CN104056654A - ZSM-5 molecular sieve composition, preparation method and application thereof - Google Patents

ZSM-5 molecular sieve composition, preparation method and application thereof Download PDF

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CN104056654A
CN104056654A CN201310093921.2A CN201310093921A CN104056654A CN 104056654 A CN104056654 A CN 104056654A CN 201310093921 A CN201310093921 A CN 201310093921A CN 104056654 A CN104056654 A CN 104056654A
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molecular sieve
zsm
roasting
catalyst
powder
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CN104056654B (en
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李明罡
张巍
王萍
王殿中
罗一斌
慕旭宏
舒兴田
汪燮卿
刘建强
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Sinopec Research Institute of Petroleum Processing
China Petroleum and Chemical Corp
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Sinopec Research Institute of Petroleum Processing
China Petroleum and Chemical Corp
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Abstract

An ZSM-5 molecular sieve composition is characterized in that the molecular sieve composition comprises 0.1-10 wt% of phosphorus on a basis of P2O5, and 0-10 wt% of rare earth on a basis of oxide; in the ZSM-5 molecular sieve, the content of alkali metal is less than 0.2 wt% on a basis of oxide, the mole ratio of SiO2 to Al2O3 is 100-1000, the BET-method specific surface area determined by a nitrogen adsorption method is 300-600 m2/g, the total pore volume is 0.2-0.6 mL/g, and the pore volume of mesopores with a pore diameter more than 2 nm accounts for 30-70% of the total pore volume. The molecular sieve composition is beneficial to the improvement of selectivity of target product propylene in reaction of preparing light olefin from methanol.

Description

A kind of ZSM-5 molecular sieve composition, preparation method and application thereof
Technical field
The present invention relates to a kind of ZSM-5 molecular sieve composition, preparation method and application thereof, the present invention relates to furtherly a kind of ZSM-5 molecular sieve composition, preparation method and application thereof of phosphorous and rare earth.
Background technology
Propylene is important Organic Chemicals, along with increasing rapidly of the derivative demands such as polypropylene, the demand of propylene is also risen year by year.In the tradition source of production of propylene, approximately 70% from cracking petroleum hydrocarbon vapor technique, separately has 28% from heavy oil catalytic cracking process, all relies on petroleum resources.The significantly rising of the decline of oil production capacity and global oil price forces researcher to develop new alternative energy source and new process is carried out production bulk chemical.Ripe and realize large-scale industrial production to methanol conversion technology through synthesis gas by coal, natural gas, living beings etc., be that catalytic material dehydration preparing low-carbon olefins (MTO) and preparing propylene from methanol (MTP) technology are the novel alkene production technologies that is hopeful to replace petroleum path most by methyl alcohol.The research of methanol-to-olefins technology, exploitation, industrialization become the focus of international each major oil companies technological development in recent years.
From Mobil company of the U.S. in 1984 report by after preparing gasoline by methanol process modification for preparing light olefins from methanol (MTO) (Chang, C D etc., J.Catal., SB, 289 (1984)) after, many zeolites or molecular sieve are used as the catalyst of MTO reaction, through screening study for many years, mainly concentrate at present two molecular sieve analog catalyst.Wherein a class concentrates on as the mesopore zeolite of ZSM-5 zeolite etc.USP3911041 discloses and has adopted that to make methanol conversion at least about the ZSM-5 zeolite of 0.78 % by weight phosphorus modification, at 300-700 DEG C of temperature be alkene.USP4049573 and 4088706 discloses by the oxide of boron or magnesium, or further adds phosphorous oxides modified ZSM-5 zeolite, and under 250-700 DEG C and 0.2-30 atmospheric pressure, making methanol conversion is alkene.USP4480145 discloses the diffusivity of the silica filling reduction zeolite of use large crystal ZSM-5-5 zeolite and zeolite pores, can improve the ethylene yield of methanol conversion.This patent also discloses by hydrothermal treatment consists at 180-820 DEG C and has reduced zeolite alpha active to 6-10, can improve cycle life and the methanol conversion activity of zeolite.USP4549573 discloses while methanol conversion being hydro carbons under 350-700 DEG C and 1-100 atmospheric pressure, uses constraint factor for the zeolite that 1-12 and silica/alumina mole ratio are 298-2000, can improve the productive rate of light olefin.
The another kind of important catalyst that is alkene for methanol conversion is SAPO (SAPO) family molecular sieves.This family molecular sieves is invented (USP4440871) in the early 1980s by associating carbon compound company of the U.S. (UCC), wherein SAPO-34 molecular sieve has represented preferably catalytic performance of methanol-to-olefins, but the rich ethene that produces in this product, yield of ethene reaches 53.8%, propylene is 29.1%, P/E lower than very (USP5817906).Recently be reported in Propylene Selectivity in methanol to olefins reaction and reach 45.4%, ethylene contents is still very high, and P/E (propylene/ethylene) weight ratio is less than 1.45 (USP6710218).SAPO Series Molecules sieve catalyst aperture is little, easily coking, and in product component, P/E, than low, is not suitable for MTP technique.
Last century the nineties, the ZSM-5 molecular sieve of Lurgi company of Germany based on modification developed a set of complete MTP technique, adopt portion of product alkene circular response mode, Propylene Selectivity reaches 71.2% (PEPReview98-13), makes to cause again researcher's concern about preparing propylene from methanol technology on ZSM-5 molecular sieve.
CN1431982A discloses the method with preparing propylene from methanol, after methyl alcohol partial dehydration, enter series connection fixed bed reactors, utilize the mode of portion of product circulation to make methanol conversion for light olefin, used catalyst is ZSM-5 zeolite catalyst, and its alkali metal content is less than 380ppm.The ZnO content of described catalyst is less than 0.1 % by weight, and CdO content is less than 0.1 % by weight, and BET surface area is 300 to 600m 2/ g, pore volume is that 0.3 to 0.5mL/g(mercury injection method is measured).The more detailed preparation method of this catalyst, referring to US05063187 and US07229941, is 0.1-0.9 μ m(US05063187 by the elementary crystallite dimension of Hydrothermal Synthesis) or 0.01-0.1 μ m(US07229941) ZSM-5 zeolite be dispersed in the alumina binder that accounts for catalyst 10-40% and prepare.
CN1084431A discloses and has a kind ofly produced phosphorous, the rare earth element of light olefin process and the ZSM-5 type zeolite catalyst of pore structure conditioning agent and adopt dehydration reactor and the regenerate course of reaction of multistage insulation fixed bed cracking reactor of handover operation of 2~n reaction one for methyl alcohol or dimethyl ether, at high temperature (>400 DEG C) once-through operation, be on day device of processing methyl alcohol 0.7-1 ton in scale, methanol conversion 100%, C 2~C 4olefine selective can be greater than 85%, and can be greater than 600 hours the online duration of runs, and the one-pass operation cycle can be greater than 24 hours.Wherein ZSM-5 zeolite silica alumina ratio is 40-80, and catalyst phosphorus content is 0.7-5%, and lanthanum or lanthanum rich mischmetal content are 0.9-6.5%.
