RU2707832C1 - Method of producing high-density aqueous slurries based on lithium-aluminosilicate glass - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to ceramic industry and can be used in making glass-ceramic articles by water-slurry casting into porous molds. Method of producing a high-density aqueous slurry based on lithium aluminosilicate glass involves loading into a mill a starting material in form of a glass granulate or process wastes for making articles and grinding bodies at ratio of 1:(3–4), introduction in one pass of design amount of water, wet grinding and stabilization of slurry by mechanical stirring with subsequent addition of HCl or NH₄Cl, prior to loading of the initial raw material, a fraction passing through the sieve with the cell side of 1.2 mm, or 1.4 mm, or 1.6 mm is removed from it, and the acid is added in amount of 0.1 ml per 1 l of the stabilized slurry, based on calculation reducing the slurry pH value by 0.1, wherein acid is mixed with same volume of distilled water before introduction into the slurry and uniformly poured on the surface of the slurry.

EFFECT: high efficiency when preparing high-density aqueous slurries of lithium aluminosilicate glass in ball mills and low level of process rejection when making ceramic articles from said slurries.

1 cl, 1 tbl, 4 ex

Description

The invention relates to the ceramic industry and can be used in the manufacture of glass-ceramic products by water slip casting in porous forms.

A known method of producing aqueous slips from lithium aluminum silicate glass (German Patent 19622522, CL C03C 10/12, 1998). According to the first option, dry granulation of glass granulate or technological crystallized glass wastes is carried out at a ratio of glass and grinding media from Al ₂ O ₃ as 1: 2, screening of fractions of a given particle size distribution (the first fraction - particles less than 63 microns, the second fraction - particles less than 7 microns ), mixing these fractions in the required ratio, followed by introducing water into the powder, mechanically mixing the mixtures to obtain a slip.

According to the second option, obtaining a water slurry consists in manufacturing a coarse-grained powder (fraction with particles less than 63 μm) by dry grinding of the feedstock and screening, obtaining a fine fraction of the powder in the process of wet grinding of the feedstock, followed by freezing water, adding dried powder to the first fraction, followed by the introduction of water and mechanical stirring.

The disadvantages of this technical solution for the preparation of aqueous slips of glass of lithium aluminum silicate composition to obtain densely sintered glass-ceramic products include: multi-operation preparation of a slip, the complexity of screening the desired fractions, low density and high viscosity of the obtained slurries, the duration of the molding process of dusty workplaces, high porosity of the castings obtained, small porosity dimensions of the products obtained.

The closest technical solution is a method for producing high-density aqueous slurries based on lithium aluminum silicate glass (RF patent No. 2211810, class C03C 10/12, 09/10/2003), which includes loading the feedstock in the form of glass granulate or technological waste from the production of products and grinding media from Al ₂ O ₃ in the mill at a ratio of 1: (3-4), dry grinding for 30-60 minutes, introducing the calculated amount of water in one step, wet grinding and stabilization of the slip by mechanical stirring, followed by the addition of HCl or NH ₄ Cl in the amount of 1 , 0-2.0 ml per 1 liter of slip.

The disadvantages of the known technical solution include the fact that either granulate lithium aluminum silicate glass, or technological waste products, including used defective products that have passed the firing operation, are previously crushed to particle sizes of not more than 15 × 15 × 5 mm. In this case, as a result of crushing, a sufficiently large amount of a fine fraction is formed, which during the grinding process not only undergoes very poor grinding, but also takes away most of the moisture. As a result, it is necessary to increase the amount of water at the initial stage of grinding, which in turn leads to an increase in the porosity of the resulting workpieces and, as a result, an increase in shrinkage and warpage of the workpieces during beading and firing. In addition, the presence of a fine fraction in the slip leads to an increase in the time for forming blanks, an uneven set, and as a result to marriage in this operation. The situation is aggravated by the fact that the amount of fines due to various factors can vary greatly from batch to batch of crushed material, which greatly complicates the selection of optimal technological parameters in the manufacture of products and leads to an increase in the rejection of manufactured products.

Another significant drawback of the known technical solution is that the stabilization of the slip is carried out by mechanical stirring, followed by the addition of HCl or NH ₄ Cl in an amount of 1.0-2.0 ml per 1 liter of slip. Considering that the obtained slurry after grinding has a pH value from 8.4 to 10.0, and for each type of product, the final pH values are selected individually, as a rule, in a fairly narrow range from 7.4 to 7.6, the introduction of acid in these limits often leads to the production of a slip with inappropriate pH parameters, which leads to the need for repeated operation of adjusting the slip in pH to the necessary parameters, and as a result to increase the duration of the process.

The objective of the present invention is to increase productivity in the preparation of high-density aqueous slips of lithium aluminum silicate glass in ball mills and to reduce the level of technological defects in the manufacture of ceramic slips from these slips.

