table 1, mixture 1). Dusting was carried out in a drum mixer.

Part of the obtained granular material after storage for 36 hours at ambient temperature was tested for strength by compression in a cylinder according to GOST 9758; the rest was used in the preparation of concrete mixtures for the manufacture of samples of building products. The compressive strength of the granules was 2.7 MPa.

Preparation of silicate raw mix. The components were dosed by the weight method: 1.15 kg of quicklime (11.5 wt.%, Table 1, mixture 1), 5.85 kg of sand (58.5 wt.%) And 3.0 kg (30 wt. %) of the granular aggregate was mixed, quenched in a screw mixer and dampened to a molding moisture content of 12%.

Samples were formed in the traditional way at a pressure of 20 MPa.

Hydrothermal processing of the samples was carried out in an autoclave at a pressure of 1 MPa and a temperature of 178 ° C for 12 hours according to the prototype [RF Patent No. 2142440, class 6 С04В 28/18, 1998].

A filler according to the prototype (see RF patent No. 2142440, example No. 4) consisted of ground to a fraction of 0.4-1.2 mm clay expanded rock impregnated with lime suspension, and had a crushing strength of 1.7 MPa in the cylinder.

The obtained samples of wall products were tested for strength (according to GOST 10180), thermal conductivity (according to GOST 7076), frost resistance (according to GOST 7025-91) and water resistance were determined - the relative loss of strength during compression of the samples after 25 soaking cycles. The test results are shown in table 2 (mixture 1).

In the same way, wall products with other compositions of components were obtained (Table 1), the results of determining the physicomechanical properties of silicate products after autoclaving are shown in Table 2, mixtures 1-5.

Analysis of the data in Table 2 of the test results of the properties of samples of silicate building products shows the following.

1. Introduction to the composition of the silicate mixture of the inventive granular aggregate with a size of 0.5-10 mm, consisting of a core in the form of together ground liquid perlite and alkali metal hydroxide, which is coated with a coating of ground lime and sodium silicofluoride in the claimed amounts, allows to obtain durable waterproof silicate wall products with reduced thermal conductivity, increased water resistance and frost resistance, while by eliminating the burning of aggregate, the energy is significantly reduced derived container wall products.

2. Reducing the amount of granular aggregate in the concrete mix to 5 wt.%, As well as the ratio in the core of the sodium hydroxide aggregate to 0.05 relative to the mass of perlite, the specific surface of the powder material of the core to 150 m ² / kg, the ratio of sodium silicofluoride in the granule shell up to 0.05 with respect to the weight of lime and the diameter of the aggregate granules to 0.5 mm reduces the strength of the granular aggregate, reduces its reactivity, which leads to an increase in thermal conductivity, a decrease in water oykosti, cold resistance and strength of the resulting silicate samples wall products (mixture of 2, Table 2), the composition taken as a boundary.

A further decrease in the above ratios and parameters leads to a significant decrease in the complex physical and mechanical properties of granular aggregate and silicate wall products, therefore, the composition of the mixture 4 is beyond the scope of the claimed compositions of silicate wall products.

3. The use of granular aggregate in the composition of the silicate mixture in an amount of 40 wt.%, As well as the ratio in the core of the filler of sodium hydroxide in an amount of 0.30 relative to the mass of perlite, the specific surface of the powder material of the core up to 250 m ² / kg, the ratio of sodium silicofluoride in the protective shell of the granule to 0.15 relative to the mass of lime and the diameter of the granules of the aggregate to 10 mm also leads to a decrease in the strength of the granular aggregate, increased consumption of liquid glass for a bunch of redispersed components . Excessively high activity of granular aggregate with a size of more than 10 mm during autoclaving of silicate products leads to the formation of large pores in their array with many structural defects, which also leads to increased thermal conductivity, decreased water resistance, frost resistance and strength of the obtained samples of silicate wall products (mixture 3, table .2), this composition is accepted as boundary.

A further increase in these ratios and parameters leads to a significant decrease in the physico-mechanical properties of silicate wall products, therefore, the composition of the mixture 5 is beyond the scope of the claimed compositions of silicate wall products.

With an optimal ratio of components (mixture 1, Table 1), the obtained silicate wall products have the following advantages compared to the known ones:

1) while maintaining strength indicators, thermal conductivity decreases by 1.4-1.6 times, water resistance increases by 15-20%, and frost resistance by 1.3-1.6 times;

2) the inventive granular aggregate does not require heat treatment in the manufacture, due to this reduced energy consumption when receiving silicate wall products.

When using raw silicate mixtures with boundary component ratios (mixtures 2 and 3, Table 1), the obtained silicate products practically retain water resistance and strength characteristics compared to the similar properties of the prototype.

In the process of applying a protective shell of ground lime and sodium silicofluoride to the core of the aggregate, the components of the shell interact with liquid glass, which leads to a rapid increase in the strength of the aggregate granules at ambient temperature, which allows it to be used in the preparation of silicate mixtures without additional energy-intensive temperature curing. During the autoclave treatment of the inventive silicate products, in the cores of the granular aggregate, water-soluble sodium silicates are synthesized, which, penetrating through the protective shell, provide extremely strong adhesion of the claimed granules with the silicate matrix of the product.

Composite aggregate according to the prototype, when introduced into the composition of silicate wall products during autoclaving, exhibits low activity, does not interact with the silicate matrix in the boundary contact zones in volume. When an external load is applied (compression and bending strength test), the destruction of these building products occurs along the boundaries of the contacts between this aggregate and the silicate matrix, i.e. sufficiently strong adhesion to a silicate matrix, as in the inventive granular composite aggregate, is not observed.

Obtained by the present method, silicate wall products have, in addition, improved adhesive properties with respect to masonry and plaster mortars.

Claims (4)

1. Granular composite aggregate for silicate wall products, made from a composition comprising silica-containing and lime-containing components, characterized in that it is made in the form of granules with a size of 0.5-10.0 mm, consisting of a core and a shell, where the core is obtained by granulating the mixture co-milled to a specific surface area of 150-250 m ² / kg of silica-containing component - perlite and alkali metal hydroxide at a mass ratio of 0.70-0.95: 0.05-0.30 with a binder - an aqueous solution of sodium silicate with a density of 1.2 -1.3 g / cm ³ the amount of 0.1-7.0% of the mixture, and the shell is formed on the surface of the core by rolling it with a dry pulverized mixture of together ground quicklime and sodium silicofluoride with a mass ratio of 0.85-0.95: 0.05-0.15 s subsequent hardening to a strength of at least 2.1 MPa. 2. The raw material mixture for the manufacture of silicate wall products, including aggregate according to claim 1, quicklime and quartz sand in the following ratio of components, wt.%:
specified placeholder 5.0-40.0 quicklime 10.0-12.5 quartz sand 50.0-82.5 3. A method of producing silicate wall products, including obtaining a raw mixture according to claim 2 by mixing its components, wetting the mixture to molding moisture, molding under pressure of the products and their autoclaving. 4. Silicate wall product, characterized in that it is obtained by the method according to claim 3.