CN1352627A discloses the catalyst that methyl alcohol or dimethyl ether is selectively converted to light olefin, employing has the zeolite of 10 ring cross aisles as ZSM-5 zeolite and ZSM-11 zeolite, by add phosphorus-containing compound hydrothermal treatment consists to make and in the time measuring under 120 DEG C and 8kPa zeolite the diffusion parameter of 2,2-dimethylbutane is less than to 100s -1, use catalyst prepared by this zeolite for the reaction of methanol conversion, in the time that 370-480 DEG C, methyl alcohol dividing potential drop are 30-150PSia, the conversion per pass of methyl alcohol is less than 95%, due to the selective raising of diffusion-restricted to ethene.
The disclosed use moving bed technique of CN1803738A and the method that independently heavy alkene shift step is propylene by transforming oxygenated organic compound, preferably use ZSM-5 molecular sieve catalyst, in oxygenate conversion reaction step, use moving-burden bed reactor technology, replace the bed technology of prior art; Adopt independently heavy alkene shift step, make the reaction temperature in oxygenate conversion reaction step reduce by 15 DEG C; Limiting catalyst <700 hour circulation timei; Product ethene returns to oxygenate conversion reactor, reduce the green coke on catalyst, make the conversion ratio of activity, oxygenatedchemicals of catalyst and Propylene Selectivity substantially close to or remain on catalyst initial cycle level, thereby significantly improved oxygenatedchemicals and be converted into the average propylene circulation productive rate of propylene.
CN101172246A discloses the preparation method of propylene catalyst from methanol conversion.By roasting after be 20-1000 by silica alumina ratio ZSM-5 molecular sieve and adhesive mixed-forming, with be selected from acid solution or the ammonium salt solution of at least one in hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid or tartaric acid and exchange rear roasting, experiencing temperature is the steam treatment of 400-700 DEG C again, and then makes modified molecular sieve catalyst with being selected from the rear roasting of at least one acid solution dipping in oxalic acid, citric acid, phosphoric acid or tartaric acid.When this catalyst is evaluated for preparing propylene by methanol transformation, methanol conversion can reach 100%, and propene yield reaches 47.1%, P/E ratio higher than 6.
CN101172918A discloses after methyl alcohol first contacts with aluminium oxide catalyst and has contacted two sections of method for transformation realizing preparing propylene from methanol with above-mentioned catalyst again.
CN101429085A discloses the method for preparing propylene, ethylene light olefin hydrocarbon from methanol/dimethyl ether, used catalyst is the binderless ZSM-5 molecular sieve of silica alumina ratio >50,0.01-10% rare earth and the modification of 0.01-10% phosphorous oxides, comprises ZSM-5, ZSM-11, ZSM-23, ZSM-48 or its mixture.
CN101239326A discloses the preparation method of propylene catalyst from methanol conversion.The former powder of the ZSM-5 molecular sieve roasting in air atmosphere that is 20~1000 by silica alumina ratio, remove the roasting after at least one the acid solution exchange being selected from hydrochloric acid, nitric acid, sulfuric acid or phosphoric acid for the former powder of ZSM-5 molecular sieve of segment template agent, contact rear roasting with at least one aqueous slkali being selected from alkali metal hydroxide or alkali carbonate again, then make required catalyst with roasting after at least one exchange being selected from nitric acid, hydrochloric acid, phosphoric acid or sulfuric acid.Gained catalyst is at 470 DEG C, and methyl alcohol weight space velocity is 1h -1, methyl alcohol dividing potential drop is greater than under the methanol conversion condition of 70 kPas, and Propylene Selectivity is greater than 40%, and ethylene selectivity is less than 5%, P/E (propylene/ethylene weight) than being greater than 9.
CN101279282A discloses the ZSM-5 molecular sieve Catalysts and its preparation method for preparing propylene from methanol.After the ZSM-5 mesopore molecular sieve of silica alumina ratio 20-1000 is mixed with the binding agent that is selected from silica, clay or aluminium oxide by mass fraction 20-100%, extrusion, compressing tablet or spray ball forming; Then at least one acid solution in being selected from hydrochloric acid, nitric acid, sulfuric acid or acetic acid regulates the ammonium salt solution of pH value to contact, product after temperature 400-700 DEG C of Water Under steam treatment by least one solution impregnation in being selected from oxalic acid, citric acid or maleic acid.Gained modified molecular sieve catalyst is 500 DEG C of reaction temperatures, methyl alcohol air speed 4h -1under condition, methanol conversion 100%, propene yield can reach 47%, P/E ratio and exceed 6.The disclosed catalyst of CN101279280A similarly.
High stability molecular sieve catalyst of the disclosed preparing propylene by methanol transformation of CN101279281A and preparation method thereof is 20-1000 by silica alumina ratio, and percentage by weight is counted the former powder of ZSM-5 molecular sieve of 25-99.9% and is selected from SiO 2, clay, A1 2o 3in at least one binding agent through extrusion, compressing tablet or spray ball forming; Process at temperature 20-90 DEG C through being selected from ammonium nitrate, ammonium chloride, ammonium sulfate the ammonium salt solution of at least one or being selected from the acid solution of at least one in hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, acetic acid again; Then counting with percentage by weight at least one solution that 0.1-5% is selected from lanthanum, cerium nitrate or chloride is to process under 20-90 DEG C of condition in temperature; At temperature 400-700 DEG C of Water Under steam treatment 2-15 hour; With being selected from, in oxalic acid, citric acid, phosphoric acid, maleic acid, at least one floods to obtain required modified molecular sieve catalyst again.This catalyst reacts for preparing propylene by methanol transformation, 470 DEG C of reaction temperatures, and methyl alcohol air speed 1 hour -1under condition, methanol conversion can reach 100%, and propene yield exceedes 45%, and the life-span reaches as high as 850 hours.
