RU2607221C1 - White pigment - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to chemical industry and can be used for making pigments for varnishes and paints. White-color pigment contains shell and core. Shell is made of titanium dioxide. Core is made of mixture of kaolin and aluminium oxide with total weight content of aluminium silicates and aluminium oxide of not less than 97 %. Weight ratio of aluminium silicates to aluminium oxide ranges from 2 to 4. Weight ratio of shell material to core material varies from 0.66 to 3 at core material ratio from 2 to 5 mcm and shell material from 0.2 to 0.5 mcm.

EFFECT: invention allows to improve quality of pigment due to creation on surface of core dense shell of titanium dioxide, resistant to destruction in operating conditions at acidic precipitation, storage and transportation.

1 cl, 11 ex

Description

The invention relates to the chemical industry and may find application in the manufacture of pigments for varnishes and paints.

Known pigment with a core of titanium dioxide coated with a metal oxide, hydroxide or oxyhydroxide (RU 2162443 C1 IPC C01G 23/053, C09D 5/32, C09C 1/36, A61K 7/42).

A disadvantage of the known pigment is that due to the coating of particles of titanium dioxide with a layer of metal oxides and hydroxides, the chemical stability of the pigment increases, but reduces the degree of whiteness and hiding power in comparison with pure titanium dioxide.

Known pigment consisting of mica, which is the core coated with a layer of titanium dioxide (RU 2198191 IPC С09С 1/00, С09С 1/36).

A disadvantage of the known pigment is that it does not provide a strong relationship between the mica core and titanium dioxide, which leads to a low content of titanium dioxide on the surface of the core and, as a result, the appearance of a pearlescent shade.

Known pigment for paints and enamels containing a core of synthetic calcium silicates, coated with pigment titanium dioxide (SU 1837610 A1 IPC C09C 1/02, C09C 1/36).

A disadvantage of the known technical solution is that the shell material has poor adhesion to the core material due to the low surface adsorption activity of the core material. This does not allow for a strong relationship between the core and the shell and determines the content of pigment titanium oxide in the shell of the known pigment is not more than 20 wt. parts relative to the core material. The low surface adsorption activity of the core material prevents the formation of a continuous shell of titanium dioxide on its surface, which negatively affects the whiteness and hiding power. The low surface adsorption activity of the core material also leads to peeling of the shell and its destruction during mechanical stress during storage and transportation. When interacting with acid-containing atmospheric precipitation, calcium silicate is destroyed and the shell of titanium dioxide exfoliates from the core, which further affects the quality of the coating in which this pigment is used.

         The problem to which the invention is directed, is to improve the quality of the pigment due to the creation on the surface of the core of a dense shell of titanium dioxide, resistant to destruction in operating conditions with acid precipitation, storage and transportation.

To solve this problem, in contrast to the known pigment containing a core of filler and a shell of titanium dioxide, in the proposed pigment, the core is made of a mixture of kaolin and aluminum oxide with a total mass content of aluminosilicates and alumina of at least 97%, and the mass ratio of aluminosilicates to oxide aluminum is from 2 to 4, and the mass ratio of the shell material to the core material is from 0.66 to 3 with a fractional composition of the core material from 2 to 5 μm and the shell material from 0.2 to 0.5 μm.

When the total mass content of aluminum and aluminum oxide silicates in the core material is less than 97%, the adhesion of the core material to the shell material and the weather resistance of the pigment are significantly impaired.

When the mass ratio of aluminosilicates to alumina is less than 2 due to the low optical density of alumina, the total optical contribution of the core to the achievement of the required level of whiteness and hiding power of the pigment decreases.

With a mass ratio of the content of aluminosilicates to alumina of more than 4, the cohesive strength of the core, the adsorption and adhesion bonds of titanium dioxide in the core-shell system are not ensured. The deficiency of aluminum oxide as a grinding body, necessary for joint mechanical processing of pigment components, does not fully ensure mutual dispersion of particles of various chemical nature, hardness and geometric shape. In this case, an equilibrium stable state in the pigment structure is not achieved due to adsorption, electrostatic and adhesive forces both inside the core and at the core-shell interface.

When the mass ratio of the shell material to the core material is less than 0.66, the “whiteness” and “hiding power” deteriorate due to the insufficient content of titanium dioxide in the pigment shell.

The mass ratio of the shell material to the material of the core 3 is the maximum limit.

When the fractional composition of the core material is less than 2 μm, the adhesion of the shell material to the core material deteriorates, since the core itself loses its solidity and isotropy.

When the fractional composition of the core material is more than 5 μm, the structural monolithicity of the core worsens due to the formation of air microvoids in the core, the presence on the surface of the core of areas with different densities, integral hardness and surface activity.

When the fractional composition of titanium dioxide is more than 0.5 μm, the adhesion of the shell material to the core material is deteriorated due to steric factors that impede the placement of titanium dioxide microparticles in a monolithic and uniform layer over the entire surface of the core.

When the fractional composition of titanium dioxide is less than 0.2 μm, spontaneous aggregation of microparticles of titanium dioxide with high surface activity occurs, which leads to the spontaneous appearance of labile structural aggregates on the surface of the core and the disruption of mobile equilibrium in the core-shell system.

Compliance with the claimed quantitative and dimensional ratios between the particles of substances that make up the white pigment, allows you to provide both the desired set of properties and the stability of the pigment.

The proposed pigment is obtained by joint machining in a ball mill of the core material and the shell material. The core material is preliminarily subjected to thermomechanical processing to obtain a white product in which the claimed dimensional ranges of constituent particles are achieved. As a result, a mobile equilibrium is achieved between the nuclei and shells of the white pigment particles, shifted towards stable structures due to a combination of adsorption and steric factors. After joint machining, pigment grains from 6 to 10 microns in size are obtained.

Alumina in the core provides an increase in the scattering ability of the pigment due to the distribution of dispersed particles of titanium dioxide obtained in the process of joint machining. This improves the uniformity and stable equilibrium homogeneity in the composition of coatings, which helps to maintain the stability of the main optical properties.

As the shell, titanium dioxide of both anatase and rutile forms can be used.

The following are examples of white pigment.

Example 1

1 kg of pigment contains 0.75 kg of titanium dioxide brand Sum Titan R-206 with a particle size of 0.2-0.5 μm rutile modification, forming a shell of pigment grains, 0.08 kg of aluminum oxide with a particle size of 2-5 μm and 0.17 kg Super kaolin with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 93 cu, a hiding power of not more than 24 g / m ² , pH 7.3. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 2

1 kg of pigment contains 0.75 kg of titanium dioxide brand Sum Titan R-206 with a particle size of 0.2-0.5 μm rutile modification, forming a shell of pigment grains, 0.05 kg of aluminum oxide with a particle size of 2-5 μm and 0.2 kg Super kaolin with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 93 cu, a hiding power of not more than 24 g / m ² , pH 7.2. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 3

1 kg of pigment contains 0.40 kg of titanium dioxide brand CRIMEA TIOX-230 with a particle size of 0.2-0.50 microns of rutile modification, forming a shell of pigment grains, 0.12 kg of aluminum oxide with a particle size of 2-5 microns and 0.48 kg of kaolin Super brand with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 93 cu, a hiding power of not more than 25 g / m ² , pH 7.9. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 4

1 kg of pigment contains 0.40 kg of titanium dioxide brand CRIMEA TIOX-230 with a particle size of 0.2-0.5 μm rutile modification, forming a shell of pigment grains, 0.2 kg of aluminum oxide with a particle size of 2-5 μm and 0.4 kg of kaolin Super brand with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 93 cu, a hiding power of not more than 25 g / m ² , pH 7.9. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 5

1 kg of pigment contains 0.5 kg of titanium dioxide brand CRIMEA TIOX-230 with a particle size of 0.2-0.5 μm rutile modification, forming a shell of pigment grains, 0.15 kg of aluminum oxide with a particle size of 2-5 μm, 0.35 kg of kaolin brand "Standard" with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 91 cu, a hiding power of no more than 24 g / m ² , pH 7.5. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 6

1 kg of pigment contains 0.6 kg of titanium dioxide brand Sum Titan R-206 with a particle size of 0.2-0.5 μm rutile modification, forming a shell of pigment grains, 0.1 kg of aluminum oxide with a particle size of 2-5 μm and 0.3 kg kaolin of the Standard brand with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 92 cu, a hiding power of not more than 24 g / m ² , pH 7.6. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 7

1 kg of pigment contains 0.55 kg of titanium dioxide brand Sum Titan R-211 with a particle size of 0.2-0.5 microns, forming a shell of pigment grains, 0.1 kg of aluminum oxide with a particle size of 2-5 microns and 0.35 kg of kaolin brand “Super” particle size of 2-5 microns, forming the core of the pigment grains with a total mass content of aluminosilicates and alumina of 98%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 91 cu, a hiding power of no more than 24 g / m ² , pH 7.2. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 8

1 kg of pigment contains 0.4 kg of titanium dioxide brand Sum Titan R-205 with a particle size of 0.2-0.5 microns, forming a shell of pigment grains, 0.16 kg of aluminum oxide with a particle size of 2-5 microns and 0.45 kg of kaolin brand “Super” particle size of 2-5 microns, forming the core of the pigment grains with a total mass content of aluminosilicates and alumina of 98%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 90 cu, a hiding power of not more than 25 g / m ² , pH 7.8. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 9

1 kg of pigment contains 0.6 kg of titanium dioxide brand Sum Titan R-205 with a particle size of 0.2-0.5 microns, forming a shell of pigment grains, 0.1 kg of aluminum oxide with a particle size of 2-5 microns and 0.1 kg of kaolin brand Super "particle size of 2-5 microns and 0.2 kg of kaolin" Standard "with a particle size of 2-5 microns, forming a core of pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 92 cu, a hiding power of not more than 24 g / m ² , pH 8.0. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 10

1 kg of pigment contains 0.5 kg of titanium dioxide brand Sum Titan R-202 with a particle size of 0.2-0.5 microns, forming a shell of pigment grains, 0.1 kg of aluminum oxide with a particle size of 2-5 microns and 0.4 kg of kaolin brand Super "particle size of 2-5 microns, forming the core of the pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 92 cu, a hiding power of not more than 24 g / m ² , pH 8.2. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

Example 11

1 kg of pigment contains 0.7 kg of titanium dioxide brand Sum Titan R-202 with a particle size of 0.2-0.5 μm, forming a shell of pigment grains, 0.1 kg of aluminum oxide with a particle size of 2-5 μm and 0.2 kg of kaolin brand Super "particle size of 2-5 microns, forming the core of the pigment grains with a total mass content of aluminosilicates and alumina of 97%. The components have previously undergone thermomechanical processing. The pigment has a white color with a whiteness of at least 93 cu, a hiding power of not more than 24 g / m ² , pH 7.4. The pigment is resistant to destruction under operating conditions with acid precipitation, does not change its properties during storage and transportation.

In the composition of the inventive white pigment, the minimum content of titanium dioxide is 40 mass. hours per 100 mass. including pigment. This is achieved through a combination of titanium dioxide, aluminosilicates and aluminum dioxide. Moreover, the components have a certain structure, degree of dispersion, as well as the microstructure of individual particles and their aggregates. This determines the surface activity of particles in a state of stable equilibrium, as well as their ability to disperse in the process of joint mechanical processing. The dispersion process is facilitated by the weakly basic nature of the used amphoteric components. The dispersion quality is also determined by the ratio of the hardness values of the leaving components.

Claims (1)

A white pigment containing a core of filler and a shell of titanium dioxide, characterized in that the core is made of a mixture of kaolin and aluminum oxide with a total mass content of aluminosilicates and alumina of at least 97%, and the mass ratio of aluminosilicates to alumina is from 2 to 4, and the mass ratio of the shell material to the core material is from 0.66 to 3 with a fractional composition of the core material from 2 to 5 μm and the shell material from 0.2 to 0.5 μm.