This object is achieved by the fact that the proposed method for producing a high-density water slurry based on lithium aluminum silicate glass, including loading into the mill the feedstock in the form of granulate glass, or technological waste products and grinding media with a ratio of 1: (3-4), introduction in one step calculated amount of water, wet grinding and stabilizing the slurry by mechanical stirring followed by addition of HCl or NH ₄ Cl, characterized in that before charging the starting raw material fraction removed therefrom, past A sieve with a cell side of 1.2 mm, or 1.4 mm, or 1.6 mm, and the acid is added in an amount of 0.1 ml per 1 liter of stabilized slip, based on the calculation of reducing the pH of the slip by 0.1, at this acid is mixed with the same volume of distilled water before being introduced into the slip and poured evenly over the surface of the slip.

The authors experimentally established that the screening of the fine fraction from the feedstock before loading it into the mill provides a slip with specified parameters in a minimum amount of time. Moreover, due to the fact that the feedstock always has a comparable fractional composition, a stable process is ensured.

It was experimentally established that the mesh through which the screening is carried out should have a cell side size of at least 1.6 mm. Otherwise, a complete exclusion of the ingress of a small fraction of the raw material during loading into the mill is not ensured.

It was also experimentally established that to reduce the pH value by 0.1, 0.1 ml of acid per 1 liter of slip is introduced. In this case, the calculated amount of acid must be mixed with the same amount of distilled water before being introduced into the slip. Exceeding the amount of water can lead to an increase in the moisture content of the slurry, and a decrease in the amount of water can lead to a non-uniform distribution of acid over the volume of the slip. In both cases, there is a chance of a slip with a deviation from the given requirements.

The implementation of the proposed technical solution is shown in the following examples.

Example 1 (prototype). In a mill with corundum lining, lithium aluminum silicate granulate was loaded with particle sizes of not more than 15 × 15 × 5 mm and grinding bodies made of Al ₂ O ₃ in a ratio of 1: 3. The loading of water into the mill in the amount of 15.0% by weight of the glass was carried out 30 minutes after the start of dry grinding. In the grinding process, to achieve the required parameters, an additional introduction of water was required, while the total amount of water was brought up to 18.5%. The grinding time was 35 hours. The obtained slurry after stabilization for 20 hours had a pH of 8.3. For a particular type of product, a pH of 7.5 was required. After the introduction of acid HCl at the rate of 1 ml per 1 liter of stabilized slip and stirring, a pH of 7.4 was obtained. To achieve the required parameters of the slip, it was necessary to add acid to it and carry out additional stabilization. The total stabilization time was 30 hours. A batch of products that subsequently underwent heat treatment was molded from the resulting slip. The total _launch K (the ratio of the number of products launched into production to the number of received good) amounted to 2.7.

Example 2. In a mill with corundum lining, lithium aluminum silicate granulate was loaded with a particle size of not more than 15 × 15 × 5 mm, from which the fine fraction passed through a sieve with a mesh having a mesh side size of 1.2 mm and the grinding bodies were previously screened from Al ₂ O ₃ in a ratio of 1: 3. A load of water in the mill in the amount of 15.0% of the weight of the glass was made 30 minutes after the start of dry grinding. During the grinding process, additional water was needed to achieve the required parameters, while the total amount of water was brought up to 17.4%. The grinding time was 29 hours. The resulting slip after stabilization for 20 hours had a pH of 8.4. To achieve a pH value of 7.5, HC1 acid was introduced into the slip from the calculation of decreasing the pH of the slip by 0.1. This was achieved by administering 0.1 ml of acid per 1 liter of slip. After stirring the slip for 2 hours, a pH of 7.5 was obtained. The total stabilization time was 22 hours. A batch of products that subsequently underwent heat treatment was molded from the resulting slip. The total _launch K (ratio of the number of products launched into production to the number of received good) was 2.2.

Examples 3 and 4 are performed analogously to example 2, with the difference that in example 3, a mesh with a mesh size of 1.4 mm was used for screening the fine fraction, and for example 4-1.6 mm.

The obtained generalized data for all four examples are presented in the table.

As follows from the table, the proposed technical solution provides high-density aqueous slips from lithium aluminum silicate glass with significantly higher performance while maintaining their parameters at the same high level. At the same time, the level of technological marriage of products obtained from these slips is significantly reduced.

Claims (1)

A method for producing a high-density aqueous slurry based on lithium aluminum silicate glass, which includes loading raw materials in the form of glass granulate or technological waste products and grinding media at a ratio of 1: (3-4), introducing a calculated amount of water in one go, wet grinding and stabilizing the slurry by mechanical stirring followed by addition of HCl or NH ₄ Cl, characterized in that before charging the starting raw material fraction removed therefrom, passed through a sieve with a 1.2 mm cell side, or 1.4 mm or 1.6 m And the acid is added in an amount of 0.1 ml per 1 liter of the slurry stabilized, based on the calculation reduction of the pH of the slurry to 0.1, wherein the acid before introduction into the slurry is mixed with the same volume of distilled water and uniformly poured slip surface.