CN101306381A discloses a kind of ZSM-5 molecular sieve Catalysts and its preparation method of preparing propylene by methanol transformation.After the binding agent that the ZSM-5 molecular sieve of silica alumina ratio 20-1000 is selected to silica, clay or aluminium oxide according to the mass fraction 20-99.8% meter that accounts for catalyst and at least one mixes, extrusion, compressing tablet or spray ball forming; Then at least one acid solution in being selected from hydrochloric acid, nitric acid, sulfuric acid or acetic acid regulates the ammonium salt solution contact of pH value, then be selected from least one nitrate or the chloride solution contact in barium, magnesium or calcium with weight percent meter 0.01-5%, be then selected from phosphoric acid, metavanadic acid with weight percent meter 0.01-5% and contact by least one salting liquid in, ammonium molybdate or ammonium tungstate; Product after temperature 400-700 DEG C of Water Under steam treatment by least one solution impregnation in being selected from oxalic acid, citric acid or maleic acid.Gained modified molecular sieve catalyst is 470 DEG C of reaction temperatures, methyl alcohol air speed 1h -1under condition, methanol conversion 100%, propene yield can reach 45%, and the life-span reaches 800 hours, has improved that Propylene Selectivity is low, molecular sieve heat endurance and hydrothermal stability, is difficult for coking and deactivation.The disclosed preparing propylene from methanol ZSM-5 of CN101279283A catalyst further the grain size limits of ZSM-5 molecular sieve in 0.2-1 micrometer range.
CN101347743A discloses high propylene/ethylene than the preparation method of propylene catalyst from methanol conversion.Adopt first and process the former powder of ZSM-5 molecular sieve with at least one aqueous slkali being selected from NaOH, magnesium hydroxide, potassium hydroxide, calcium hydroxide, sodium carbonate or sodium acid carbonate, then be selected from least one the acid solution processing in hydrochloric acid, nitric acid, sulfuric acid or acetic acid, again after temperature is 400-700 DEG C of steam treatment with binding agent mixed-forming, roasting after, with being selected from least one solution impregnation in oxalic acid, citric acid, phosphoric acid or tartaric acid, after roasting, obtain ZSM-5 Type Zeolites agent again.This catalyst makes material benzenemethanol conversion ratio can reach 100%, and propene yield can reach 48.2%, P/E weight ratio can reach 10.
CN101234353A discloses a kind of preparing propylene from methanol catalyst, to account for the cerium modified H-ZSM-5 molecular sieve of molecular sieve mass ratio as 0.005-0.15, for preparing propylene from methanol reaction, reaction condition is temperature 300-500 DEG C, pressure is 0-1Mpa, and liquid hourly space velocity (LHSV) is 0.1-10h -1.
CN101176849A discloses a kind of catalyst and preparation method who is prepared propylene by methyl alcohol or dimethyl ether in high selectivity.Adopt rare earth element stable molecule sieve structure, alkaline matter to change surface acidity and online silanization the duct mode such as modify is carried out to modification to active constituent ZSM-5 molecular sieve catalyst, the spray-dried catalyst for fluidized-bed reaction of preparing high selectivity and produce propylene; The composition of this catalyst is pressed following percentage by weight: rare earth 0.1-8%, and alkaline modifier 0.5-30%, binding agent 20-80%, silanization silicone content 0.05-10%, all the other are ZSM-5 molecular sieve.
CN101433858A discloses a kind of HZSM-5 molecular sieve catalyst of producing propylene from methanol/dimethyl ether, employing accounts for the W elements modification HZSM-5 molecular sieve catalyst that molecular sieve mass fraction is 0.005-10%, for preparing propylene from methanol reaction, reaction condition is temperature 300-500 DEG C, pressure is 0-1Mpa, and liquid hourly space velocity (LHSV) is 0.1-10h -1.
CN101624192A discloses the HZSM-5 molecular sieve catalyst for a kind of producing propylene from methanol/dimethyl ether, and the silica alumina ratio of this ZSM-5 molecular sieve is 250-1150, and particle diameter is 65-250nm.The preparation method of this molecular sieve comprises aluminium source is mixed with organic directed agents, adds silicon source to become gel with organic additive, then hydrothermal crystallizing 24-240h at 60-200 DEG C.Wherein organic additive and SiO 2mol ratio be 0.5-8, kind is one or more in methyl alcohol, ethanol, acetone and polyvinylpyrrolidone.
CN102050691A discloses the method for preparing low-carbon alkene with coupling between methanol carbon 4 hydrocarbon, and adopting the phosphorous modified ZSM-5 molecular sieve that silica alumina ratio is 15-80 is catalyst.
CN101780417A discloses the catalyst of a kind of methanol conversion paraxylene processed and low-carbon alkene, by transition metal and rare-earth metal modified after ZSM-5 molecular sieve prepare through the compound-modified surface acidity of siloxy group and pore structure again, the 0.1-10% that wherein levels of transition metals is catalyst is heavy, rare earth metal content is that the 0.1-5% of catalyst is heavy, and the 0.1-8% that siloxy group compound accounts for catalyst in Si is heavy.
CN102125866A discloses a kind of H-ZSM-5 molecular sieve catalyst for preparing propylene from methanol, evaporates part moisture when by Hydrothermal Synthesis molecular sieve initiation material and forms and carry out the crystallite dimension that crystallization directional preparation obtains after gel and be less than 300nm, specific area 380-420m 2the H-ZSM-5 molecular sieve of/g, silica alumina ratio 80-100.
Summary of the invention
Although adopted very complicated preparation were established, such as adding in the initial reactant of synthesis of molecular sieve organically or inorganic assistant, adopt the methods such as the siloxy group of high price is compound modified to synthesize and modified zsm-5 zeolite, but it still have much room for improvement for process for preparing propylene from methanol gained olefine selective.Inventor is surprised to find that on the basis of a large amount of ZSM-5 molecular sieve development tests, process after the ZSM-5 molecular sieve of low sodium content when adopting fluosilicic acid hydro-thermal method, again with phosphorous and carry out the combination of molecular sieve obtaining after activation processing containing earth solution, there is special pore structure and distribute, more unexpectedly, when using its active component as MTP catalyst, in keeping methyl alcohol high conversion, propylene/ethylene mass ratio is significantly improved, and based on this, forms the present invention.
The object of the invention is to provide on the basis of existing technology a kind of ZSM-5 molecular sieve composition with special pore structure feature.
Second object of the present invention is to provide a kind of preparation method of this ZSM-5 molecular sieve composition.
The 3rd object of the present invention is to provide a kind of method of Methanol light olefin.
ZSM-5 molecular sieve composition provided by the invention, is characterized in that this combination of molecular sieve contains with P 2o 5the phosphorus of the 0.1-10 % by weight of meter and in the rare earth of the 0-10 % by weight of oxide, in said ZSM-5 molecular sieve, alkali metal is less than 0.2 % by weight, SiO in the content of oxide 2with A1 2o 3molar ratio be 100-1000, nitrogen adsorption method measure under BET method specific area be 300-600m 2/ g, total pore volume is 0.2-0.6mL/g, the mesoporous pore volume of bore dia >2nm accounts for the 30-70% of total pore volume.
