CN100334182C - Process for preparing silicon blue photoluminescent material - Google Patents
Process for preparing silicon blue photoluminescent material Download PDFInfo
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- CN100334182C CN100334182C CNB2005101222522A CN200510122252A CN100334182C CN 100334182 C CN100334182 C CN 100334182C CN B2005101222522 A CNB2005101222522 A CN B2005101222522A CN 200510122252 A CN200510122252 A CN 200510122252A CN 100334182 C CN100334182 C CN 100334182C
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Abstract
The present invention provides an aerosol manufacture method for a method for manufacturing blue silicate photoluminescence materials, which belongs to the technical field of luminescent materials. The method is characterized in that silicon dioxide particles in a nanometer dimension are used as pre-bury crystal seed, and the silicon dioxide particles are peptized by using weak acid and added with a small amount of surfactants; the silicon dioxide particles and a compound of strontium, magnesium, europium and dysprosium are prepared into uniform solution according to a metering ratio and then atomized to evaporate water in liquid drops in the process of flight, and thus, the spherical dried gel particles with uniformly distributed components are formed; reduction thermal decomposition is carried out on the gel particles, and then the blue silicate photoluminescence long-afterglow materials can be obtained. The method combines the advantages of a liquid phase method, a sol-gel method and a spraying thermal decomposition method; the luminescent materials are a plurality of loose particles in a micrometer size and do not need the processing of ball milling, the afterglow time is more than 16 hours, and the present invention is suitable for mass production.
Description
[technical field]
The invention belongs to the photoelectric material technical field, particularly a kind of aerosol preparation method who mixes the silicate blue photoluminescence long-afterglow material of europium and dysprosium ion altogether.
[background technology]
Have commercial long-afterglow material now based on aluminates system, SrAl
2O
4: Eu, Dy, CaAl
2O
4: Eu, Nd and Sr
4Al
14O
25: Eu, Dy are main kinds.In order to overcome the deficiency of the poor chemical stability that has aluminate long afterglow materials now, developed the long-afterglow material (ZL98105078) of silicate systems.These luminescent materials mostly adopt traditional solid phase method preparation.The characteristics of solid phase method are that raw material needs the ball milling operation, with each component of thorough mixing; The firing temperature height will add fusing assistant usually; Final product also needs ball milling, and this causes brightness to reduce usually; There is dephasign etc. easily in product.
Adopting the spraying-pyrolysis method of soluble salt (being generally the nitrate of each component) solution to have that thing is mutually pure, the tiny characteristics of particle, is an important technology of preparing route.Main deficiency has, and when raw material adopts complete nitrate ion solution, introduces a large amount of nitrate ions, decomposes at the high temperature firing process to produce oxynitride, and environment is worked the mischief; The broken easily or formation ghost particle of the luminescent material particle that obtains.
[summary of the invention]
The object of the present invention is to provide a kind of process for preparing silicon blue photoluminescent material of mixing europium and dysprosium altogether.This method adopts the aerogel technology of the silica dioxide granule of imbedding nanoscale in advance, can increase the ratio of active principle in the luminescent material, reduces and pollutes, and feed composition is mixed, and can also make the size of final luminescent material and pattern controlled easily.
Technical scheme of the present invention discloses a kind of process for preparing silicon blue photoluminescent material of mixing europium and dysprosium altogether.This method adopts nanometer silicon dioxide particle as fluor silicon source, carry out peptization with weak acid, and adding dispersion agent, after being made into homogeneous solution, the soluble salt of strontium, magnesium, europium and dysprosium atomizes, form spherical dry gel particle, this particle carries out the reduction heat decomposition reaction again, can obtain silicate blue photoluminescence long-afterglow material.
The first prepare silicon sol solution of preparation method provided by the invention, be atomized into dry gel particle again, obtain the silicate luminescent material of uniform component distribution at last through once-firing, compared with prior art have several big characteristics: 1) Lian Jia nano silicon had both been done the silicon source of product, also as xerogel and particle crystalline center, reduce to pollute, prevent or reduce the generation of ghost light-emitting particles; 2) material composition mixes on nanometer, atom, molecular scale level; 3) the fluor firing temperature reduces, and helps energy-conservation; 4) phosphor particle is several microns sizes, cancellation ball milling operation; 5) this material sends the light of 420-520nm under the exciting of the light of the following wavelength of 430nm, and peak value is at 468nm.Be fit to large-scale production more than 16 hours time of persistence.
[description of drawings]
Accompanying drawing 1 is the X-ray diffractogram of silicate luminescent material of the present invention;
Accompanying drawing 2 is exciting light spectrograms of silicate luminescent material of the present invention;
Accompanying drawing 3 is emmission spectrum figure of silicate luminescent material of the present invention.
