CN101780417B - Catalyst for preparing paraxylene and low-carbon olefin by methyl alcohol conversion, preparation method and application thereof - Google Patents

Catalyst for preparing paraxylene and low-carbon olefin by methyl alcohol conversion, preparation method and application thereof Download PDF

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CN101780417B
CN101780417B CN2010101108689A CN201010110868A CN101780417B CN 101780417 B CN101780417 B CN 101780417B CN 2010101108689 A CN2010101108689 A CN 2010101108689A CN 201010110868 A CN201010110868 A CN 201010110868A CN 101780417 B CN101780417 B CN 101780417B
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catalyst
molecular sieve
transition metal
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rare earth
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CN101780417A (en
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许磊
李铭芝
刘中民
张莹
袁翠峪
张今令
欧书能
马跃龙
金阳
肖钢
郑长波
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Dalian Institute of Chemical Physics of CAS
CNOOC New Energy Investment Co Ltd
China National Offshore Oil Corp CNOOC
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Dalian Institute of Chemical Physics of CAS
CNOOC New Energy Investment Co Ltd
China National Offshore Oil Corp CNOOC
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P20/00Technologies relating to chemical industry
    • Y02P20/50Improvements relating to the production of bulk chemicals
    • Y02P20/52Improvements relating to the production of bulk chemicals using catalysts, e.g. selective catalysts
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P30/00Technologies relating to oil refining and petrochemical industry
    • Y02P30/20Technologies relating to oil refining and petrochemical industry using bio-feedstock
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P30/00Technologies relating to oil refining and petrochemical industry
    • Y02P30/40Ethylene production

Abstract

The invention discloses a catalyst for preparing paraxylene and low-carbon olefin by methyl alcohol conversion, a preparation method and application thereof. The catalyst provided by the invention is obtained by the method that a zeolite molecular sieve modified by transition metal and rare-earth metal is performed with the surface acidity and the pore structure modification by a siloxy group compound, wherein the transition metal is 0.1-10 wt% of the total weight of catalyst, the rare-earth metal is 0.1-5 wt% of total weight of the catalyst, and the modified siloxy group compound which is accounted by Si is 0.1-8 wt% of total weight of the catalyst; the catalyst can realize that methyl alcohol is used for directly preparing three basic chemicals in one reaction process, i.e. ethylene, propylene and paraxylene; the selectivity of the obtained hydrocarbon products in paraxylene is more than 80 wt%, and the selectivity of ethylene and propylene in C1-C5 is more than 80 wt%.

Description

A kind of methanol conversion prepares the Catalysts and its preparation method and the application of paraxylene and low-carbon alkene
Technical field
The present invention relates to a kind of technology, relate to a kind of Catalysts and its preparation method and application particularly by methyl alcohol highly-selective preparation paraxylene coproduction ethene, propylene by preparing low carbon olefinic hydrocarbon with methanol and aromatic hydrocarbons.
Background technology
Ethene, propylene and paraxylene are the base stocks of modern chemical industry.At present, toluene, C are mainly adopted in paraxylene production 9Aromatic hydrocarbons and mixed xylenes are raw material, produce through disproportionation, isomerization, adsorbing separation or cryogenic separation.Because the paraxylene content in its product is controlled by thermodynamics, paraxylene is at C 8Only account in the BTX aromatics about 20%, material circular treatment amount is big in the technical process, and equipment is huge, and operating cost is high.Particularly the boiling point of three isomers of xylenes differs very little, adopts common distillation technique can not obtain the high-purity paraxylene, and must adopt expensive adsorptive separation technology.Ethene and propylene be with crude refining light oil (naphtha and light diesel fuel) and liquefied petroleum gas (LPG) and the natural gas processing ethane and the propane that make be that raw material is produced.In recent years, domestic and international many patents disclose the new way that paraxylene is produced, the paraxylene that wherein alkylation of toluene can the production high selectivity, but said process all depends on petroleum resources.