The present invention also provides the preparation method of above-mentioned said ZSM-5 molecular sieve composition, it is characterized in that, the method comprises that former the ZSM-5 molecular sieve of alkali metal-free or low alkali powder is removed to organic formwork agent through roasting obtains roasting powder, roasting powder carries out liquid phase acid treatment and obtains pickling filter cake, and, said pickling filter cake carries out reclaiming the step that obtains ZSM-5 molecular sieve composition after the activation processing of phosphorus-containing compound and compounds containing rare earth, wherein, it is that roasting powder and the acidic aqueous solution making beating that contains fluosilicic acid are evenly become to molecular sieve pulp that said roasting powder carries out step that liquid phase acid treatment obtains pickling filter cake, and in airtight still temperature 100-200 DEG C, hydrothermal treatment consists under pressure 0.1-2Mpa, the mass ratio of the butt of said fluosilicic acid and said roasting powder is 0.0001-0.1:1, in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 3-20:1.
The method of the Methanol light olefin (C2-C4 alkene, object product are propylene) the present invention further provides, the active component of the method taking above-mentioned ZSM-5 molecular sieve composition as catalyst.
The present invention, by adopting the alkali metal-free of removed template method or the ZSM-5 molecular sieve of low alkali to process and introduce the activation processing process of the hetero atom such as phosphorus or phosphorus and rare earth etc. under fluosilicic acid hydrothermal condition, makes ZSM-5 molecular sieve have high mesoporous pore volume and suitable acidity.In reaction at Methanol for light olefin, the ZSM-5 molecular sieve composition of high mesoporous pore volume and appropriate acid is conducive to improve the diffusion rate of reactant methanol and product light olefin, be conducive to suppress the intermediate product such as propylene, butylene light olefin in the reaction of methanol dewatered propylene the side reactions such as hydrogen migration, superimposed, condensation green coke further occur, improve the selective of object product propylene; And can improve the appearance charcoal amount of catalyst, improve the anti-coking deactivation ability of catalyst, the single pass life of extending catalyst.
Brief description of the drawings
Accompanying drawing 1 is the XRD diffraction pattern of the ZSM-5 molecular sieve composition of embodiment 1.
Accompanying drawing 2 is the MTP reaction life assessment result of embodiment 8 and comparative example 2 catalyst.
Detailed description of the invention
ZSM-5 molecular sieve composition provided by the invention, is characterized in that this combination of molecular sieve contains with P 2o 5the phosphorus of the 0.1-10 % by weight of meter and in the rare earth of the 0-10 % by weight of oxide, in said ZSM-5 molecular sieve, alkali metal is less than 0.2 % by weight, SiO in the content of oxide 2with A1 2o 3molar ratio be 100-1000, nitrogen adsorption method measure under BET method specific area be 300-600m 2/ g, total pore volume is 0.2-0.6mL/g, the mesoporous pore volume of bore dia >2nm accounts for the 30-70% of total pore volume.
In said composition, said phosphorus is with P 2o 5meter, preferred content are 0.2-5 % by weight, and said rare earth is taking oxide, preferred content as 0-5 % by weight.Said alkali metal in oxide, preferred content for being less than 0.1 % by weight, said SiO 2with A1 2o 3molar ratio be preferably 150-500, said nitrogen adsorption method measure under BET method specific area be preferably 350-500m 2/ g, total pore volume is preferably 0.3-0.5mL/g, and the mesoporous pore volume of its median pore diameter >2nm preferably accounts for the 40-60% of total pore volume.
In said composition, said rare earth is one or more in yttrium, lanthanum, cerium and praseodymium preferably, and preferred rare earth element is lanthanum and/or cerium.
The preparation method of ZSM-5 molecular sieve composition provided by the invention, is characterized in that, the method comprises that former the ZSM-5 molecular sieve of alkali metal-free or low alkali powder is removed to organic formwork agent through roasting obtains roasting powder, roasting powder carries out liquid phase acid treatment and obtains pickling filter cake, and, said pickling filter cake carries out reclaiming the step that obtains ZSM-5 molecular sieve composition after the activation processing of phosphorus-containing compound and compounds containing rare earth, wherein, it is that roasting powder and the acidic aqueous solution making beating that contains fluosilicic acid are evenly become to molecular sieve pulp that said roasting powder carries out step that liquid phase acid treatment obtains pickling filter cake, and in airtight still temperature 100-200 DEG C, hydrothermal treatment consists under pressure 0.1-2Mpa, the mass ratio of the butt of said fluosilicic acid and said roasting powder is 0.0001-0.1:1, in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 3-20:1
In said method, (alkali metal mainly refers to sodium or potassium for said alkali metal-free or low alkali content, be less than 0.2 % by weight in oxide) the former powder of ZSM-5 molecular sieve can derive from multiple channel, such as being commercially available, such as alkali metal obtains through ammonium exchange, what preferably under the sial system of alkali metal-free or low alkali, Hydrothermal Synthesis obtained.Under the sial system of said alkali metal-free or low alkali, to obtain the process of the former powder of ZSM-5 molecular sieve be that aluminium source, silicon source, water and organic formwork agent are thoroughly mixed to form to reactant mixture to Hydrothermal Synthesis, by reactant mixture under agitation, under the temperature of 70~200 DEG C, self-generated pressure hydrothermal crystallizing 20~200 hours, crystallization product after filtration, washing, dry, mole compositing range of said reactant mixture is organic formwork agent/SiO 2=0.03-0.3, SiO 2/ Al 2o 3=100-1000, H 2o/SiO 2=5-30, wherein, said aluminium source is selected from hydrated alumina, aluminum sulfate, aluminum nitrate, aluminium hydroxide, aluminium isopropoxide; Said silicon source is selected from the solid silicon source such as solid silicone, white carbon; Said organic formwork agent is tetraethyl ammonium hydroxide or TPAOH.
Said roasting removes the organic formwork agent in the former powder of ZSM-5 molecular sieve, obtains the step of ZSM-5 molecular sieve roasting powder, and roasting condition is preferably ingress of air roasting 0.5-50h at 300-800 DEG C.
Said roasting powder carries out liquid phase acid treatment and obtains pickling filter cake, say more specifically roasting powder is evenly become to molecular sieve pulp with the acidic aqueous solution making beating that contains fluosilicic acid, and under temperature 100-200 DEG C, pressure 0.1-2Mpa, process in airtight still, conventionally process 0.5-30h; In a preferred embodiment, said roasting powder and the acidic aqueous solution making beating that contains fluosilicic acid are evenly become to molecular sieve pulp, and the temperature of processing in airtight still is that 105-180 DEG C, pressure are 0.11-1Mpa, more preferably temperature 105-150 DEG C, pressure 0.12-0.7Mpa.The mass ratio of the butt of said fluosilicic acid and said roasting powder is 0.0001-0.1, preferably 0.001-0.05, more preferably 0.002-0.01, and in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 3-20, preferred 4-15, more preferably 5-10.After said processing, through being cooled to lower than 80 DEG C, pressure release to normal pressure, by products therefrom after filtration, obtain alkali metal content in oxide, for example Na 2the pickling filter cake of O content <0.2 % by weight.The said acidic aqueous solution that contains fluosilicic acid also can further contain one or more that are selected from hydrochloric acid, sulfuric acid, nitric acid, phosphoric acid and oxalic acid etc.
