CN1354132A - Method for synthesizing small-grain A-type molecular sieve - Google Patents
Method for synthesizing small-grain A-type molecular sieve Download PDFInfo
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- CN1354132A CN1354132A CN 01135686 CN01135686A CN1354132A CN 1354132 A CN1354132 A CN 1354132A CN 01135686 CN01135686 CN 01135686 CN 01135686 A CN01135686 A CN 01135686A CN 1354132 A CN1354132 A CN 1354132A
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Abstract
The method for synthesizing small grain molecular sieve type A includes the folloiwng steps: firstly, according to the mole ratio of 1 Al2O3: (1-6) SiO2: (1-5) NaO2: (100-500) H2O preparing reaction silica-alumina gel; then according to the weight ratio of reaction silica-alumina gel: oil: surfactant: auxiliary surfactant=(4-6): (12-25): (1-5): (1-3) preparing stable W/O microemulsion, finally making the microemulsion to implement static crystallization at 90-120 deg.C. The crystallization of the molecular sieve is implemented in a specific water in oil (W/O) microemulsion, the crystal growth can be limited by finite space in the miniature water phase wrapped with oil phase, so that it prevents crystal from excessively growing, and the average grain size of said molecular sieve is less than 400 nm, its distribution range of grain size is narrow, and its crystallinity is above 90%.
Description
The present invention relates to a kind of synthetic method of molecular sieve.
Molecular sieve is because of the port size of its open pore passage structure, Subnano-class, big specific surface area, high ion-exchange performance and good heat, chemistry and biologically stable etc., has of crucial importance in many essential industry processes such as oil, chemical industry and environmental protection and uses widely as selective adsorption/separating agent and ion-exchanger.Selective adsorption/separation on the molecular sieve and ion exchange process are closely-related with its intracrystalline diffusion.For big crystal grain molecular sieve, small crystal grain molecular sieve has the particular structure characteristic, such as bigger outer surface area, more be exposed to outer structure cell and aperture, short and regular duct, skeleton component distribution uniformly etc., thereby when having determined it, have higher speed and capacity and shorter regeneration period as selective adsorption/separating agent and ion-exchanger.Therefore, the research of small crystal grain molecular sieve has important use value.
The general synthetic method of molecular sieve is that silicon source and aluminium source are mixed in certain medium (normally alkaline aqueous solution), forms unformed alumino silica gel, under hydrothermal temperature, goes out molecular sieve crystal through the certain hour crystallization then.If the nucleus in the synthetic system is many more, the molecular sieve crystal size that then finally synthesizes is more little and size distribution is even more.Owing in the molecular sieve crystallization process, exist running balance between the formation of molecular sieve nucleus and crystalline growth and its dissolving.With compare than small-crystalline or than the small crystal nucleus presoma, have bigger growth tendency than macrocrystal or big nucleus presoma, dissolving trend is then less.Therefore, along with the carrying out of molecular sieve crystallization process, can cause than small-crystalline or than the dissolving of small crystal nucleus presoma than the growth of macrocrystal or bigger nucleus presoma, thereby be unfavorable for composite crystals size and the uniform molecular sieve of size distribution.Many investigators have carried out useful exploration to small-grain A-type molecular sieve synthetic.(Study.SurfaceScience ﹠amp such as Bronic; Catalysis, Vol37, Elesvier, Amsterdam, 1988, P107) studied the influence of the ageing of reaction alumino silica gel to NaA zeolite crystal size.The result shows that along with the prolongation of digestion time, the number of dies in the synthetic system increases.Ageing 3 days and 7 days, the NaA molecular sieve that synthesizes has the grain fineness number of 10 μ m and 4 μ m respectively.Schoeman etc. (Zeolites, 1994,14:110) containing a large amount of organic lamina membranacea agent TMA
+The clear system in, synthesized NaA molecular sieve with 250nm average grain size.(Zeolites such as Myatt, 1994,14,190) tensio-active agent and solubility polymer have systematically been investigated to forming the influence of NaA nucleus, discovery adds the formation that cats product helps a large amount of less crystal seeds in synthetic system, the grain-size of final molecular sieve reduces.The adding aniorfic surfactant has then suppressed the formation of nucleus, has reduced nucleation rate, therefore forms the less and larger-size crystal seed of number, makes zeolite crystal bigger.Although patent Eas is Ger.Pat0238605, JP62-252314, JP62-256720, JP62-256895 and JP63-008212 adds tensio-active agent in synthetic system and the solubility polymer can synthesize the NaA type molecular sieve that grain-size is about 100nm, the degree of crystallinity of product and productive rate are all lower.