It is the new way that non-petroleum path is produced ethene, propylene and aromatic hydrocarbons that preparing light olefins from methanol and methyl alcohol prepare aromatic hydrocarbons.Mobil Oil company in 1976 has carried out methyl alcohol is converted into hydrocarbon on the ZSM-5 molecular sieve catalyst reaction.USP 4,035, disclose methyl alcohol transforms gasoline on the ZSM-5 molecular sieve catalyst process in 430; USP4 discloses methyl alcohol is produced low-carbon alkene on the ZSM-5 molecular sieve catalyst technology in 542,252; USP 3,911,041, and USP 4; 049,573, USP 4,100; 219, JP 60-126233, JP 61-97231 discloses among JP 62-70324 and the EP 6501 and has used the reaction of the ZSM-5 molecular sieve catalyst of phosphorus, magnesium, silicon or alkali metal modification by preparing low carbon olefinic hydrocarbon with methanol; USP 5; 367; Disclose the reaction that Dalian Chemical Physics Research Institute uses the ZSM-5 molecular sieve catalyst of phosphorus and lanthanum modification to produce low-carbon alkene by methyl alcohol or dimethyl ether in 100, its ethene and propylene overall selectivity are merely about 65wt%, and ethene, propylene and butylene overall selectivity are greater than 85wt%.Chinese patent CN 101244969 discloses a kind of C 1-C 2The fluidized bed plant of hydro carbons or aromatization of methanol and catalyst regeneration utilizes this device and catalyst, can regulate the coking state of the catalyst in the aromatization reactor at any time, transforms C thereby reach continuous high-efficient 1-C 2Hydro carbons or methyl alcohol and high selectivity generate the purpose of aromatic hydrocarbons.Chinese patent CN 1880288 discloses a kind of process of methanol conversion for preparing arene, and on the modified zsm-5 zeolite catalyst, the methyl alcohol catalyzed conversion is for being main product with aromatic hydrocarbons, and the overall selectivity with aromatic hydrocarbons is high, the flexible process operation advantage.U.S. Pat 4615995 discloses a kind of ZSM-5 molecular sieve catalyst that has supported Zn and Mn, is used for methanol conversion and prepares alkene and aromatic hydrocarbons, can change the ratio of low-carbon alkene/aromatic compound in the product through the content of Zn in the regulating catalyst and Mn.
Above-mentioned methanol conversion prepares low-carbon alkene or aromatic hydrocarbons method, mainly concentrates on converting methanol to prepare low carbon olefin, methanol conversion is produced BTX aromatics, or converting methanol to prepare low carbon olefin by-product BTX aromatics.Methanol conversion principal product content is all lower in any method; Like ethylene, propylene poor selectivity in the converting methanol to prepare low carbon olefin product; The BTX aromatics market value that methyl alcohol directly transforms preparation is lower, thereby makes these technical process be difficult to application in industry.
Summary of the invention
The object of the present invention is to provide the catalyst of a kind of methanol conversion highly-selective preparation paraxylene and low-carbon alkene (ethene, propylene).Utilize this catalyst to can be implemented in the course of reaction purpose of directly producing three big Essential Chemistry article ethene, propylene and paraxylene by methyl alcohol.
Be to realize above-mentioned purpose, catalyst provided by the present invention, be by zeolite molecular sieve earlier after transition metal and rare earth metal bimetallic-modified, obtain through siloxy group is compound modified again;
In the said catalyst, said levels of transition metals is the 0.1-10% of said catalyst gross mass, and said rare earth metal content is the 0.1-5% of said catalyst gross mass, and said siloxy group compound is the 0.1-8% of catalyst gross mass in the loading of silicon.
Further, levels of transition metals is the 4-8% of said catalyst gross mass in the said catalyst, and rare earth metal content is the 2-5% of said catalyst gross mass, and said siloxy group compound is the 3-6% of catalyst gross mass in the loading of silicon.