Said activation processing of ZSM-5 molecular sieve pickling filter cake being carried out to phosphorus-containing compound and compounds containing rare earth, by water-soluble the soluble inorganic phosphor-contained compound of required amount of calculation, become activator with the aqueous solution containing the soluble salt that is selected from one or more rare earth elements in yttrium, lanthanum, cerium and praseodymium of required amount of calculation, activator is mixed to then dry, roasting at 80-800 DEG C of temperature with the making beating of ZSM-5 molecular sieve pickling filter cake.Said soluble inorganic phosphor-contained compound is selected from one or more mixtures in phosphoric acid, ammonium phosphate, diammonium hydrogen phosphate, ammonium dihydrogen phosphate (ADP); The aqueous solution of the soluble salt of said rare earth element is selected from the soluble salt of yttrium, lanthanum, cerium or praseodymium element, for example, comprise chloride, nitrate etc.
ZSM-5 molecular sieve composition provided by the invention can be in the method for methanol dewatered light olefin, particularly propylene as the active component of catalyst.Said ZSM-5 molecular sieve composition and inorganic oxide binder are mixed with as preformed catalyst, pellet catalyst, the bar shaped catalyst of extruded moulding or the microspherical catalyst of spray shaping of the moulding of for example rolling.Inorganic oxide binder, clay etc. in the composition of said preformed catalyst, are also comprised, wherein, ZSM-5 molecular sieve composition of the present invention accounts for 30-95 % by weight, preferred 50-90%, binding agent accounts for 5-70 % by weight, preferred 10-50 % by weight in inorganic oxide, and clay accounts for 0-50 % by weight, preferred 0-30 % by weight.The example of said inorganic oxide binder includes but not limited to following kind: the mixture of one or more in aluminium oxide, silica, aluminum phosphate, amorphous aluminum silicide, zirconia and titanium oxide.Its precursor of said aluminium oxide comprises aluminium colloidal sol, polymeric aluminum chloride, boehmite and boehmite etc.; Its precursor of said silica comprises silester, Ludox etc.The material that said clay comprises artificial synthetic or natural generation, as one or more the mixture in kaolin, kaolinite, montmorillonite, talcum and bentonite, also can be the product after peracid or the processing of alkali treatment process by above-mentioned clay, preferred clay be kaolin and the product through acid or alkali treatment thereof.
In the method for said Methanol light olefin, material benzenemethanol can be refining and moisture not refining methyl alcohol, in course of reaction, can add steam or inert gas regulates methanol feeding dividing potential drop, reaction temperature used is 250 DEG C-600 DEG C, is preferably 350 DEG C-500 DEG C; Reaction pressure used is 0.1-50 atmospheric pressure, preferred 0.5-5 atmospheric pressure, and weight space velocity used (WHSV) is 0.01-50h -1, be preferably 0.1-10h -1.
Below by embodiment, the invention will be further described, but content not thereby limiting the invention.
In each embodiment and comparative example, the X-ray powder diffraction of molecular sieve mensuration instrument is German Bruker D5005 diffractometer, adopts CuK alpha ray; Molecular sieve chemical composition x-ray fluorescence spectrometry.N 2adsorption analysis adopts U.S. Micromeritics ASAP2400 adsorption instrument to measure, the wherein mesoporous pore volume of >2nm=total pore volume-Micropore volume.
Raw materials used except special instruction in embodiment, be chemically pure reagent.
Example 1-4 illustrates ZSM-5 molecular sieve composition provided by the invention and preparation process thereof.
Embodiment 1
7.8 kilograms of dry glue powders (are weighed to Al containing 74% 2o 3sinopec catalyst Chang Ling branch company produces, lower same) join 1694 kilograms of TPAOH aqueous solution (containing 20% heavy TPAOH) dissolving, then (Qingdao Marine Chemical Co., Ltd. produces to add 577 kilograms of solid silicones, lower same), be uniformly mixed 2 hours.Mole consisting of of gained reactant mixture: TPAOH/SiO 2=0.2, SiO 2/ Al 2o 3=140, H 2o/SiO 2=9.5.Pack reactant mixture into stainless steel crystallizing kettle, crystallization 90 hours under 130 DEG C, continuous stirring and self-generated pressure.Then crystallization product filtered, washed and dry 16h at 120 DEG C, obtaining molecular screen primary powder product A 1.
Above-mentioned dry former powder A1, as in Muffle furnace, in 550 DEG C of roasting 6h, is obtained to roasting molecular sieve powder A2.
Get the 400 kilograms of above-mentioned roasting molecular sieve of butt powder A2 and join 2800 kilograms of deionized water for stirring making beating, then add 8.84 kilograms of fluorine silicic acid aqueous solutions (containing 30% fluosilicic acid, lower same), being placed in exchange still seals, continuing to be warming up to 130 DEG C under stirring, under still is pressed as 0.28Mpa, keep 1h, be then cooled to 70 DEG C of filtrations, washing, obtain filter cake product A 3.
14.17 kilograms of ammonium dihydrogen phosphate (ADP)s are dissolved in 300 kilograms of deionized waters, add the 350 kilograms of above-mentioned molecular sieve filter cake of butt A3 stirring to pulps even, then slurries are dried to 16h at 140 DEG C, obtain combination of molecular sieve product A 4 of the present invention.
Get the above-mentioned zeolite product A4 of part, measure through X-ray powder diffraction, its result, as shown in diffraction pattern in Fig. 1, illustrates that it is ZSM-5.Through XRF analysis, Na in A4 molecular sieve 2o content is 0.04%, P 2o 5content is 2.69%, and silica alumina ratio is 158.Through low temperature N 2-adsorption analysis, the BET method specific area of A4 molecular sieve is 469m 2/ g, total pore volume is 0.393mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.203mL/g, and accounting for total pore volume ratio is 51.4%.
Embodiment 2
4.5 kilograms of dry glue powders and 1271 kilograms of TPAOH aqueous solution (are contained to 20% heavy TPAOH, Sinopec catalyst Jian Chang branch company produce) pack into stainless steel crystallizing kettle dissolve, add again 260 kilograms of deionized waters and 577 kilograms of solid silicones, be uniformly mixed 2 hours.Mole consisting of of gained reactant mixture: TPAOH/SiO 2=0.15, SiO 2/ Al 2o 3=180, H 2o/SiO 2=9.By reactant mixture crystallization 75 hours under 140 DEG C, continuous stirring and self-generated pressure.Then crystallization product filtered, washed and dry 16h at 120 DEG C, obtaining molecular screen primary powder product B 1.