Purpose of the present invention aims to provide a kind of synthetic method of carrying out small-grain A-type molecular sieve in the micro emulsion system at night of specific water-in-oil (W/O).
The method steps of the said synthesizing small-grain A-type molecular sieve of the present invention is as follows:
1. the preparation of reaction alumino silica gel: press 1Al
2O
3: (1-6) SiO
2: (1-5) Na
2O: (100-500) H
2The mole proportioning of O is preferably 1Al
2O
3: (1-4) SiO
2: (2-4) Na
2O: (150-200) H
2The mole proportioning of O at 4-40 ℃, is preferably under room temperature and the mechanical stirring, silicon source, aluminium source, sodium hydroxide and water is mixed, and continue to be stirred to raw material and mix, and obtains reacting alumino silica gel.Said silicon source is water glass, silicon sol, is preferably silicon sol; Said aluminium source is new system aluminium hydroxide, sodium aluminate, is preferably sodium metaaluminate.
2.W/O the preparation of microemulsion system: by reacting alumino silica gel: oil: tensio-active agent: cosurfactant is (4-6): (12-25): (1-5): weight ratio (1-3), preferably by the reaction alumino silica gel: oil: tensio-active agent: cosurfactant is 5: 15: 3: 1.5 weight ratio, at first with oil, tensio-active agent and cosurfactant at 4-40 ℃, preferably mechanical stirring is mixed under the room temperature, slowly add the reaction alumino silica gel then, and it is even to continue to be stirred to the raw material thorough mixing with this understanding, obtains the W/O microemulsion.Said oil is hexanaphthene, sherwood oil, is preferably hexanaphthene; Said tensio-active agent is Triton X-100, sodium laurylsulfonate, is preferably Triton X-100; Said cosurfactant is Pentyl alcohol, n-hexyl alcohol, preferably Pentyl alcohol.
3. the crystallization of molecular sieve: the microemulsion of step 2 gained is changed in the autoclave pressure, and sealing then at 90-120 ℃ of following static crystallization 5-60 hour, is preferably in 100 ℃ of following static crystallization 15-20 hours; Product is dried down at 120 ℃ after neutral through centrifugal, repetitive scrubbing, obtains the A type molecular sieve sample.
The synthetic method of small-grain A-type molecular sieve provided by the invention, the crystallization of its molecular sieve is to carry out in the microemulsion system of specific water-in-oil (W/O), microemulsion system is by oil, water, tensio-active agent and cosurfactant are formed each homogeny, transparent and thermodynamically stable dispersion system, the particle diameter of drop is about 10-100nm, drop is stablized by the hybrid films of tensio-active agent and cosurfactant, because the crystal growth of molecular sieve is limited by the finite space in the small water that oil phase wrapped up, and can avoid excessively growing up of molecular sieve crystal; Simultaneously, be restricted, also can reduce and/or avoid because of the dissolving that growth caused than the small crystal nucleus presoma than macrocrystal or bigger nucleus presoma by the effect of mass transmitting between the small water that oil phase wrapped up.Therefore can effectively synthesize have less grain fineness number, the narrower molecular sieve of particle size distribution range.Sieve sample adopts X-ray diffraction (XRD), transmission electron microscope technology such as (TEM) characterizes crystalline phase, degree of crystallinity and grain-size, the average grain size of the A type molecular sieve that is synthesized is less than 400nm, and has narrower size distribution, and degree of crystallinity generally is higher than 90%.In addition, the organic phase in the microemulsion system can be used after separating behind the molecular sieve end of synthesis repeatedly, can reduce synthetic cost.
Fig. 1,2 is the TEM figure of embodiment 1 product A type molecular sieve.
The present invention will be further described below by embodiment:
Embodiment 1: press 1Al
2O
3: 2SiO
2: 3Na
2O: 150H
2The mole proportioning of O, with 30g silicon sol (25wt%, down together), the 62.5ml sodium aluminate solution is (by Al (OH)
3With the NaOH preparation, contain 2mol NaAlO in every liter of solution
2With 4mol NaOH, down with) and 90ml distilled water, under room temperature and mechanical stirring, mix, and be stirred to raw material and mix, obtain the alumino silica gel of leucosol shape.With 25g alumino silica gel, 15g Triton X-100,7.5g Pentyl alcohol and 75g hexanaphthene, under room temperature and mechanical stirring, mix, and be stirred to raw material and mix, can obtain stable W/O microemulsion system.Change in the autoclave pressure, crystallization was left standstill 15 hours in the sealing back under 100 ℃.Take out and cooling pressure still fast, product through high speed centrifugation, washing to neutral and at 120 ℃ down after the oven dry, gained sample XRD, the TEM technology characterizes.The XRD test result shows that the sample that above-mentioned synthetic method makes is an A type molecular sieve, and main diffraction peak data see Table 1, and degree of crystallinity is 97.4%.The TEM photo shows that (as Fig. 1) this A type molecular sieve sample has the average grain size of 300nm, and size distribution is comparatively even.
The XRD main diffraction peak position and the intensity of table 1 embodiment 1 products molecule sieve
2θ h
2+k
2+l D I/I
0
7.38 4 11.98435 100.0
10.38 8 8.526426 8.0
12.64 12 7.006546 30.8
16.26 20 5.453901 12.4
17.84 24 4.974278 4.6
21.84 36 4.07144 32.1
24.2 44 3.67947 51.1
27.34 56 3.263595 40.7
30.2 68 2.960724 48.3
32.84 80 2.728493 6.5
34.44 88 2.605308 29.7
36.06 100 2.491893 4.8
Embodiment 2: press 1Al
2O
3: 1SiO
2: 5Na
2O: 100H
2The mole proportioning of O is with 62.5ml water glass (1mol/lNa
2SiO
3Solution), 9.8g new system aluminium hydroxide, 20g sodium hydroxide and 100ml deionized water at room temperature with under the mechanical stirring mix, and are stirred to raw material and mix, and obtain reacting alumino silica gel.According to reacting alumino silica gel: oil: tensio-active agent: cosurfactant=6: 25: 5: 3 weight ratio, with 25g alumino silica gel, 24g Triton X-100,50g Pentyl alcohol and 100g hexanaphthene, under room temperature and mechanical stirring, mix, and be stirred to raw material and mix, can obtain stable W/O microemulsion system.Change in the autoclave pressure, crystallization was left standstill 15 hours in the sealing back under 100 ℃.Take out and cooling pressure still fast, product through high speed centrifugation, washing to neutral and at 120 ℃ down after the oven dry, gained sample XRD, the TEM technology characterizes.Characterization result shows that the sample that above-mentioned synthetic method makes is an A type molecular sieve, and degree of crystallinity is 95%, and average grain size is 370nm.
Embodiment 3: the preparation feedback alumino silica gel is identical with embodiment 1.According to reacting alumino silica gel: oil: tensio-active agent: cosurfactant=4: 12: 1: 1 weight ratio, with the 25g alumino silica gel, the 6g sodium laurylsulfonate, the 6g n-hexyl alcohol, the 75g sherwood oil, under room temperature and mechanical stirring, mix, and be stirred to raw material and mix, obtain stable W/O microemulsion system.Change in the autoclave pressure, crystallization was left standstill 15 hours in the sealing back under 100 ℃.Take out and quick cooling pressure still, after product such as embodiment 1 handle, carry out XRD, the TEM characterized by techniques.Characterization result shows that the sample that above-mentioned synthetic method makes is an A type molecular sieve, and degree of crystallinity is 92.7%, and average grain size is 330nm.
Embodiment 4: the raw material of preparation feedback alumino silica gel and microemulsion system is identical with embodiment 1 with consumption, but has prepared reaction alumino silica gel and microemulsion system respectively under 40 ℃, and the microemulsion system of gained was 90 ℃ of following crystallization 20 hours.After product such as embodiment 1 handle, carry out XRD, the TEM characterized by techniques.Characterization result shows that the sample that above-mentioned synthetic method makes is an A type molecular sieve, and degree of crystallinity is 94%, and average grain size is 385nm.
Embodiment 5: press 1Al
2O
3: 6SiO
2: 1Na
2O: 500H
2The mole proportioning of O, with the 90g silicon sol, 9.8g new system aluminium hydroxide, 5g sodium hydroxide and 495ml distilled water mix under room temperature and mechanical stirring, and continue to be stirred to raw material and mix, and obtain the alumino silica gel of leucosol shape.According to reacting alumino silica gel: oil: tensio-active agent: cosurfactant=7: 25: 5: 3 weight ratio, with 25g alumino silica gel, 18g Triton X-100,11g Pentyl alcohol, 90ml hexanaphthene, under room temperature and mechanical stirring, mix, and continue to be stirred to raw material and mix, obtain stable W/O microemulsion system.Change in the autoclave pressure, crystallization was left standstill 15 hours in the sealing back under 100 ℃.Take out and quick cooling pressure still, after product such as embodiment 1 handle, carry out XRD, the TEM characterized by techniques.Characterization result shows that the sample that above-mentioned synthetic method makes is an A type molecular sieve, and degree of crystallinity is 96.5%, and average grain size is 350nm.
Claims (7)
1, a kind of method of synthesizing small-grain A-type molecular sieve is characterized in that building-up reactions carries out in specific water in oil microemulsion system, step is as follows:
(1) preparation of reaction alumino silica gel: according to 1Al
2O
3: (1-6) SiO
2: (1-5) Na
2O: (100-500) H
2The mole proportioning of O under 4-40 ℃ and mechanical stirring, is mixed silicon source, aluminium source, sodium hydroxide and water, and continues to be stirred to raw material and mix, and obtains reacting alumino silica gel.Said silicon source is water glass, silicon sol; Said aluminium source is new system aluminium hydroxide, sodium aluminate;
(2) preparation of stable W/O microemulsion system: according to reacting alumino silica gel: oil: tensio-active agent: cosurfactant is (4-6): (12-25): (1-5): weight ratio (1-3), at first oil, tensio-active agent and cosurfactant are mixed 4-40 ℃ of following mechanical stirring, slowly add the reaction alumino silica gel then, and it is even to continue to be stirred to the raw material thorough mixing with this understanding, obtain the W/O microemulsion, said oil is hexanaphthene, sherwood oil; Said tensio-active agent is Triton X-100, sodium laurylsulfonate; Said cosurfactant is Pentyl alcohol, n-hexyl alcohol;
(3) crystallization of molecular sieve: the microemulsion of step 2 gained is changed in the autoclave pressure, and the sealing back was at 90-120 ℃ of following static crystallization 5-60 hour; Product is dried down at 120 ℃ after neutral through centrifugal, washing, obtains the A type molecular sieve sample.
2, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1, the mole proportioning that it is characterized in that reacting the raw material of alumino silica gel is 1Al
2O
3: (1-4) SiO
2: (2-4) Na
2O: (150-200) H
2O.
3, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1, it is characterized in that reacting in the W/O microemulsion system alumino silica gel: oil: tensio-active agent: cosurfactant is 5: 15: 3: 1.5 weight ratio.
4, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1 is characterized in that preparation feedback alumino silica gel and W/O microemulsion all at room temperature carry out.
5, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1 is characterized in that said oil is hexanaphthene in the preparation of W/O microemulsion, and tensio-active agent is a Triton X-100, and cosurfactant is a Pentyl alcohol.
6, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1, the crystallization that it is characterized in that molecular sieve are under 100 ℃ of temperature static crystallization 15-20 hour.
7, the method for a kind of synthesizing small-grain A-type molecular sieve as claimed in claim 1 is characterized in that said silicon source is a silicon sol in the step 1, and the aluminium source is a sodium metaaluminate.
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1295150C (en) * | 2003-11-20 | 2007-01-17 | 江西师范大学 | Nanometer A type molecular sieve preparation method |
| CN103043681A (en) * | 2013-01-16 | 2013-04-17 | 山西大学 | Preparation method of nano layered ZSM (Zeolite Molecular Sieve)-5 zeolite molecular sieve |
| CN107437615A (en) * | 2017-07-05 | 2017-12-05 | 东莞中汽宏远汽车有限公司 | High-capacity lithium battery negative pole and preparation method thereof and lithium battery |
| CN110228812A (en) * | 2018-03-06 | 2019-09-13 | 华东理工大学 | A kind of binderless A type sieve particle and preparation method thereof |
-
2001
- 2001-10-19 CN CNB011356863A patent/CN1162326C/en not_active Expired - Fee Related
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1295150C (en) * | 2003-11-20 | 2007-01-17 | 江西师范大学 | Nanometer A type molecular sieve preparation method |
| CN103043681A (en) * | 2013-01-16 | 2013-04-17 | 山西大学 | Preparation method of nano layered ZSM (Zeolite Molecular Sieve)-5 zeolite molecular sieve |
| CN103043681B (en) * | 2013-01-16 | 2014-12-10 | 山西大学 | Preparation method of nano layered ZSM (Zeolite Molecular Sieve)-5 zeolite molecular sieve |
| CN107437615A (en) * | 2017-07-05 | 2017-12-05 | 东莞中汽宏远汽车有限公司 | High-capacity lithium battery negative pole and preparation method thereof and lithium battery |
| CN110228812A (en) * | 2018-03-06 | 2019-09-13 | 华东理工大学 | A kind of binderless A type sieve particle and preparation method thereof |
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