Said transition metal can be selected from following any one: iron, cobalt, nickel, copper and zinc are preferably zinc or iron; Said rare earth metal can be lanthanum.
Catalyst provided by the present invention is to prepare according to the method that comprises the steps:
1) zeolite molecular sieve is prepared into acidic zeolite through ion-exchange, roasting;
2) acidic zeolite that step 1) is obtained flooded 0.5-12 hour in transition metal soluble-salt or transition metal dissolvable oxides solution, after the taking-up oven dry, at 450-650 ℃ of roasting 2-6 hour, obtained the molecular sieve of monometallic modification;
3) with step 2) molecular sieve of the monometallic modification that obtains in rare earth metal soluble-salt solution 0.5-12 hour, take out the oven dry back at 450-650 ℃ of roasting 2-6 hour, obtain the molecular sieve of bimetallic-modified;
The molecular sieve of the bimetallic-modified that 4) step 3) is obtained takes out the oven dry back at 450-650 ℃ of roasting 2-6 hour siloxy group compound dipping 0.5-12 hour, obtains said catalyst.
Wherein, the metal step 2) in transition metal soluble-salt and the said transition metal dissolvable oxides be selected from following any one: iron, cobalt, nickel, copper and zinc are preferably zinc or iron; The soluble-salt of rare earth metal described in the step 3) is the soluble-salt of lanthanum.
Zeolite molecular sieve described in the present invention is the alumino-silicate with crystallization skeleton structure, and its structure type is MFI type or MEL type; The zeolite molecular sieve of said MFI type is preferably ZSM-5, and the zeolite molecular sieve of said MEL type is preferably ZSM-11.
Said siloxy group structural general formula is suc as formula shown in the I:
Figure GSA00000030816500031
(formula I)
Wherein, R 1, R 2, R 3And R 4All be selected from C 1-C 10Alkyl; Preferred siloxy group compound is a tetraethyl orthosilicate among the present invention.
A further object of the present invention provides above-mentioned catalyst and prepares the application in paraxylene and the co-producing light olefins in methanol conversion.
The method that methanol conversion prepares paraxylene and coproduction ethylene, propylene is: adopt catalyst provided by the present invention, react with methanol feedstock, obtain paraxylene and ethene, propylene; Reactive mode can adopt any form of fixed bed or fluid bed; The condition of said reaction is: reaction temperature is 350-550 ℃, is preferably 400-500 ℃; Reaction pressure is 0-5MPa; The methanol feeding weight space velocity is 0.5-10h -1
The selectivity of paraxylene in aromatic hydrocarbons is greater than 80wt% in the hydrocarbon product of product, and ethylene, propylene is at C 1-C 5Middle selectivity is greater than 80wt%.
The specific embodiment
Catalyst of the present invention is to be that MFI or MEL alumino-silicate are active component with the structure type with crystallization skeleton structure; Through transition metal or its acidity of rare earth metal bimetallic modulation; Through silicone agent its outer surface acidity and duct are modified and be prepared into catalyst, its preparation process is following:
1) molecular screen primary powder is prepared into acidic molecular sieve through exchange, roasting.
2) molecular sieve is flooded transition metal and rare earth metal, obtain modified molecular screen.
4) use siloxy group reagent that modified molecular screen is carried out finishing, regulating catalyst outer surface acidity and pore structure obtain catalyst.
In above-mentioned preparation process, use oxide, the soluble-salt of transition metal and rare earth metal that zeolite molecular sieve is carried out modification, its purpose is to improve the arenes selectivity of catalyst methanol conversion reaction.Use siloxy group reagent that the molecular sieve of modification is carried out outer surface acidity and pore structure modification, its purpose is to improve the paraxylene selectivity of catalyst methanol conversion reaction.
Experimental technique described in the following embodiment like no specified otherwise, is conventional method; Said reagent and material like no specified otherwise, all can obtain from commercial sources; " wt% " expression quality percentage composition among the embodiment.