Above-mentioned dry former powder B1, as in Muffle furnace, in 550 DEG C of roasting 4h, is obtained to roasting molecular sieve powder B2.
Get the 200 kilograms of above-mentioned roasting molecular sieve of butt powder B2 and join 1800 kilograms of deionized water for stirring making beating, then add 2.97 kilograms of fluorine silicic acid aqueous solutions, being placed in exchange still seals, continuing to be warming up to 105 DEG C under stirring, under pressing as 0.13Mpa, still keeps 1h, then be cooled to 60 DEG C of filtrations, washing, obtain filter cake product B 3.
4.37 kilograms of ammonium dihydrogen phosphate (ADP)s are dissolved in double centner deionized water, again 6.1 kilogram of six nitric hydrate yttrium salt is dissolved in 80 kilograms of deionized waters, and join and in ammonium dihydrogen phosphate, form colloid, in this colloid, add the 180 kilograms of above-mentioned molecular sieve filter cake of butt B3 stirring to pulps even, then slurries are dried to 24h at 120 DEG C, obtain combination of molecular sieve product B 4 of the present invention.
Get the above-mentioned zeolite product B4 of part, measure through X-ray powder diffraction, its diffraction pattern, with Fig. 1 feature, illustrates that it is ZSM-5.Through XRF analysis, Na in B4 molecular sieve 2o content is 0.02%, P 2o 5content is 1.49%, Y 2o 3content is 1.16%, and silica alumina ratio is 188.Through low temperature N 2-adsorption analysis, the BET method specific area of B4 molecular sieve is 418m 2/ g, total pore volume is 0.31mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.14mL/g, and accounting for total pore volume ratio is 45.2%.
Embodiment 3
0.8 kg of hydrogen aluminium oxide is joined to 330 kilograms of TPAOH aqueous solution and dissolve, then add 150 grams of deionized waters and 150 kilograms of white carbons (production of Guangdong Hai Hua Chemical Co., Ltd.), be uniformly mixed 2 hours.Mole consisting of of gained reactant mixture: TPAOH/SiO 2=0.17, SiO 2/ Al 2o 3=300, H 2o/SiO 2=12.Pack reactant mixture into stainless steel crystallizing kettle, crystallization 100 hours under 120 DEG C, continuous stirring and self-generated pressure.Then crystallization product filtered, washed and dry 16h at 120 DEG C, obtaining molecular screen primary powder products C 1.
Above-mentioned dry former powder C1, as in Muffle furnace, in 600 DEG C of roasting 2h, is obtained to roasting molecular sieve powder C2.
Get the above-mentioned roasting molecular sieve of double centner butt powder C2 and join 1000 kilograms of deionized water for stirring making beating, then add 1.11 kilograms of fluorine silicic acid aqueous solutions, being placed in exchange still seals, continuing to be warming up to 150 DEG C under stirring, under pressing as 0.48Mpa, still keeps 4h, then be cooled to 40 DEG C of filtrations, washing, obtain filter cake products C 3.
0.68 kilogram of ammonium dihydrogen phosphate (ADP) is dissolved in 40 kilograms of deionized waters, then adds with RE 2o 3(Sinopec catalyst asphalt in Shenli Refinery product, ree distribution pattern is for containing 60%La for the mixed chlorinated rare earth solution of meter 100g/L 2o 3, 40%CeO 2) 4.4L, add the 70 kilograms of above-mentioned molecular sieve filter cake of butt C3 stirring to pulps even, then slurries are dried to 16h at 120 DEG C, obtain combination of molecular sieve products C 4 of the present invention.
Get the above-mentioned zeolite product C4 of part, measure through X-ray powder diffraction, its diffraction pattern, with Fig. 1 feature, illustrates that it is ZSM-5.Through XRF analysis, Na in C4 molecular sieve 2o content is 0.04%, P 2o 5content is 0.69%, La 2o 3content is 0.42%, CeO 2content is 0.26%, and silica alumina ratio is 374.Through low temperature N 2-adsorption analysis, the BET method specific area of C4 molecular sieve is 440m 2/ g, total pore volume is 0.323mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.171mL/g, and accounting for total pore volume ratio is 52.9%.
Embodiment 4
The roasting molecular sieve powder B2 that gets preparation in double centner butt embodiment 2 joins 800 grams of deionized water for stirring making beating, then add 7.48 kilograms of fluorine silicic acid aqueous solutions and 1 kilogram of aqueous hydrochloric acid solution (containing 10% geavy salt acid), being placed in exchange still seals, continuing to be warming up to 120 DEG C under stirring, under pressing as 0.21Mpa, still keeps 2h, then be cooled to 50 DEG C of filtrations, washing, obtain filter cake product D3.
1.46 kilograms of ammonium dihydrogen phosphate (ADP)s are dissolved in 50 kilograms of deionized waters, again 2.39 kilograms of lanthanum nitrate hexahydrate salt are dissolved in 40 kilograms of deionized waters, and join and in ammonium dihydrogen phosphate, form colloid, in this colloid, add the 90 kilograms of above-mentioned molecular sieve filter cake of butt D3 stirring to pulps even, then slurries are dried to 24h at 120 DEG C, obtain combination of molecular sieve product D4 of the present invention.
Get the above-mentioned zeolite product D4 of part, measure through X-ray powder diffraction, its diffraction pattern, with Fig. 1 feature, illustrates that it is ZSM-5.Through XRF analysis, Na in D4 molecular sieve 2o content is 0.02%, P 2o 5content is 0.99%, La 2o 3content is 1.17%, and silica alumina ratio is 274.Through low temperature N 2-adsorption analysis, the BET method specific area of D4 molecular sieve is 432m 2/ g, total pore volume is 0.32mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.15mL/g, and accounting for total pore volume ratio is 46.9%.
Example 5-8 illustrates the catalyst of preparing as active component taking ZSM-5 molecular sieve composition of the present invention.
Embodiment 5
By 4 and 349 grams of aluminium colloidal sols of 300 grams of butt molecular sieve-4 As in embodiment 1, (Sinopec catalyst asphalt in Shenli Refinery product, containing 21.5% heavy Al 2o 3) fully mix, then in bowling machine, rotating into pellet catalyst, screening obtains the bead of diameter 1.4-2.0mm, and gained bead, through 120 DEG C of oven dry 16h, then obtains pellet catalyst CA4 for 4 hours in 550 DEG C of temperature, roasting.
CA4 catalyst consists of 80% weight molecule sieve A4 and 20% heavy Al 2o 3.
Embodiment 6
By 22.34 grams of kaolin (China Kaolin Co., Ltd's products, igloss 16%) add 150 grams of deionized waters and 261 grams of aluminium colloidal sols to pull an oar, add again 300 grams of butt molecular sieve B4 in embodiment 2 and fully mix, then spray shaping microspherical catalyst on small spraying drying shaping apparatus, screening obtains the microballoon of diameter 38-150 μ m scope, thus obtained microsphere, through 120 DEG C of oven dry 16h, then obtains microspherical catalyst CB4 for 4 hours in 550 DEG C of temperature, roasting.
CB4 catalyst consists of 80% weight molecule sieve B4,15% heavy Al 2o 3with 5% heavy kaolin.
Embodiment 7
85 grams of butt molecular sieve C4 in embodiment 3 are fully mixed with 15 grams of butt dry glue powders (production of Sinopec catalyst Chang Ling branch company), add 1.5% heavy aqueous acetic acid to mediate, then extrude the bar shaped catalyst of diameter 1.5mm with banded extruder, through 120 DEG C of oven dry 16h, then within 2 hours, obtain bar shaped catalyst CC4 in 550 DEG C of temperature, roasting.
CC4 catalyst consists of 85% weight molecule sieve C4 and 15% heavy Al 2o 3.
Embodiment 8
By 300 grams of butt molecular sieve D4 in embodiment 4 with 211.6 grams of Ludox (containing 25% heavy SiO 2) fully mix, then in bowling machine, rotate into pellet catalyst, screening obtains the bead of diameter 1.4-2.0mm, gained bead is dried 16h through 120 DEG C, after in Muffle furnace through 600 DEG C of temperature, roasting 8 hours pellet catalyst CD4.
CD4 catalyst consists of 85% weight molecule sieve D4 and 15% heavy SiO 2.
Comparative example 1
This comparative example illustrates the preparation process of conventional ZSM-5 molecular sieve catalyst.
(Sinopec catalyst Jian Chang branch company produces to get 500 grams of butt ZSM-5 molecular sieves, trade mark ZRP-5B, silica alumina ratio 120~150) after the de-amine of 550 DEG C of roasting 4h is processed, add the making beating of 3000mL deionized water, add again 100 grams of ammonium chlorides and 10 grams of aqueous hydrochloric acid solutions (containing 10% geavy salt acid), and be under agitation warming up to 70 DEG C exchange 1h, filter, washing, filter cake adds the making beating of 3000mL deionized water again, add again after 100 grams of ammonium chlorides and 10 grams of aqueous hydrochloric acid solutions (containing 10% geavy salt acid), under agitation be warming up to 70 DEG C of exchange 1h, filter, after washing, dry 16h through 120 DEG C, must contrast sieve sample DBA.
Get the above-mentioned molecular screen primary powder DBA of part, measure through X-ray powder diffraction, its diffraction pattern is with Fig. 1 feature.Through XRF analysis, Na in DBA molecular sieve 2o content is 0.01%, and silica alumina ratio is 145.Through low temperature N 2-adsorption analysis, the BET method specific area of DBA molecular sieve is 355m 2/ g, total pore volume is 0.21mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.03mL/g, and accounting for total pore volume ratio is 14.3%.
Above-mentioned 80 grams of butt molecular sieve DBA are mixed with 20 grams of butt boehmites, continue to add 1.5% heavy aqueous acetic acid fully to mediate, then extrude the bar shaped catalyst of diameter 1.5mm through banded extruder, by 120 DEG C of oven dry 16h, then within 8 hours, obtain bar shaped catalyst CDBA in 600 DEG C of temperature, roasting.
CDBA catalyst consists of 80% weight molecule sieve DBA and 20% heavy Al 2o 3.
Comparative example 2
The catalyst that the same ZSM-5 molecular sieve composition that uses fluosilicic acid, obtain under non-hydrothermal treatment consists condition of this comparative example explanation obtains for active component.
(Sinopec catalyst Jian Chang branch company produces to get 1000 grams of butt ZSM-5 molecular sieves, trade mark ZRP-5, silica alumina ratio 80~100) join the making beating of 8000 grams of deionized water for stirring, then add 460.8 grams of fluorine silicic acid aqueous solutions, be placed in exchange still, continuing to be warming up to 70 DEG C under stirring, keep 2h, then be cooled to 60 DEG C of filtrations, washing, obtain filter cake.15.0 grams of ammonium dihydrogen phosphate (ADP)s are dissolved in 500 grams of deionized waters, again 30.0 grams of lanthanum nitrate hexahydrate salt are dissolved in 400 grams of deionized waters, and join and in ammonium dihydrogen phosphate, form colloid, in this colloid, add the 900 grams of above-mentioned molecular sieve filter cake of butt stirring to pulps even, then slurries are dried to 24h at 120 DEG C, must contrast sieve sample DBB.
Get the above-mentioned zeolite product DBB of part, measure through X-ray powder diffraction, its diffraction pattern, with Fig. 1 feature, illustrates that it is ZSM-5.Through XRF analysis, Na in DBB molecular sieve 2o content is 0.01%, P 2o 5content is 1.02%, La 2o 3content is 1.47%, and silica alumina ratio is 285.Through low temperature N 2-adsorption analysis, the BET method specific area of DBB molecular sieve is 384m 2/ g, total pore volume is 0.20mL/g, and the mesoporous pore volume that its mesoporous is >2nm is 0.03mL/g, and accounting for total pore volume ratio is 15.0%.
(weigh SiO containing 25% by above-mentioned 600 grams of butt molecular sieve DBB and with 423.2 grams of Ludox 2) fully mix, then in bowling machine, rotate into pellet catalyst, screening obtains the bead of diameter 1.4-2.0mm, gained bead is dried 16h through 120 DEG C, after in Muffle furnace through 600 DEG C of temperature, roasting 4 hours pellet catalyst CDBB.
CDBB catalyst consists of 85% weight molecule sieve DBB and 15% heavy SiO 2.
Embodiment 9
The catalyst that the present embodiment explanation is contained ZSM-5 molecular sieve composition provided by the invention is applied to the evaluation result of MTP course of reaction.
MTP reaction evaluating carries out on atmospheric fixed bed micro anti-evaluation device, and this device is made up of sampling system, reactor, product-collecting system, regenerative system and temperature control system five parts.The catalyst of filling purges to reaction temperature with High Purity Nitrogen in the time of reaction evaluating pre-heating temperature elevation, methanol aqueous solution raw material is injected in reactor with micro-injection pump, the cooling laggard promoting the circulation of qi liquid product of product separates, gaseous products collects through draining water gathering of gas law the circumstances in which people get things ready for a trip analysis of spectrum of going forward side by side, and liquid-phase product is collected laggard circumstances in which people get things ready for a trip analysis of spectrum; After having reacted, temperature of reactor is risen to 600 DEG C, pass into oxygen simultaneously and regenerate, regeneration gas is fully oxidized by oxidation furnace, the CO of generation 2gas is by the infrared CO of QGS-08D 2gas analyzer is measured, and obtains the carbon deposit content of post catalyst reaction after integral operation.
Become 20-40 order particle for subsequent use through crushing and screening the catalyst sample of embodiment 5-8.When MTP reaction evaluating, catalyst in reactor loadings is 2 grams.Adopt 50% heavy methanol aqueous solution charging, after 1h is stablized in charging under reaction temperature, start to measure the MTP reaction mass balance in 10min subsequently.Gained methanol conversion and product are distributed as the mean value in 10min feed time section.The carbon back productive rate (%) of propylene is the mass percent that the carbon in product propylene accounts for carbon in charging methyl alcohol.Evaluation response temperature is that 470 DEG C, methanol feeding WHSV are 11h -1, reaction pressure is a little more than normal pressure.
Gained reaction evaluating the results are shown in table 1.
Comparative example 3
The catalyst that the explanation of this comparative example is contained conventional ZSM-5 molecular sieve is applied to the evaluation result of MTP course of reaction.
Process is with embodiment 9, and difference is that catalyst used is the catalyst of comparative example 1, comparative example 2.
Gained reaction evaluating the results are shown in table 1.
Table 1
Sample Methanol conversion, % Propylene carbon back productive rate, % Propylene/ethylene mass ratio
Catalyst CA4 100.0 44.6 4.7
Catalyst CB4 100.0 43.8 5.9
Catalyst CC4 96.8 39.4 10.4
Catalyst CD4 100.0 42.9 7.1
Contrast medium CDBA 100.0 36.9 3.3
Contrast medium CDBB 94.5 37.8 5.9
Obviously can find out from the evaluation result of table 1, compared with the catalyst of prior art, adopt catalyst that combination of molecular sieve of the present invention is active component effectively catalysis methanol transform and obtain propylene, through the modulation of peracidity and pore structure, in keeping methyl alcohol high conversion, propylene/ethylene mass ratio is significantly improved, and this is conducive to reduce the separating energy consumption of ethene in product subsequent separation system, improves the benefit of MTP reaction unit.
Embodiment 10
Life assessment result when the present invention illustrates the catalyst that contains ZSM-5 molecular sieve composition provided by the invention for MTP process.
Become 20-40 order particle for subsequent use through crushing and screening the catalyst sample of embodiment 8.
MTP reaction life assessment still adopts the MAT device in embodiment 9 descriptions, and catalyst in reactor loadings is 8 grams.Adopt 50% heavy methanol aqueous solution charging, under 460 DEG C of reaction temperatures, methanol feeding WHSV is 1.5h -1, reaction pressure is carried out life assessment a little more than normal pressure.Using methanol conversion lower than 96% standard as catalysqt deactivation.Gained methanol conversion is listed in Fig. 2 with the result of variations in reaction time.
Comparative example 4
The catalyst of the ZSM-5 molecular sieve that the explanation of this comparative example is contained comparative example 2 is applied to the life assessment result of MTP course of reaction.
Process is with embodiment 10, and difference is that catalyst used is the ZSM-5 molecular sieve catalyst of comparative example 2.
Gained methanol conversion is listed in Fig. 2 with the result of variations in reaction time.
As can be seen from Figure 2, compared with comparative catalyst, adopt the process of ZSM-5 molecular sieve composition of the present invention, the one way active lifetime of its catalyst obviously extends, and is conducive to reduce the regeneration times of catalyst, extends life cycle.

Claims (20)

1. a ZSM-5 molecular sieve composition, is characterized in that this combination of molecular sieve contains with P 2o 5the phosphorus of the 0.1-10 % by weight of meter and in the rare earth of the 0-10 % by weight of oxide, in said ZSM-5 molecular sieve, alkali metal is less than 0.2 % by weight, SiO in the content of oxide 2with A1 2o 3molar ratio be 100-1000, nitrogen adsorption method measure under BET method specific area be 300-600m 2/ g, total pore volume is 0.2-0.6mL/g, the mesoporous pore volume of bore dia >2nm accounts for the 30-70% of total pore volume.
2. according to the composition of claim 1, wherein, said phosphorus is with P 2o 5meter, content is 0.2-5 % by weight, and said rare earth is less than 0.1 % by weight taking oxide, content as 0-5 % by weight, said alkali metal in oxide, content.
3. according to the composition of claim 1, wherein, said SiO 2with A1 2o 3molar ratio be 150-500.
4. according to the composition of claim 1, wherein, said BET method specific area under nitrogen adsorption method is measured is 350-500m 2/ g, total pore volume is 0.3-0.5mL/g, the mesoporous pore volume of its median pore diameter >2nm accounts for the 40-60% of total pore volume.
5. according to the composition of claim 1, wherein, said rare earth is selected from one or more in yttrium, lanthanum, cerium and praseodymium.
6. the preparation method of the ZSM-5 molecular sieve composition of claim 1-5, is characterized in that, the method comprises that former the ZSM-5 molecular sieve of alkali metal-free or low alkali powder is removed to organic formwork agent through roasting obtains roasting powder, roasting powder carries out liquid phase acid treatment and obtains pickling filter cake, and, said pickling filter cake carries out reclaiming the step that obtains ZSM-5 molecular sieve composition after the activation processing of phosphorus-containing compound and compounds containing rare earth, wherein, it is that roasting powder and the acidic aqueous solution making beating that contains fluosilicic acid are evenly become to molecular sieve pulp that said roasting powder carries out step that liquid phase acid treatment obtains pickling filter cake, and in airtight still temperature 100-200 DEG C, hydrothermal treatment consists under pressure 0.1-2Mpa, the mass ratio of the butt of said fluosilicic acid and said roasting powder is 0.0001-0.1:1, in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 3-20:1.
7. according to the method for claim 6, wherein, the former powder of said ZSM-5 molecular sieve is to obtain through following process: aluminium source, silicon source, water and organic formwork agent are thoroughly mixed to form to reactant mixture, and mole compositing range is organic formwork agent/SiO 2=0.03-0.3, SiO 2/ Al 2o 3=100-1000, H 2o/SiO 2=5-30, wherein organic formwork agent is tetraethyl ammonium hydroxide or TPAOH, by reactant mixture under agitation, under the temperature of 70~200 DEG C, self-generated pressure hydrothermal crystallizing 20~200 hours, crystallization product after filtration, dry at 80-200 DEG C of temperature after washing, obtain the former powder of ZSM-5 molecular sieve.
8. according to the method for claim 7, wherein, said aluminium source is selected from hydrated alumina, aluminum sulfate, aluminum nitrate, aluminium hydroxide or aluminium isopropoxide; