RU2664143C2 - Method for applying protective film on surface of phosphor dots - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: invention relates to the chemical industry, security printing, agriculture, electronics and lighting technology and can be used to manufacture polymer films in order to create artificial illumination of greenhouses and orangeries, LEDs, IR visualizers, night vision devices, dosimeters, displays for displaying alphanumeric information. Surface of the phosphor dots is treated with a polysilicic acid sol, synthesized by hydrolysis in an alcoholic solution of tetraethoxysilane in an amount of 0.1–0.3 % by weight, in the presence of a catalyst, which is a solution of the nitrate salt of the elements of the second group in an amount of 18–25 wt%, in the process of applying a protective coating onto the surface of the phosphor dots. Then, the phosphor crystals are encapsulated in a film formed on their surface from a solution of a dispersion of polyacrylic acid added in an amount of 1–2 % by weight of the processed phosphor mass. After that, the treated phosphor is dried.EFFECT: increased service life and brightness of luminescent phosphors, their resistance to environmental factors.1 cl, 1 tbl, 8 ex

Description

The invention relates to the chemical industry, in particular, to a method for protecting the surface of phosphors from environmental factors and can be used to protect the surface of phosphors from environmental factors in order to increase the lighting and operational parameters of these phosphors.

As you know, the chemical and physical properties of phosphors directly depend on the qualitative composition of these phosphors (Medvedeva SA Chemistry and physics of compounds A ^II B ^VI (translated from English). - M .: Mir. - 1970. - 624 p.). The substances that form the phosphor crystal (matrix, activators, components of mineralizers) can have different reaction stability with respect to foreign chemicals that come into direct contact with crystallophosphorus during the industrial use of the phosphor. The destruction of a luminescent crystal results in a gradual loss of luminescent properties by the substance, which is manifested by a decrease in the initial brightness level, a shift of the bands in the absorption and emission spectra, which changes the hue and color of the phosphor luminescence, rendering it unusable. Such phosphors include structures based on REE halides and oxyhalides, aluminate compounds, and crystalline phosphors based on schZM sulfides (Morrison S. Chemical physics of a solid surface. M .: Mir. - 1980. - 489 p.). The luminescent characteristics of these substances are unique and, given their wide application in various industries and science, the issue of surface protection of low-stability phosphors is of particular relevance.

The main problem in developing a method for applying a surface coating is the search for an inert compound capable of forming strong bonds with the surface atoms of phosphor crystals, while creating chain structures leading to the encapsulation of the particle so that the surface coating is sufficiently transparent (Guo Chongfeng, Chu Benli, Xu Gian, Su Qiang. Surface treatment of alkaline sulfides based phosphor. // Chem. Res. Chinese u. - 2004. - Vol. 20. - No. 3. - P. 253-257).

In US patent No. 4690832, 1987, CL. С09K 11/475 describes a method for modifying the surface of phosphors based on oxyhalides and oxychalcogenides of REEs by treating them with inorganic silicon-containing compounds from aqueous solutions: solutions of potassium silicate and Group II metal compounds, followed by calcining the treated product in air at 400-800 ° C for 0, 5-3 hours.

A known method of processing phosphor particles with the formation of a film of silicon dioxide by pyrolytic decomposition of silane at a temperature of 500 ° C (U.S. Patent No. 4855189).

The disadvantage of these methods is the use of high temperatures at which a decline in the lighting characteristics of the phosphor is possible.

A technical solution is known (Application of Germany No. 2747509, 1979, class C09K 11/02.), In which a vitreous coating is applied to the surface of a phosphor based on zinc sulfides and zinc-cadmium sulfides. Later, this method was finalized (RF Patent No. 2401293, 2008, class C09K 11/77) and the following method for modifying anti-Stokes phosphors based on REE oxychlorides was proposed. The essence of the method is to process the phosphor with a low-melting glass of the composition SiO ₂ 10.5 wt. %, In ₂ About ₃ 14.6 wt. %, Al ₂ O ₃ 1.1 wt. %, PbO - the rest.

The disadvantage of this method is the presence of lead oxide in the glassy coating, which leads to a change in the composition of the matrix and quenches the luminescence.

The known method (U.S. Patent No. 3264133) for surface treatment of phosphor particles with the formation of a titanium dioxide film by treating phosphor particles with an alcohol solution of a halogen-containing compound, in particular titanium chloride, followed by washing and annealing.

The disadvantage of this method is the use of titanium tetrachloride, which is a strongly fuming liquid in the air with a pungent odor and is a toxic substance.

A well-known industrial method of processing phosphor particles with a solution of potassium silicate (B. M. Gugel, "Phosphors for the electric vacuum industry", 1967, M., "Energy", S. 76-87; Kazankin ON, Markovsky L.Ya., Mironov I.A. et al. "Inorganic phosphors", 1975, L. "Chemistry", pp. 108-111), which gives good results on the flowability of the phosphor powder, but, as a result of the hydrolysis of the matrix and activator, due to the influence of strongly alkaline environment, there is a decrease in the brightness and life of the phosphor.

The author's certificate (AS USSR No. 415286, BI No. 6, 1974, p. 70) describes a method of applying a zinc silicate film by treating the phosphor powder with appropriate solutions of salts of mineral acids.

However, this method does not provide continuous encapsulation of phosphor particles and contributes to the destruction of luminescent compounds (phosphors based on alkaline earth metal chalcogenides) that are unstable to aqueous media during the process of applying a protective film.

A known method (US Patent No. 5087523) for processing phosphor particles with the formation of a double film of silicon dioxide and aluminum oxide by chemical vapor deposition. The disadvantage of this method is the high cost, the inability to process large batches of phosphor and the complexity of the design of the reactor for coating.

In the application of the Russian Federation No. 2013111302/05, 2013, С09K 11/80, a method is proposed for modifying the surface of silicate phosphors with a fluoride coating, including a fluorinated inorganic agent, a fluorinated organic agent, or a combination thereof. Also proposed is a scheme for applying a double coating consisting of fluoride and oxides MgO, Al ₂ O ₃ , Y ₂ O ₃ , La ₂ O ₃ , Gd ₂ O ₃ , Lu ₂ O ₃ and SiO ₂ by deposition on the crystal surface of these compounds from liquid phase.

US Pat. No. 6,359,048 describes a non-aqueous alkyd-based system containing a phosphor.

The disadvantage of this system is the need to use a base - an alkyd resin and a diluent emitting organic vapors - combustible and usually have a strong odor. In addition, cleaning paint equipment also requires the use of a solvent with the same hazardous properties.

RF patent No. 2236434 relates to a multistage process for producing a phosphor, including at the last stage ultrasonic treatment of phosphor particles in water-silicone ash at 25 kHz to cover them with a thin silicate film that protects the particles from water. The method includes the step of manually sorting the phosphor particles to remove non-luminous by-products and phosphors with different radiation wavelengths. The method is unsuitable for industrial use.

Japanese patent No. 2929162 proposes a method for improving the properties of a phosphor, which consists in the fact that on the surface of phosphors consisting of metal oxides (calcium, aluminum, strontium, barium, cerium) with the addition of activators from rare earth elements, a water-insoluble or hardly soluble film in water is obtained, formed as a result of exposure to an aqueous medium of an acid or any compound having the properties of an acid to a metal oxide forming a phosphor.

The method consists in placing the phosphor in an aqueous solution containing an acid or at least one compound having an acidic effect. The processing of the phosphor can also be carried out by spraying on its surface an aqueous solution that contains acid or at least one compound having an acidic effect. A third embodiment of the method is that the phosphor is placed in a gaseous medium containing, in a high concentration, water vapor of acid or water vapor of at least one compound having an acidic effect.

Japanese application No. 207292282 A proposes a modified phosphor containing metal oxide with the addition of a rare earth element treated with an acid, preferably a phosphoric or acid-forming substance.

The luminescent pigment is modified by immersion in a 0.5-4% acid solution for 10-60 minutes at 50 ° C.

However, in the description of US patent No. 6264855 it is said that the phosphors obtained by the above methods lose their resistance to water during prolonged contact with it at a temperature of 60 ° C, although their use does not cause special problems at ordinary temperature

At the same time, our experimental studies of the effects of various acids on luminescent compositions showed that a number of acids (H ₃ BO ₃ , HCl, HNO ₃ ) recommended in US Pat. No. 6,264,855 do not protect against hydrolysis. In addition, HCl and HNO ₃ , both diluted and concentrated, easily react with all the phosphors we used to form the corresponding salts soluble in the reaction medium, which leads to their destruction.

A known method of processing the surface of the phosphor particles with the formation of a continuous film of silicon dioxide on the surface

each phosphor particle by treating the phosphor with a solution containing a complex compound of silicic acid with an organic quaternary ammonium base (U.S. Patent No. 4,287,227). The disadvantage of this method is the use of organic alkalis such as choline, which require a long washing process. Compounds of this type at the drying temperature of the encapsulated phosphor do not decompose completely and during operation are capable of poisoning the phosphor, impairing its lighting characteristics.

The authors of the article (Jau-Ho Jean, Szu-Ming Yang; Y ₂ O ₃ : Eu Red Phosphor Powders Coated with Silica // Joumal American Ceramic Society, 2000, v. 83, No. 8), proposed a method for processing phosphor particles when dispersed in ethanol with tetraethoxysilane (TEOS) and water. To accelerate the catalysis of the sol-gel reaction, hydrochloric acid is used.

The disadvantages of the method include the use of hydrochloric acid, which destroys the phosphor matrix, it is also known that chlorine ion can cause phosphor poisoning and thereby reduce its brightness characteristics.

In the patent SU 904476 (CL H01L 21/225, 02.15.1985) a method for producing film-forming solutions based on tetraethoxysilane having a shorter ripening time and longer service life is described. The method includes dissolving in a mixture of an organic solvent and water a catalyst and compounds of alloying elements and hydrolysis of tetraethoxysilane. An organic solvent and water in a ratio of 1: 4 to 4: 1 dissolve the catalyst, mix with tetraethoxysilane and carry out its hydrolysis, while the ratio of the total volume of organic solvent and water to the volume of tetraethoxysilane should be from 1: 3 to 2: 1, then in the remaining part of the organic solvent and water dissolve the compounds of alloying elements and the resulting solution is mixed with a solution of hydrolyzed tetraethoxysilane. As a catalyst for the preparation of solutions according to the proposed method, it is proposed to use nitric, hydrochloric or phosphoric acid.

These acids, both diluted and concentrated, easily react with all the phosphors we used to form the corresponding salts soluble in the reaction medium, which leads to their destruction.

As the closest analogue to the claimed invention, which has a combination of features that are closest to the essential features of the claimed invention, the patent for the invention of the Russian Federation No. 2256254 C1 (H01J 29/20, C09K 11/02, 12/29/2003, in) which proposes a method of applying a protective film to the surface of the phosphor particles, comprising treating the surface of the phosphor particles with an inorganic compound and drying the treated phosphor. The treatment is carried out with a polysilicic acid sol, synthesized by hydrolysis of tetraethoxysilane in an aqueous solution with an ammonia concentration of 0.6-0.8 wt. %, and the treatment is carried out in two stages: first, they are treated with sol with a concentration of silicon oxide of 0.5 mass. %, and then sol with a concentration of silicon oxide of 4 mass. %, when drying the phosphor, ammonia is removed.

The method of this patent consists of the following steps:

1. Obtaining polysilicic acid sol (PAC) with a silica content of 11 wt. %

0.6-0.8 mass. % aqueous solution of ammonia and TEOS in a ratio of 1: 1.5 is loaded into a container and stirred for 4-5 hours at a temperature of at least 25 ° C. It was found that when the concentration of ammonia is less than 0.6 mass. % hydrolysis is not complete and unstable exfoliating emulsions of TEOS are formed, but at ammonia concentrations above 0.8 mass. % sol stability drops sharply due to the aging (enlargement) of the PAC.

2. Preparation of diluted sol PAC with a silica content of 0.5 mass. %

3. Preparation of diluted sol PAC with a silica content of 4 wt. %

4. Disaggregation of the phosphor.

The phosphor is loaded into a glass and filled with distilled water, and stirred for 10 minutes. After the specified time, the suspension is squeezed. The moisture content of the precipitate is 12%.

5. Processing of the phosphor 0.5 mass. % sol in a ball mill without balls for 10 hours, sol: phosphor ratio 1: 1.

6. Spin, step drying at temperatures: 50 ° C - 5 hours, 80 ° C - 5 hours, 180 ° C - to the state of dusting.

7. The secondary processing of the phosphor 4 mass. % sol is similar to paragraph 5.

8. Spin, drying similar to paragraph 6.

The methods for applying a protective film to the surface of phosphor particles using film-forming solutions, as claimed in the closest analogue, are illustrated by specific examples.