Through embodiment the present invention is detailed below, but the present invention is not limited to following examples.
Embodiment 1, Zn-La-HZSM-5 zeolite molecular sieve
1) with the former powder (SiO of ZSM-5 zeolite molecular sieve 2/ Al 2O 3=61, Fushun catalyst plant) remove template 550 ℃ of following roastings, in 80 ℃ of water-baths, exchange 4 times with 0.5 molar equivalent ammonium nitrate solution, exchange is then dried in 120 ℃ of air, and 550 ℃ of following roastings 3 hours obtain the HZSM-5 zeolite molecular sieve.
2) get the HZSM-5 zeolite molecular sieve 50g that step 1) prepares, use 10wt% concentration Zn (NO 3) 2Aqueous solution dipping 10 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Zn-HZSM-5 zeolite molecular sieve, wherein Zn loading 5wt%.
3) get Zn-HZSM-5 zeolite molecular sieve 20g, use the La (NO of 10wt% concentration 3) 3Aqueous solution dipping 10 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Zn-La-HZSM-5 zeolite molecular sieve, wherein La loading 3wt%.
Embodiment 2, Fe-La-HZSM-5 zeolite molecular sieve
1) with the former powder (SiO of ZSM-5 zeolite molecular sieve 2/ Al 2O 3=61, Fushun catalyst plant) remove template 550 ℃ of following roastings, in 80 ℃ of water-baths, exchange 4 times with 0.5 molar equivalent ammonium nitrate solution, exchange is then dried in 120 ℃ of air, and 550 ℃ of following roastings 3 hours obtain the HZSM-5 zeolite molecular sieve.
2) get the HZSM-5 zeolite molecular sieve 50g that step 1) prepares, use 12wt% concentration Fe (NO 3) 3Aqueous solution dipping 12 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Fe-HZSM-5 zeolite molecular sieve, wherein, and Fe loading 6wt%.
3) get Fe-HZSM-5 zeolite molecular sieve 20g, use the La (NO of 10wt% concentration 3) 3Aqueous solution dipping 10 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Fe-La-HZSM-5 zeolite molecular sieve, wherein La loading 3wt%.
The catalyst of embodiment 3, preparation methanol conversion highly-selective preparation paraxylene and low-carbon alkene
Use the silicone agent tetraethyl orthosilicate that Zn-La-HZSM-5, the Fe-La-HZSM-5 zeolite molecular sieve that embodiment 1 and embodiment 2 obtain carried out finishing:
(1) 10 gram Zn-La-HZSM-5 were put into 20 gram tetraethyl orthosilicates dippings 12 hours, incline liquid after, after 120 ℃ of oven dry,, obtain modifying back Zn-La-HZSM-5 zeolite molecular sieve 550 ℃ of roastings 3 hours, be numbered MTAC-11; Wherein, the mass content of Zn is 4.7%, and the mass content of La is 2.9%, and the loading of silicon is 4.2% of a catalyst gross mass.
(2) 10 gram Fe-La-HZSM-5 were put into 20 gram tetraethyl orthosilicates dippings 12 hours, incline liquid after, after 120 ℃ of oven dry,, obtain modifying back Fe-La-HZSM-5 zeolite molecular sieve 550 ℃ of roastings 3 hours, be numbered MTAC-12; Wherein, the mass content of Fe is 5.6%, and the mass content of La is 2.9%, and the loading of silicon is 4.3% of a catalyst gross mass.
Embodiment 4 fixed bed reaction evaluations
On fixed bed reactors, carry out the methanol conversion reaction, use the catalyst among the embodiment 3, reaction condition: the methyl alcohol weight space velocity is 2h -1, temperature is 450 ℃.Adopt gas-chromatography on-line analysis product (normalization behind the removal methyl alcohol), as shown in table 1.C wherein 1-C 5Composition analysis adopts the gas-chromatography off-line analysis, and the result is as shown in table 2.
