CN1587149A - Method for synthesizing high pure superfine biological glass powder - Google Patents
Method for synthesizing high pure superfine biological glass powder Download PDFInfo
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- CN1587149A CN1587149A CN200410080802.4A CN200410080802A CN1587149A CN 1587149 A CN1587149 A CN 1587149A CN 200410080802 A CN200410080802 A CN 200410080802A CN 1587149 A CN1587149 A CN 1587149A
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Abstract
The present invention relates to method of synthesizing high purity superfine biological glass powder, and features that after hydrolyzing ethyl silicate for 0.5-1 hr, ethyl phosphate, ethanol solution of calcium nitrate and ethanol solution of magnesium nitrate are dropped successively into the hydrolyzed ethyl silicate liquid and deionized water and nitric acid are then added to regulate pH value to 0.5-2; the mixed liquid is aged and mixed with urea in the same volume, and the mixture is ignited to burn to obtain glass powder precursor; and the precursor is heated to obtain superfine biological glass powder. The simple process can eliminate devitrification, component segregation and crucible pollution, and has short production period, less introduced impurity and less hard powder aggregation.
Description
Technical field
A kind of method of synthesizing high pure superfine biological glass powder relates to a kind of method that is used to prepare the glass powder of bio-vitric and stupalith thereof.
Background technology
At present, the preparation method of bio-vitric and ceramic powder thereof mainly is the high temperature melting method, this method required equipment complexity, inconvenient operation, raw material is volatile, and the constituent element loss is big, and devitrification and component segregation phenomenon are difficult for eliminating, be prone to crucible and pollute, these characteristics will produce certain negative impact to the over-all properties of bioglass material.Sol-gel method has solved some problems that the high temperature melting method is brought, as component segregation and crucible pollution etc., and, owing to be in solution, to react, can make reaction raw materials uniform mixing on atom, molecular level.In addition, the gel powder purity height, the specific surface area that make are big, are more suitable in being used as biomaterial.But, utilize Prepared by Sol Gel Method xanthan gel glass powder have the powder process cycle long, easily introduce impurity, powder shortcomings such as hard aggregation take place easily.Particularly in multicomponent system, utilize the Prepared by Sol Gel Method powder, occurring causing the fast solute selective hydrolysis of hydrolysis rate to form precipitation because the hydrolytie polycondensation speed of each solute is different easily separates out, cause the phenomenon of whole system uneven components, and after making gel, will be through reaching 100 hours ageing drying, in this process, a large amount of materials comprises that volatilizations such as ethanol, acid, alkoxide or ester can cause environmental pollution, and the preferential supersaturation that some metal-salt can occur separates out, and influences the final homogeneity of powder.
Summary of the invention
The objective of the invention is in order to overcome the shortcoming that above-mentioned prior art exists, the milling method that equipment is simple, easy to operate, can effectively eliminate devitrification and component segregation phenomenon and crucible pollution is provided.It is short that this method also has the powder process cycle, introduces the few advantage of impurity, and to make powder be soft-agglomerated form, grinds easily and obtain ultrafine powder.
The objective of the invention is to be achieved through the following technical solutions.
A kind of method of synthesizing high pure superfine biological glass powder is characterized in that its preparation process successively:
A. be SiO at first according to amounting to into oxide mol ratio
2: CaO: P
2O
5: the amount of MgO=1~7: 1~7: 0~2: 0~2 is measured tetraethyl silicate, etherophosphoric acid, nitrocalcite and magnesium nitrate respectively, mix mutually for its dehydrated alcohol of 5~10 times with mol ratio respectively, make tetraethyl silicate/ethanol, etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln;
B. the deionized water that with mole number is 0.5~2 times of tetraethyl silicate mole number is added drop-wise in the ethanolic soln of tetraethyl silicate, and making its prehydrolysis is the hydrolysis intermediate product that polymerizing power is arranged;
C. successively they are added drop-wise in the prehydrolysis tetraethyl silicate/ethanolic soln of b step according to etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/alcoholic acid order; After every kind of solution dropwises 0.5~1 hour, add a kind of solution down again;
D. after all solution dropwised, adding mole number was the deionized water of 0.5~2 times of tetraethyl silicate mole number, and it is complete to make system continue hydrolytie polycondensation;
E. pH value to 0.5~2 that add catalyzer nitric acid regulator solution;
F. the colloidal sol that the e step is made rested under the humid atmosphere of 55 ℃~60 ℃ temperature, humidity 50%~100% ageing 20~60 hours, made wet gel;
G. wet gel and isopyknic urea are mixed,, from horizontal blanking, make the glass powder presoma until flame 400 ℃~600 ℃ down-firing burnings;
H. precursor powder is ground in agate mortar, obtain the ultrafine powder that the powder median size is 150~300 nanometers;
I. handle the powder 2~4 hours that the h steps make at 700 ℃~850 ℃, make intracrystalline crystal water, nitrate and carbonate in the powder fully decompose and volatilize, promptly obtain superfine biological glass powder.
Method of the present invention, allow the slow tetraethyl silicate of hydrolytie polycondensation speed hydrolysis certain hour in advance, make its formation have the hydrolysis intermediate product of certain polymerizing power, add the fast etherophosphoric acid of hydrolysis rate again, the artificial hydrolytie polycondensation time of regulating both makes it to be consistent, avoided the fast etherophosphoric acid selective hydrolysis of hydrolysis rate, separated out thereby form precipitation with nitrocalcite that adds subsequently and magnesium nitrate.The water that adds in the d step is the deficiency of replenishing the water yield in the system reaction process, and hydrolysis condensation reaction is carried out fully.Utilize tetraethyl silicate and etherophosphoric acid hydrolytie polycondensation to prepare wet gel, calcium, magnesium ion are evenly distributed in the gel as the network intermediate; Wet gel lighted a fire at a lower temperature make its rapid combustion synthesize high-purity fluffy glass forerunner powder.Forerunner's powder promptly obtains the biological glass powder of high pure and ultra-fine through Overheating Treatment, grinding.
Method of the present invention has sol-gel method concurrently and spreads the advantage of method certainly, equipment is simple, easy to operate, effectively eliminate and have the characteristics that the powder process cycle is short, introducing impurity is few, powder is difficult for taking place hard aggregation, synthesizing high pure superfine biological gel glass powder fast when devitrification and component segregation phenomenon and crucible pollute.
Description of drawings
Accompanying drawing is a process flow diagram of the present invention.
Embodiment
A kind of method of synthesizing high pure superfine biological glass powder, its preparation process is: a. is according to amounting to into oxide compound than being SiO
2: CaO: P
2O
5: the amount of MgO=1~7: 1~7: 0~2: 0~2 is measured tetraethyl silicate, etherophosphoric acid, nitrocalcite and magnesium nitrate, mix mutually for its dehydrated alcohol of 5~10 times with mol ratio respectively, make etherophosphoric acid/ethanol and tetraethyl silicate/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln.B. the deionized water that with mole number is 0.5~2 times of tetraethyl silicate mole number is added drop-wise in tetraethyl silicate/ethanolic soln, makes its prehydrolysis 0.5~1 hour.C. the order according to etherophosphoric acid, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln is added drop-wise to them in tetraethyl silicate/ethanolic soln successively.Whenever drip a kind of solution and add another kind of solution after 0.5~1 hour again, guarantee fully carrying out of reaction.D. after all solution dropwised, adding mole number was the deionized water of 0.5~2 times of tetraethyl silicate mole number, adds the pH value of catalyzer nitric acid regulator solution again, and it is remained between 0.5~2.E. the colloidal sol that makes is rested under the humid atmosphere of 55~60 ℃ of temperature, 50~100% humidity ageing 20~60 hours, and generated wet gel.F. wet gel and isopyknic urea are mixed, 400~600 ℃ of ignition to flame from horizontal blanking, make the glass powder presoma; G. precursor powder is ground in agate mortar, can obtain the ultrafine powder that median size is 150~300 nanometers; H. in 700~850 ℃ of electric furnaces, handle this powder 2~4 hours, can obtain superfine biological glass powder.
Embodiment 1
According to the oxide mol ratio ratio is SiO
2: CaO: P
2O
5: MgO=5: 3: 1: 1 amount is measured tetraethyl silicate, nitrocalcite, etherophosphoric acid and magnesium nitrate, mix mutually for its dehydrated alcohol of 10 times with mol ratio respectively, make etherophosphoric acid, ethanol and tetraethyl silicate/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln.With mole number is that the deionized water of 1 times of tetraethyl silicate mole number is added drop-wise in tetraethyl silicate/ethanolic soln, makes its prehydrolysis 0.5 hour.Order according to etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln is added drop-wise to them in the tetraethyl silicate pre-hydrolyzed solution successively.Whenever drip a kind of solution, react and add another kind of solution again after 1 hour, guarantee fully carrying out of reaction.After all solution dropwised half an hour, adding mole number was the deionized water of 1 times of tetraethyl silicate mole number, and the pH value that adds catalyzer nitric acid regulator solution again is 0.5.More than test is carried out following vigorous stirring in the process always.The colloidal sol that makes rested on ageing became wet gel in 20 hours under 60 ℃, the humid atmosphere of humidity 50%.Wet gel and isopyknic urea are mixed,, make the glass powder presoma 400 ℃ of ignition; Precursor powder is ground half an hour in agate mortar, can obtain the ultrafine powder that the powder median size is 150 nanometers; In 850 ℃ of electric furnaces, handle this powder 2 hours, can obtain superfine biological glass powder.
According to the oxide mol ratio ratio is SiO
2: CaO: P
2O
5: MgO=1: 7: 1: 1 amount is measured tetraethyl silicate, nitrocalcite, etherophosphoric acid and magnesium nitrate, mix mutually for its dehydrated alcohol of 9 times with mol ratio respectively, make etherophosphoric acid/ethanol and tetraethyl silicate/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln.With mole number is that the deionized water of 0.5 times of tetraethyl silicate mole number is added drop-wise in tetraethyl silicate/ethanolic soln, makes its prehydrolysis 1 hour.Order according to etherophosphoric acid, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln is added drop-wise to them in the tetraethyl silicate pre-hydrolyzed solution successively.Whenever drip a kind of solution, react and add another kind of solution again after 0.5 hour, guarantee fully carrying out of reaction.After all solution dropwised half an hour, adding mole number was the deionized water of 0.5 times of tetraethyl silicate mole number, and the pH that adds catalyzer nitric acid regulator solution again is 1.5.The colloidal sol that makes is rested under 55 ℃, the humid atmosphere of humidity 70% ageing 30 hours, become wet gel.Wet gel and isopyknic urea are mixed,, make the glass powder presoma 500 ℃ of ignition; Precursor powder is ground half an hour in agate mortar, can obtain the ultrafine powder that the powder median size is 250 nanometers; In 850 ℃ of electric furnaces, handle this powder 3 hours, can obtain superfine biological glass powder.
Embodiment 3
According to the oxide mol ratio ratio is SiO
2: CaO: P
2O
5: MgO=7: 1: 1: 1 amount is measured tetraethyl silicate, nitrocalcite, etherophosphoric acid and magnesium nitrate, mix mutually for its dehydrated alcohol of 8 times with mol ratio respectively, make etherophosphoric acid/ethanol and tetraethyl silicate/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln.With mole number is that the deionized water of 0.5 times of tetraethyl silicate mole number is added drop-wise in tetraethyl silicate/ethanolic soln, makes its prehydrolysis 1 hour.Order according to etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln is added drop-wise to them in the tetraethyl silicate pre-hydrolyzed solution successively.Whenever drip a kind of solution, react and add another kind of solution again after 0.5 hour, guarantee fully carrying out of reaction.After all solution dropwised half an hour, adding mole number was the deionized water of 0.5 times of tetraethyl silicate mole number, adds catalyzer nitric acid again, and the pH of regulator solution is 2.The colloidal sol that makes is rested under 60 ℃, the humid atmosphere of humidity 90% ageing 50 hours, become wet gel.Wet gel and isopyknic urea are mixed,, make the glass powder presoma 600 ℃ of ignition; Precursor powder is ground half an hour in agate mortar, can obtain the ultrafine powder that the powder median size is 200 nanometers; In 850 ℃ of electric furnaces, handle this powder 4 hours, can obtain superfine biological glass powder.
Embodiment 4
According to the oxide mol ratio ratio is SiO
2: CaO: P
2O
5=5: 3: 2 amount is measured tetraethyl silicate, nitrocalcite and etherophosphoric acid, mixes mutually for its dehydrated alcohol of 5 times with mol ratio respectively, makes etherophosphoric acid/ethanol and tetraethyl silicate/ethanol and nitrocalcite/ethanol.With mole number is that the deionized water of 0.5 times of tetraethyl silicate mole number is added drop-wise in tetraethyl silicate/ethanolic soln, makes its prehydrolysis 1 hour.Order according to etherophosphoric acid and nitrocalcite/ethanolic soln is added drop-wise to them in the tetraethyl silicate pre-hydrolyzed solution successively.Whenever drip a kind of solution, react and add another kind of solution again after 0.5 hour, guarantee fully carrying out of reaction.After all solution dropwised half an hour, adding mole number was the deionized water of 2 times of tetraethyl silicate mole numbers, and the pH that adds catalyzer nitric acid regulator solution again is 2.The colloidal sol that makes is rested under 60 ℃, the humid atmosphere of humidity 100% ageing 60 hours, obtain wet gel.Wet gel and isopyknic urea are mixed,, make the glass powder presoma 500 ℃ of ignition; Precursor powder is ground half an hour in agate mortar, can obtain the ultrafine powder that the powder median size is 150 nanometers; Handle this powder 3 hours at 750 ℃, can obtain superfine biological glass powder.
Claims (1)
1. the method for a synthesizing high pure superfine biological glass powder is characterized in that its preparation process successively:
A. be SiO at first according to amounting to into oxide mol ratio
2: CaO: P
2O
5: the amount of MgO=1~7: 1~7: 0~2: 0~2 is measured tetraethyl silicate, etherophosphoric acid, nitrocalcite and magnesium nitrate respectively, mix mutually for its dehydrated alcohol of 5~10 times with mol ratio respectively, make tetraethyl silicate/ethanol, etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/ethanolic soln;
B. the deionized water that with mole number is 0.5~2 times of tetraethyl silicate mole number is added drop-wise in the ethanolic soln of tetraethyl silicate, and making its prehydrolysis is the hydrolysis intermediate product that polymerizing power is arranged;
C. successively they are added drop-wise in the prehydrolysis tetraethyl silicate/ethanolic soln of b step according to etherophosphoric acid/ethanol, nitrocalcite/ethanol and magnesium nitrate/alcoholic acid order; After every kind of solution dropwises 0.5~1 hour, add a kind of solution down again;
D. after all solution dropwised, adding mole number was the deionized water of 0.5~2 times of tetraethyl silicate mole number, and it is complete to make system continue hydrolytie polycondensation;
E. pH value to 0.5~2 that add catalyzer nitric acid regulator solution;
F. the colloidal sol that the e step is made rested under the humid atmosphere of 55 ℃~60 ℃ temperature, humidity 50%~100% ageing 20~60 hours, made wet gel;
G. wet gel and isopyknic urea are mixed,, from horizontal blanking, make the glass powder presoma until flame 400 ℃~600 ℃ down-firing burnings;
H. precursor powder is ground in agate mortar, obtain the ultrafine powder that the powder median size is 150~300 nanometers;
I. handle the powder 2~4 hours that the h steps make at 700 ℃~850 ℃, make intracrystalline crystal water, nitrate and carbonate in the powder fully decompose and volatilize, promptly obtain superfine biological glass powder.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CNB2004100808024A CN1300026C (en) | 2004-10-12 | 2004-10-12 | Method for synthesizing high pure superfine biological glass powder |
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|---|---|---|---|
| CNB2004100808024A CN1300026C (en) | 2004-10-12 | 2004-10-12 | Method for synthesizing high pure superfine biological glass powder |
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| CN1587149A true CN1587149A (en) | 2005-03-02 |
| CN1300026C CN1300026C (en) | 2007-02-14 |
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102219386A (en) * | 2011-05-16 | 2011-10-19 | 武汉理工大学 | Preparation method for ultrafine powder body of SiO2-based composite oxide system glass |
| CN106673426A (en) * | 2017-01-13 | 2017-05-17 | 上海师范大学 | Porous-microsphere nanoscale bioglass material doped with rare earth element as well as preparation method and application of porous-microsphere nanoscale bioglass material |
| CN106800406A (en) * | 2016-12-19 | 2017-06-06 | 中国矿业大学 | A kind of microwave radiation technology collosol and gel burning synthesis method of titanium porcelain Special body porcelain powder |
| CN111908798A (en) * | 2020-04-30 | 2020-11-10 | 华南理工大学 | Sr/Mg/Zn/Cu doped silicon-based sol-gel bioactive glass powder and preparation method and application thereof |
Family Cites Families (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPS58176135A (en) * | 1982-04-07 | 1983-10-15 | Mitsubishi Metal Corp | Preparation of quartz glass powder |
| JPS58176136A (en) * | 1982-04-12 | 1983-10-15 | Mitsubishi Metal Corp | Preparation of quartz glass powder |
| JPS58190831A (en) * | 1982-04-27 | 1983-11-07 | Mitsubishi Metal Corp | Manufacture of quartz glass powder |
| CN1151086C (en) * | 2002-01-18 | 2004-05-26 | 中国科学院上海硅酸盐研究所 | Nanometer level bioactive glass powder material and its prepn |
-
2004
- 2004-10-12 CN CNB2004100808024A patent/CN1300026C/en not_active Expired - Fee Related
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102219386A (en) * | 2011-05-16 | 2011-10-19 | 武汉理工大学 | Preparation method for ultrafine powder body of SiO2-based composite oxide system glass |
| CN102219386B (en) * | 2011-05-16 | 2013-04-24 | 武汉理工大学 | Preparation method for ultrafine powder body of SiO2-based composite oxide system glass |
| CN106800406A (en) * | 2016-12-19 | 2017-06-06 | 中国矿业大学 | A kind of microwave radiation technology collosol and gel burning synthesis method of titanium porcelain Special body porcelain powder |
| CN106673426A (en) * | 2017-01-13 | 2017-05-17 | 上海师范大学 | Porous-microsphere nanoscale bioglass material doped with rare earth element as well as preparation method and application of porous-microsphere nanoscale bioglass material |
| CN111908798A (en) * | 2020-04-30 | 2020-11-10 | 华南理工大学 | Sr/Mg/Zn/Cu doped silicon-based sol-gel bioactive glass powder and preparation method and application thereof |
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| CN1300026C (en) | 2007-02-14 |
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Assignee: Xi'an Huatai Nonferrous Metal Industry Co.,Ltd. Assignor: NORTHWEST INSTITUTE FOR NONFERROUS METAL RESEARCH Contract fulfillment period: 2008.3.20 to 2018.3.20 Contract record no.: 2009610000069 Denomination of invention: Method for synthesizing high pure superfine biological glass powder Granted publication date: 20070214 License type: General permission Record date: 20091126 |
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Free format text: COMMON LICENSE; TIME LIMIT OF IMPLEMENTING CONTACT: 2008.3.20 TO 2018.3.20; CHANGE OF CONTRACT Name of requester: XI'AN HUATAI NONFERROUS METAL INDUSTRY CO., LTD Effective date: 20091126 |
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