[embodiment]
The aerosol method of the silicate blue photoluminescence long-afterglow material of europium and dysprosium ion is mixed in the present invention's preparation, mainly comprises the glue body, aerogel and high temperature sintering step.This method adopts the silica dioxide granule of nanoscale as pre-buried crystal seed, carry out peptization with weak acid, and adding paucidisperse agent, soluble salt with strontium, magnesium, europium and dysprosium atomizes after being made into homogeneous solution by metering, water in the drop is evaporated in flight course, form the spherical dry gel particle of uniform component distribution.This particle carries out the reduction heat decomposition reaction again, can obtain silicate blue photoluminescence long-afterglow material.Wherein:
Said fluor matrix group becomes Sr
2MgSi
2O
7: Eu, Dy;
Nano silicon is adopted in the silicon source of said fluor, and purity is 99.9-99.99% (percent by weight), and size is the 5-40 nanometer.Peptization distilled water dosing, control silicon-dioxide: water (weight ratio)=1: 20~40, pH=2~4;
Strontium, magnesium in the said fluor composition adopt water-soluble nitrate or acetate, purity 〉=99.9% (percent by weight), and quantity adds silicon dioxide gel by stoichiometric ratio;
The said compound that adds europium and dysprosium in the silicon dioxide gel, europium and dysprosium adopt water-soluble nitrate or acetate, purity 〉=99.99% (percent by weight), quantity press strontium: europium (atomic molar number)=1: 0.01~0.05, dysprosium are 1-3 times of europium;
Said solid alkyl trimethyl class or the solid polyethylene alcohol tensio-active agent of adding in the silicon dioxide gel, quantity are by colloidal sol: tensio-active agent (percent by weight)=0.5-3%;
Said employing colloidal sol air atomizing is at 110 ℃~250 ℃ of compressed air temperature, dry air amount 100~300m
3/ h atomizes to the doped silicon oxide colloid under streams 1~2L/h, obtains dry gel particle;
Said particle reaches 1000 ℃~1400 ℃ of firing temperatures in weakly reducing atmosphere, carry out high temperature in time 2-4 hour and burn till, and reducing atmosphere can adopt N
2+ H
2, a kind of in gac reduction, decomposed ammonia body or the coal gas.
Following example is unrestricted the present invention in order further to illustrate technological process feature of the present invention.
Example 1
According to silicon-dioxide: water (weight ratio)=1: 20 is size the SiO of 10 nanometer sizes
2Join in the distilled water, transfer pH=2 with a small amount of nitric acid, again according to Sr
2MgSi
2O
7Formula is calculated strontium nitrate and the magnesium nitrate that adds theoretical amount, press strontium: europium (atomic molar number)=0.01 adds europium nitrate, and dysprosium is 2 times of europium, presses colloidal sol again: alkyl trimethyl class tensio-active agent (percent by weight)=0.1 adds, carry out mechanical stirring and become colloidal sol, colloidal sol left standstill 1 hour; The air atomizing parameter is set is: 110 ℃ of temperature ins, dry air amount 100m
3/ h, streams 2L/h obtains dry gel particle; Feeding flow in horizontal pipe furnace is the N of 2L/h
2+ 5%H
2(volume ratio) mixed gas after burning till 2 hours under 1000 ℃, obtains luminescent material, and granular size is 5 microns.
Accompanying drawing 1 is X-ray diffraction (XRD) figure of the silicate luminescent material of this example, and accompanying drawing 2 is exciting light spectrograms of the silicate luminescent material of this example, and accompanying drawing 3 is emmission spectrum figure of the silicate luminescent material of this example.
Example 2
According to silicon-dioxide: water (weight ratio)=1: 30 is size the SiO of 20 nanometer sizes
2Join in the distilled water, transfer pH=3 with a small amount of nitric acid, again according to Sr
2MgSi
2O
7Formula is calculated strontium nitrate and the magnesium nitrate that adds theoretical amount, press strontium: europium (atomic molar number)=0.02 adds europium nitrate, and dysprosium is 3 times of europium, presses colloidal sol again: alkyl trimethyl class tensio-active agent (percent by weight)=1% adds, carry out mechanical stirring and become colloidal sol, colloidal sol left standstill 2 hours; The air atomizing parameter is set is: 150 ℃ of temperature ins, dry air amount 200m
3/ h, streams 2L/h obtains dry gel particle; With gac reduction, in 1200 ℃ of following high temperature elevator furnaces, burn till 3 hours after, obtain luminescent material, granular size is 3 microns, and is spherical in shape.XRD figure spectrum, excitation spectrum and the emmission spectrum of product are similar to example 1.
Example 3
According to silicon-dioxide: water (weight ratio)=1: 40 is size the SiO of 40 nanometer sizes
2Join in the distilled water, transfer pH=2.5 with a small amount of nitric acid, again according to Sr
2SiO
4Formula is calculated strontium nitrate and the magnesium nitrate that adds theoretical amount, presses strontium: europium (atomic molar number)=0.06 adds europium nitrate, dysprosium is 4 times of europium, press colloidal sol again: alkyl trimethyl class tensio-active agent (percent by weight)=3% adds, and carries out mechanical stirring and becomes colloidal sol, and colloidal sol left standstill 3 hours; The air atomizing parameter is set is: 200 ℃ of temperature ins, dry air amount 300m
3/ h, streams 2L/h obtains dry gel particle; Feeding flow in horizontal pipe furnace is the N of 2L/h
2+ 5%H
2(volume ratio) mixed gas after burning till 2 hours under 1300 ℃, obtains luminescent material, and granular size is 1 micron, and is spherical in shape.XRD figure spectrum, excitation spectrum and the emmission spectrum of product is similar to example 1.
Claims (11)
1. process for preparing silicon blue photoluminescent material, it is characterized in that: adopt nanometer silicon dioxide particle as fluor silicon source, carry out peptization with weak acid, and adding dispersion agent, after being made into homogeneous solution, the soluble salt of strontium, magnesium, europium and dysprosium atomizes, form spherical dry gel particle, this particle carries out the reduction heat decomposition reaction again, can obtain silicate blue photoluminescence long-afterglow material.
2. preparation method as claimed in claim 1 is characterized in that said fluor matrix group becomes Sr
2MgSi
2O
7: Eu, Dy.
3. preparation method as claimed in claim 2 is characterized in that said nano silicon fluor silicon source, and purity is 99.9-99.99% by percent by weight, and size is the 5-40 nanometer.
4. preparation method as claimed in claim 3 is characterized in that the distilled water dosing of said peptization, controls silicon-dioxide by weight: water=1: 20~40, pH=2~4.
5. as claim 1 or 4 described preparation methods, it is characterized in that strontium, magnesium, europium and dysprosium in the said fluor composition adopt water-soluble nitrate or acetate, purity is 〉=99.9% by percent by weight, quantity is by stoichiometric ratio, and atomic molar is counted strontium: europium=1: 0.01~0.05, dysprosium is 1-3 a times of europium, joins silicon dioxide gel together.
6. preparation method as claimed in claim 5 is characterized in that said dispersion agent is solid alkyl trimethyl class or solid polyethylene alcohol tensio-active agent, and quantity is the 0.5-3% of colloidal sol weight.
7. as claim 1 or 6 described preparation methods, it is characterized in that said solution atomization, is at 110 ℃~250 ℃ of compressed air temperature, dry air amount 100~300m
3/ h atomizes to the doped silicon oxide colloid under streams 1~2L/h, obtains dry gel particle;
8. as claim 1 or 6 described preparation methods, it is characterized in that described reduction heat decomposition reaction be said particle at weakly reducing atmosphere, and 1000 ℃~1400 ℃ of firing temperatures carry out high temperature in time 2-4 hour and burn till.
9. preparation method as claimed in claim 7, it is characterized in that described reduction heat decomposition reaction be said particle at weakly reducing atmosphere, and 1000 ℃~1400 ℃ of firing temperatures carry out high temperature in time 2-4 hour and burn till.
10. preparation method as claimed in claim 8 is characterized in that the said reducing atmosphere that burns till can adopt N
2+ H
2, a kind of in gac reduction, decomposed ammonia body or the coal gas.
11. preparation method as claimed in claim 9 is characterized in that the said reducing atmosphere that burns till can adopt N
2+ H
2, a kind of in gac reduction, decomposed ammonia body or the coal gas.
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CN101760195B (en) * | 2010-01-22 | 2013-05-08 | 海洋王照明科技股份有限公司 | Silicate blue luminescent material and preparation method thereof |
CN105219389A (en) * | 2015-10-08 | 2016-01-06 | 上海应用技术学院 | Strontium silicate magnesium raw powder's production technology is prepared in a kind of rare earth Eu, Dy doping |
CN112160158B (en) * | 2020-09-15 | 2022-10-04 | 浙江夜光明光电科技股份有限公司 | Preparation process of printed light-reflecting and light-storing fabric prepared by same |
CN114836212B (en) * | 2022-04-22 | 2023-11-03 | 重庆交通大学 | SiO-based 2 Aerogel porous silicate long afterglow luminescent material and preparation method thereof |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1284108A (en) * | 1997-12-04 | 2001-02-14 | 松下电器产业株式会社 | Method of preparing high brightness, shorter persistence zinc orthosilicate phosphor |
CN1401731A (en) * | 2001-08-20 | 2003-03-12 | 深圳市清华彩虹纳米材料高科技有限公司 | Superlong after-grow Si-Al composite salt luminescence nanomaterial and mfg. method thereof |
CN1470598A (en) * | 2003-07-08 | 2004-01-28 | 重庆上游发光材料有限公司 | Lattice defect adjustable long-after glow luminescent material |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN1284108A (en) * | 1997-12-04 | 2001-02-14 | 松下电器产业株式会社 | Method of preparing high brightness, shorter persistence zinc orthosilicate phosphor |
CN1401731A (en) * | 2001-08-20 | 2003-03-12 | 深圳市清华彩虹纳米材料高科技有限公司 | Superlong after-grow Si-Al composite salt luminescence nanomaterial and mfg. method thereof |
CN1470598A (en) * | 2003-07-08 | 2004-01-28 | 重庆上游发光材料有限公司 | Lattice defect adjustable long-after glow luminescent material |
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