Table 1, product analysis table
Catalyst MTAC-11 MTAC-12
Reaction temperature (℃) 450 450
Feed time (min) 30 30
Methanol conversion (%) 85.23 96.21
Paraxylene selectivity (%) * 83.42 83.58
Products distribution (%)
?C 1-C 5 48.31 47.32
Benzene 0.06 0.07
Ethylbenzene 0.24 0.3
Paraxylene 43.12 44.03
Meta-xylene 0.89 0.76
Ortho-xylene 1.18 1.09
?≥C 9 6.20 6.43
Add up to 100.00 100.00
*The selectivity of paraxylene in aromatic hydrocarbons
Table 2, product analysis table
Catalyst MTAC-11 MTAC-12
Reaction temperature (℃) 450 450
Feed time (min) 20-40 20-40
CH 4 2.12 2.36
C 2H 4 46.82 45.56
C 2H 6 0.21 0.28
C 3H 6 33.49 34.59
C 3H 8 0.45 0.43
C 4 + 11.72 12.01
C 5 + 5.19 4.77
Total 100.00 100.00
C 2H 4+C 3H 6 80.31 80.15
The catalyst of embodiment 5, preparation methanol conversion highly-selective preparation paraxylene and low-carbon alkene
With the former powder (SiO of ZSM-11 zeolite molecular sieve 2/ Al 2O 3=65, the Fushun catalyst plant) remove template 550 ℃ of following roastings, the ammonium nitrate solution with 0.5 molar equivalent in 80 ℃ of water-baths exchanges 4 times, and the exchange back obtains the HZSM-11 zeolite molecular sieve 550 ℃ of following roastings 3 hours.
Get HZSM-11 zeolite molecular sieve 50g, use 12wt% concentration Fe (NO 3) 3Aqueous solution dipping 12 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Fe-HZSM-5 zeolite molecular sieve, wherein Fe loading 8wt%.
Get Fe-HZSM-11 zeolite molecular sieve 20g, use the La (NO of 10wt% concentration 3) 3Aqueous solution dipping 12 hours after the oven dry, 550 ℃ of following roastings 3 hours, obtains the Fe-La-HZSM-11 zeolite molecular sieve, wherein La loading 5wt%.
Use the silicone agent tetraethyl orthosilicate that the Fe-La-HZSM-11 zeolite molecular sieve is carried out finishing.Step is respectively: 10 gram Fe-La-HZSM-11 are put into 20 gram tetraethyl orthosilicates dippings spend the night, incline liquid after, after 120 ℃ of oven dry; 550 ℃ of roastings 3 hours, obtain modifying back Fe-La-HZSM-11 zeolite molecular sieve, be numbered MTAC-13; Wherein, The mass content of Fe is 7.6%, and the mass content of La is 4.8%, and the loading of silicon is 4.4% of a catalyst gross mass.
Embodiment 6, fixed bed reaction evaluation
On fixed bed reactors, carry out the methanol conversion reaction, use the catalyst among the embodiment 5, reaction condition: the methyl alcohol weight space velocity is 4h -1, temperature is respectively 450 ℃ and 500 ℃.Adopt gas-chromatography on-line analysis product (normalization behind the removal methyl alcohol), as shown in table 3.C wherein 1-C 5Composition analysis adopts the gas-chromatography off-line analysis, and the result is as shown in table 4.
Table 3, product analysis
Figure GSA00000030816500071
*The selectivity of paraxylene in aromatic hydrocarbons
Table 4, product analysis

Claims (5)

1. a methanol conversion prepares the catalyst of paraxylene and co-producing light olefins, be by zeolite molecular sieve earlier after transition metal and rare earth metal bimetallic-modified, obtain through siloxy group is compound modified again;
In the said catalyst, said levels of transition metals is the 0.1-10% of said catalyst gross mass, and said rare earth metal content is the 0.1-5% of said catalyst gross mass, and said siloxy group compound is the 0.1-8% of catalyst gross mass in the loading of silicon;
Said low-carbon alkene is ethene and propylene;
Said zeolite molecular sieve is ZSM-5 or ZSM-11;
Said transition metal is zinc or iron; Said rare earth metal is a lanthanum;
Said siloxy group structural general formula is suc as formula shown in the I:
Figure FSB00000646860600011
(formula I)
Wherein, R 1, R 2, R 3And R 4Be ethyl.
2. catalyst according to claim 1; It is characterized in that: in the said catalyst; Said levels of transition metals is the 4-8% of said catalyst gross mass; Said rare earth metal content is the 2-5% of said catalyst gross mass, and said siloxy group compound is the 3-6% of catalyst gross mass in the loading of silicon; Said low-carbon alkene is ethene and propylene.
3. catalyst according to claim 1 and 2 is characterized in that: said catalyst prepares according to the method that comprises the steps:
1) zeolite molecular sieve is prepared into acidic zeolite through ion-exchange, roasting; Wherein, said zeolite molecular sieve is ZSM-5 or ZSM-11;
2) acidic zeolite that step 1) is obtained flooded 0.5-12 hour in transition metal soluble-salt or transition metal dissolvable oxides solution, after the taking-up oven dry, at 450-650 ℃ of roasting 2-6 hour, obtained transition metal modified molecular sieve; Wherein, the metal in said transition metal soluble-salt and the said transition metal dissolvable oxides is zinc or iron;
3) with step 2) the transition metal modified molecular sieve that obtains flooded 0.5-12 hour in rare earth metal soluble-salt solution, took out the oven dry back at 450-650 ℃ of roasting 2-6 hour, obtained the molecular sieve of transition metal and rare earth metal bimetallic-modified; Wherein, the said rare earth metal soluble-salt soluble-salt that is lanthanum;
The molecular sieve of the bimetallic-modified that 4) step 3) is obtained flooded 0.5-12 hour in the siloxy group compound, took out the oven dry back at 450-650 ℃ of roasting 2-6 hour, obtained said catalyst;
Said siloxy group structural general formula is suc as formula shown in the I:
Figure FSB00000646860600021
(formula I)
Wherein, R 1, R 2, R 3And R 4Be ethyl.
4. a method for preparing the said catalyst of claim 1 comprises the steps:
1) zeolite molecular sieve is prepared into acidic zeolite through ion-exchange, roasting; Wherein, said zeolite molecular sieve is ZSM-5 or ZSM-11;
2) acidic zeolite that step 1) is obtained flooded 0.5-12 hour in transition metal soluble-salt or transition metal dissolvable oxides solution, after the taking-up oven dry, at 450-650 ℃ of roasting 2-6 hour, obtained transition metal modified molecular sieve; Wherein, the metal in said transition metal soluble-salt and the said transition metal dissolvable oxides is zinc or iron;
3) with step 2) the transition metal modified molecular sieve that obtains flooded 0.5-12 hour in rare earth metal soluble-salt solution, took out the oven dry back at 450-650 ℃ of roasting 2-6 hour, obtained the molecular sieve of transition metal and rare earth metal bimetallic-modified; Wherein, the said rare earth metal soluble-salt soluble-salt that is lanthanum;
The molecular sieve of the bimetallic-modified that 4) step 3) is obtained flooded 0.5-12 hour in the siloxy group compound, took out the oven dry back at 450-650 ℃ of roasting 2-6 hour, obtained the said catalyst of claim 1;
Said siloxy group structural general formula is suc as formula shown in the I:
Figure FSB00000646860600022
(formula I)
Wherein, R 1, R 2, R 3And R 4Be ethyl.
5. each described catalyst prepares the application in paraxylene and the co-producing light olefins in methanol conversion among the claim 1-3.
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