RU2585217C1 - Crude mixture for protective coating - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction materials and can be used for protection of various surfaces. Crude mixture contains portland cement, sand with particle size 0.315 mm, water and a complex additive consisting of a silica-containing component represented by white soot BS 50, and a polycarboxylate polymer based on methacrylic acid at ratio, wt%: 93.7-94.3 and 5.7-6.3 and respectively with following ratio of components, wt%: portland cement 34.48-36.48, said sand 43.72-44.82; said additive 6.4-6.9; water 13.4-13.8.

EFFECT: technical result is high corrosion resistance relative to magnesia corrosion.

1 cl, 1 tbl

Description

 The invention relates to the field of building materials and can be used to protect various surfaces.

Known raw material mixture used as a protective coating containing Portland cement clinker 62-68%, sodium nitrate 3-10%, potassium chromate 2-5%, the rest is water (RU No. 2017704, С04В 41/62, 1994).

The disadvantage of this technical solution is the lack of corrosion resistance to magnesia corrosion.

Known raw mix consisting of the following components, wt. %: cement 36.0-40.0, sand 39.0-49.0, sodium nitrate 0.9-1.8, sodium carbonate 2.0-3.2, sodium sulfate 2.5-3.6, calcium chloride 0.05-0.15, calcium carbide 0.75-1.15, calcium hydroxide 0.8-1.0, the rest is water (RU No. 2072335, C04B 28/00, 1997).

The disadvantage of this technical solution is the lack of corrosion resistance to magnesia corrosion.

Closest to the technical nature of the claimed raw material mixture for the protective coating selected for the prototype is a raw material mixture consisting of the following components, wt. %: Portland cement - 30.3-32.3; aggregate represented by sand with a maximum fraction size of 0.63 mm, in an amount of 40.4-40.9; finely ground dolomitic limestone with a specific particle surface of 200 m ² / kg in an amount of 8.1-8.6; complex additive - 3.2-3.7 and water - 16.0-16.5. The complex additive consists of the following components, wt. %: silica fume with a specific particle surface of 2000 m ² / kg - 47-49; alumina cement - 24.5-25.0; gypsum CaSO ₄ · 2H ₂ O - 9.8-10.2; plasticizer C-3 - 3.7-4.0; silicic acid sol H ₄ SiO ₄ with a density of 1.014 g / cm ³ and a pH of 3.5-3.0-3.4; bentonite clay with a specific particle surface of 500 m ² / kg - 10.0-10.4 (RU No. 2396235, С04В 41/63, 2010).

The disadvantage of this technical solution is the lack of corrosion resistance to magnesia corrosion.

The problem to which the invention is directed, is to create a raw material mixture for a protective coating having increased corrosion resistance to magnesia corrosion.

The task is achieved in that the raw material mixture for the protective coating contains Portland cement, sand fraction 0.315 mm, water and a complex additive consisting of a silica-containing component represented by white carbon black BS 50 and a polycarboxylate polymer based on methacrylic acid, in the following ratio, wt. %:

White soot BS 50 93.7-94.3 Polycarboxylate polymer 5.7-6.3

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

Portland cement 34.48-36.48 Indicated sand 43.72-44.82 Specified Additive 6.4-6.9 Water 13.4-13.8

The use of a complex additive consisting of a silica-containing component represented by white carbon and a polycarboxylate polymer based on methacrylic acid, on the one hand, increases the hydration activity of the raw material mixture used as a protective coating, thereby increasing the number of hydrated phases in the protective coating used, with on the other hand, the amount of lime hydrolysis formed, which enters the synthesis reaction with the silica-containing component represented by carbon black, which has increased reactivity in the presence of a carboxylate-based hyperplasticizer, additionally forming hydrosilicates, including low-base ones, which contributes to the densification of the protective coating structure, as well as the binding of calcium hydroxide (Ca (OH) ₂ ) to sparingly soluble compounds, thereby increasing corrosion resistance of the protective coating relative to magnesia corrosion.

At the filing date, in the opinion of the authors and the applicant, the claimed raw mix for the protective coating is not known and this technical solution has a world novelty.

The claimed combination of essential features exhibits a new property in the presence of the indicated complex additive consisting of a silica-containing component represented by white carbon and a polycarboxylate polymer based on methacrylic acid, which provides an extra-cumulative effect of increasing the hydration activity of the raw material mixture for a protective coating and a parallel synthesis reaction between the hydrolytic lime and the silica-containing component, resulting in an increase in ion resistance of the protective coating of corrosion relative to magnesia.

The mixture, including Portland cement, sand and the proposed additive, provided a protective coating characterized by increased by 19% corrosion resistance to magnesia corrosion compared to the prototype.

According to the applicant and the authors, it is precisely another property of the set of essential features that is not equal to the known properties of the distinguishing features that allows us to recognize this set in comparison with the new ones known in science and technology, and the claimed invention corresponds to the eligibility criterion of “inventive step”.

The claimed invention is industrially applicable and can be used for the manufacture of building mixtures used as a protective coating for the surface of carnallite rock (KCl · MgCl ₂ · 6H ₂ O).

Concrete example

1. Preparation of the proposed additives:

1.1. A silica-containing component is represented, represented by white soot BS 50 according to GOST 18307-78;

1.2. Methacrylic acid based polycarboxylate polymer is dosed;

1.3. The metered-dose components according to paragraph 1.1 and paragraph 1.2 are mixed until a homogeneous dispersed system is obtained.

2. Preparation of dry building mix:

2.1. Portland cement ПЦ500 Д0 is dosed;

2.2. Dose sand fraction 0.315 mm;

2.3. Dose the additive prepared according to claim 1;

2.4. The metered components are mixed in accordance with clause 2.1, clause 2.2, and clause 2.3 until a homogeneous fine powder is obtained, which is a dry building mixture for a protective coating.

3. Preparation of the raw material mixture for a protective coating:

3.1. Dose dry building mixture prepared according to p. 2.4;

3.2. Dose water;

3.3. Using an electric drill, the components are metered in according to clauses 3.1 and 3.2 until a homogeneous, lump-free moving mass is obtained, which is used as intended as a protective coating and from which 7.07 × 7.07 × cubed cubes are prepared 7.07 cm, the hardening of which was carried out under normal conditions and achieving project age of 28 days, the samples were placed in a bath of a 5% solution of magnesium chloride (MgCl _2), where they are stored for 360 days and parallel samples were stored in normal conditions, . According to the test results, according to the formula:

K _box = R _SJ (MgCl ₂₎ / K _{compression channel} (norm.hr.)

wherein R _SJ (MgCl _2), - compressive strength specimens tverdevshih a 5% solution of magnesium chloride;

R _SJ (norm.hr.) - compressive strength specimens tverdevshih under normal conditions (temperature 25 ± 2 ° C and humidity greater than 95%).

The coefficient of corrosion resistance of the proposed raw material mixture for a protective coating was determined in comparison with the prototype. The results are presented in the table.

Claims (1)

The raw material mixture for a protective coating, consisting of Portland cement, sand fraction 0.315 mm, a complex additive and water, characterized in that the complex additive consists of a silica-containing component represented by white carbon black BS 50 and a polycarboxylate polymer based on methacrylic acid in the following ratio of components, wt .%:
White soot BS 50 93.7-94.3 Polycarboxylate polymer 5.7-6.3
in the following ratio of components of the raw mix, wt.%:
Portland cement 34.48-36.48 Indicated sand 43.72-44.82 Specified Additive 6.4-6.9 Water 13.4-13.8