100 g of electroluminophore green glow (ZnS / Cu, Al) is loaded into a glass and pour 0.5 l of distilled water and stirred for 10 minutes. After the specified time, the suspension is squeezed. The moisture content of the precipitate is 12%. Pressed phosphor is loaded into a ball mill without balls and pour 100 g of 0.5 mass. % sol PAC obtained by the above method, mixing lasts 10 hours. The phosphor from the suspension is separated on a filter, transferred to a quartz cuvette and dried in an oven at temperatures: 50 ° C for 5 hours, 80 ° C for 5 hours, 180 ° C to a dusting state. The dried phosphor is loaded into a ball mill without balls and pour 100 g of 4 mass. % sol PAC, stirring lasts 10 hours.

The phosphor from the suspension is separated on a filter, transferred to a quartz cuvette and dried in an oven at temperatures: 50 ° - 5 hours, 80 ° - 5 hours, 180 ° - to the state of dusting. In this case, ammonia is removed.

100 g of photoluminophore Y ₃ Al ₅ O ₁₂ : Ce for white LEDs are loaded into a glass and then the technological process is carried out analogously to example 1.

100 g of the cathodoluminophore green glow (Zn _0.97 CdS _0.03 : Cu, Al) or blue (ZnS: Ag) is loaded into a glass and then carry out the process as in example 1.

The reasons that impede the obtaining of a technical result, which is ensured by the claimed invention, when using the closest analogue, are as follows: carrying out a process in an aqueous medium using ammonia, which helps to accelerate the hydrolysis of the base compound of unstable phosphors, multi-stage, labor-intensive and the duration of the process of applying a protective film to the surface of phosphor particles .

The signs of the closest analogue, which coincides with the essential features of the claimed invention, are as follows: a method of applying a protective film to the surface of phosphor particles, comprising treating the surface of the phosphor particles with polysilicic acid sol,

synthesized by hydrolysis of tetraethoxysilane and drying the treated phosphor.

In contrast to the closest analogue, the polysilicic acid sol is synthesized in an alcohol solution of tetraethoxysilane in an amount of 0.1-0.3 mass. %, in the presence of a catalyst, a solution of the nitric acid salt of the elements of the second group, in the amount of 18-25 mass. %, in the process of applying a protective coating to the surface of the phosphor particles, followed by encapsulation of the phosphor crystals with a film formed on the surface of the crystals from a solution of a dispersion of polyacrylic acid, added in an amount of 1-2 mass. % of the processed mass of the phosphor

The problem to which the claimed invention is directed is to create a method of applying a protective film to the surface of phosphor particles, which allows to increase the stability of these phosphors to environmental factors and their service life, simplify the implementation of this method, reduce the time of the process of applying a protective film on the surface of the phosphor particles, protect the phosphors from environmental factors, eliminate the unpleasant odor generated by the contact of hydrolytically unstable phosphors with water, as a result, expand the boundaries of the use of phosphors based on hydrolytically unstable compounds, reduce the complexity, improve the safety of the process of applying a protective film to the surface of the phosphor particles, reduce the cost of this process.

The technical result that can be achieved using the proposed technical solution is to increase the brightness of the phosphors when applying a protective film to the surface of the particles of these phosphors according to the claimed method, to increase the stability of these phosphors to environmental factors, to increase their service life, to eliminate unpleasant odor formed during the contact of hydrolytically unstable phosphors with water, which allows to expand the possibilities of using phosphors based on low compounds that are resistant to environmental factors, reducing the complexity of the process, reducing the duration of the process by eliminating intermediate operations associated with the preliminary preparation of working solutions, prolonged double mixing and double drying of the phosphor, improving working conditions and safety when applying a protective film to the surface of the phosphor particles according to the claimed method by replacing a hazardous reagent catalyst

- ammonia, as well as reducing costs associated with reducing the operating time of electrical units (mixers and ovens) in the process of applying a protective film to the surface of the particles of phosphors by the present method. In addition, the protective film on the surface of the phosphor particles deposited by the proposed method is uniform and holistic.

The technical result is achieved by the fact that the proposed method of applying a protective film to the surface of the phosphor particles, including treating the surface of the phosphor particles with a polysilicic acid sol synthesized by hydrolysis of tetraethoxysilane, and drying the treated phosphor, wherein the polysilicic acid sol is synthesized in an alcohol solution of tetraethoxysilane in an amount of 0.1-0 , 3 mass. %, in the presence of a catalyst, a solution of the nitric acid salt of the elements of the second group, in the amount of 18-25 mass. %, in the process of applying a protective coating to the surface of the phosphor particles, followed by encapsulation of the phosphor crystals with a film formed on the surface of the crystals from a solution of a dispersion of polyacrylic acid, added in an amount of 1-2 mass. % of the processed mass of the phosphor

The essential features of the claimed invention are as follows.

A method for applying a protective film to the surface of phosphor particles is proposed, including treating the surface of the phosphor particles with a polysilicic acid sol synthesized by hydrolysis of tetraethoxysilane and drying the treated phosphor. The polysilicic acid sol is synthesized in an alcohol solution of tetraethoxysilane in an amount of 0.1-0.3 mass. %, in the presence of a catalyst, a solution of the nitric acid salt of the elements of the second group, in the amount of 18-25 mass. %, in the process of applying a protective coating to the surface of the phosphor particles, followed by encapsulation of the phosphor crystals with a film formed on the surface of the crystals from a solution of a dispersion of polyacrylic acid, added in an amount of 1-2 mass. % of the processed mass of the phosphor.

The use of an alcoholic solution of a polysilicic acid sol, synthesized in an alcoholic solution of tetraethoxysilane in an amount of 0.1-0.3 mass. %, in the presence of a catalyst, a solution of the nitric acid salt of the elements of the second group, in the amount of 18-25 mass. %, with the exclusion of ammonia, allows the encapsulation of phosphors, which are not very stable to the aqueous medium, for example, sulfide / selenide compounds

alkaline earth metals and contributes to the safety of the process.

The polysilicic acid sol is synthesized by hydrolysis of tetraethoxysilane in the presence of a catalyst, a solution of the nitric acid salt of the elements of the second group, in the process of applying a protective film, which reduces the duration of the process and removes the limitation on the service life of the working solution, polysilicic acid sol, which, as shown in the SU patent 904476, has a limited service life, which affects the uniformity and integrity of the surface coating applied from the "aged" solution.

A solution of polyacrylic dispersion is prepared from commercial raw materials used for various industries. 1 volume of commercial raw materials is diluted in 10 volumes of alcohol or water and stirred for 5-10 minutes on a magnetic stirrer. The surface coating process consists of the following steps:

A volume of alcohol is poured into the chemical container, a portion of the phosphor is added, and the suspension is stirred on a magnetic stirrer for 5 minutes;

To the suspension, pour a commercial solution of tetraethoxysilane in an amount corresponding to 0.1-0.3 mass. % of a portion of the phosphor, and mix the suspension on a magnetic stirrer for 5 min;

To the resulting suspension add a catalyst - a dilute solution (20-30 g / l) of nitric acid salt of the elements of the second group, in a volume amount corresponding to 18-20 mass. % of the added tetraethoxysilane and mix the suspension on a magnetic stirrer for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles;

Then, a diluted solution of a dispersion of polyacrylic acid is added to the suspension in a volume amount corresponding to 1-2 masses. % of the processed sample of the phosphor and mix the suspension on a magnetic stirrer for 30 minutes;

Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted;

Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C.

The dried phosphor is sieved through a nylon sieve.

Checking the stability of phosphors to environmental factors was carried out under the following conditions.

A portion of the processed phosphor sample was placed in a beaker, a ten-fold volume of distilled water was poured, the suspension was stirred, and the suspension obtained was heated in a thermostat to a temperature of 60 ° C, and the suspension was kept under similar conditions for 5 hours. At the end of this time, the supernatant was decanted and the phosphor was dried to a dusting state at a temperature of 90-110 ° C. Next, we evaluated the luminous intensity of the tested and the initial phosphor, and compared the result.

The inventive method of applying a protective film on the surface of the particles of phosphors is illustrated by examples of specific performance.

Example 1

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker is mounted on a magnetic stirrer and the suspension is stirred for 5 minutes. A commercial solution of tetraethoxysilane is poured into the suspension in an amount of 0.2-0.24 ml, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg , Ca, Sr, Ba), in an amount of 2.5-1.7 ml, and the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.25-0.5 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after

whereupon the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 2

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in an amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 2.5-1.7 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.25-0.5 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to

dusting conditions at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 3

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. To the suspension, a commercial solution of tetraethoxysilane in the amount of 0.76-1 ml is poured, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of the elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 2.5-1.7 ml, and the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.25-0.5 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 4

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in the amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of the nitric acid salt of the elements of the second group Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 1.6-1 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.25-0.5 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated

at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 5

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in the amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of the nitric acid salt of the elements of the second group Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 3-2.6 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.25-0.5 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors. Example 6

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in an amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 2.5-1.7 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in an amount of 0.2-0.24 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 7

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in an amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 2.5-1.7 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Then, a diluted solution of polyacrylic dispersion in the amount of 0.6-1 ml is added to the suspension, the suspension is stirred on a magnetic stirrer for 30 minutes. Further, the suspension settles for 20-30 minutes, after which the supernatant is decanted. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

Table 1 shows the measurement data of the lighting characteristics of the source and tested phosphors.

Example 8

100 ml of alcohol is poured into a beaker (V = 400 ml), 25 g of photoluminophore of the composition ZnS: Cu or Ca _x Sr _1-x S: Eu (where x = 0-1), or Y ₂ O ₂ S: Eu are added, or Ca _x Sr _1-x S _y Se _1-y : Eu (where x (y) = 0-1), or Ca (Sr) Y ₂ S ₄ : Eu; or cathodoluminophore composition (ZnCd) S: Ag, Al; or electroluminophore ZnS (S, Se): Cu, Al; or X-ray phosphor composition of ZnS: Ag; or a flare phosphor of the composition Ca _x Sr _1-x S: Eu, Sm (where x = 0-1) or ZnS: Ag, Sm, or Ca _x Sr _1-x S _y Se _1-y : Eu, Sm (where x (y) = 0-1). The beaker was mounted on a magnetic stirrer and the suspension was stirred for 5 minutes. A commercial solution of tetraethoxysilane in an amount of 0.25-0.75 ml is poured into the suspension, stirred for 5 minutes, a catalyst, a diluted solution (20-30 g / l) of nitric acid salt of elements of the second group of Me (NO ₃ ) ₂ (where Me = Mg, Ca, Sr, Ba), in an amount of 2.5-1.7 ml and, the suspension is stirred for 30 minutes to carry out the process of hydrolysis of tetraethoxysilane and applying a protective coating to the surface of the phosphor particles. Dry the phosphor sample to a dusting state at a temperature of 90-110 ° C. The dried phosphor is sieved through a nylon sieve.

Then, 10 g of the phosphor are taken from the obtained sample, transferred to a beaker, into which 100 ml of water is poured and thermostated at 60 ° C for 5 hours, after which the liquid is decanted and the phosphor is dried to a dusting state and sieved through a nylon sieve.

As follows from the data presented in the table, the application of a protective film on the surface of these phosphors prevents and increases the brightness and intensity of the flash due to the destruction of the matrix during testing under the created conditions. The proposed method, in contrast to the prototype, allows encapsulation of phosphors on a hydrolytically unstable basis. So, as can be seen from the table, the deposition of a protective film on the surface of phosphor crystals based on sulfides, sulfoselenides of alkaline earth elements (CaS: Eu, CaS: Eu, Sm, SrS: Eu, SrS: Eu, Sm, Ca _0.2 Sr _0.8 S: Eu , Sm, Ca _0.2 Sr _0.8 S _0.7 Se _0.3 , Eu, Sm) and a solid solution of sulfides of alkaline earth and rare earth metals (SrY ₂ S ₄ : Eu) leads to the degradation of phosphors by hydrolysis of the matrix, at the stage of applying a protective coating, which is shown to be zero the level of brightness and intensity of the flash on the indicated light compositions (table).

According to the results obtained, the optimal amounts added during the application of the protective coating are as follows:

commercial tetraethoxysilane solution = 0.25-0.75 ml,

diluted catalyst solution = 2.5-1.7 ml

dilute solution of polyacrylic dispersion = 0.25-0.5 ml

According to the data presented, an insufficient amount of tetraethoxysilane, with an optimal ratio of the remaining components, as well as a lack of catalyst, with an optimal ratio of the remaining components, leads to insignificant differences in the brightness / intensity of the burst of phosphors in comparison with samples on the surface of which a protective surface coating was applied in these intervals of optimal concentrations. At the same time, phosphor crystals are sufficiently protected from environmental factors, which can be established by maintaining the flash intensity / luminescence brightness at a level of ≥ 100% from the original sample.

An increase in the content of tetraethoxysilane with an optimal ratio of the remaining components, as well as excess catalyst with an optimal ratio of the remaining components, leads to insignificant differences in the brightness / intensity of the burst of phosphors in comparison with samples on the surface of which a protective surface coating was applied in the indicated ranges of optimal concentrations to an increase in the flash intensity and luminescence brightness, while maintaining the same resistance of the phosphor samples to the fact s environment. This fact indicates the economic inappropriateness of using tetraethoxysilane and / or catalyst in an amount greater than the established optimal concentration limits in the process of applying a surface film to phosphor crystals.

When a polyacrylic dispersion solution is added less than the indicated optimal concentration range, it is not possible to obtain a higher luminescence intensity of the samples encapsulated in this way, but it increases the protection of the samples to environmental factors.

The optimal concentration of the solution of polyacrylic dispersion used in the process of applying the protective film, allows you to get the phosphor that is most protected from environmental factors and the highest possible luminescence intensity. This fact is probably explained by the best ratio of film thicknesses, their transparency, as well as the interaction of two objects when creating a core-shell system (phosphor crystal and complex protective coating, respectively), which allows the phosphor crystal to better conduct radiation emission and obtain flow of exciting energy. In this case, the effect of increasing the brightness / intensity of the luminescence flash is observed.

An increase in the amount of polyacrylic dispersion, in comparison with the optimal amount, leads to a decrease in flash intensity / luminescence brightness due to the formation of a more “muffled” coating, which acts as a “gray” filter that prevents the penetration of exciting radiation to the phosphor crystal and the emission of converted radiation out. In this case, the addition of a greater amount of polyacrylic dispersion compared with the optimum set amount is not economically feasible.

The application of a complex surface coating to the surface of the phosphor particles by the present method allows to increase and maintain the lighting characteristics of a wide class of phosphors, for example, photo, cathode, electro, X-ray phosphors, flash phosphors brought into interaction with a hydrolytic agent, eliminates the unpleasant odor of unstable chalcogenide phosphors , which allows you to expand the application of phosphors based on unstable compounds to environmental factors created by natural Twain or artificial way, for example, under conditions of high humidity and temperature.

Thus, the application of a protective film to the surface of the phosphor particles by the present method can improve the lighting characteristics of a wide class of phosphors, for example photo, cathode, electro, X-ray phosphors, flash phosphors, brought into interaction with a hydrolytic agent, eliminates the unpleasant odor of unstable chalcogenide phosphors, which allows you to expand the application of phosphors based on unstable compounds, to environmental factors created by natural or artificial by the way, for example, in conditions of high humidity and temperature. Phosphors with a protective film on the surface of their particles obtained by the proposed application method can be used as light-correcting additives in the manufacture of polymer films to create artificial lighting for greenhouses and greenhouses, as well as in LED technology, in secure printing, as IR visualizers radiation, in night vision devices, dosimeters, devices used for laser alignment, when creating displays of various designs for displaying alphanumeric information, competition Rui with foreign counterparts, which is important in terms of import substitution.

Claims (1)

A method of applying a protective film to the surface of phosphor particles, including treating the surface of the phosphor particles with a polysilicic acid sol synthesized by hydrolysis of tetraethoxysilane, and drying the treated phosphor, characterized in that the polysilicic acid sol is synthesized in an alcohol solution of tetraethoxysilane in an amount of 0.1-0.3 mass. %, in the presence of a catalyst - a solution of nitric salt of the elements of the second group in the amount of 18-25 mass. %, in the process of applying a protective coating to the surface of the phosphor particles, followed by encapsulation of the phosphor crystals with a film formed on the surface of the crystals from a solution of a dispersion of polyacrylic acid, added in an amount of 1-2 mass. % of the processed mass of the phosphor.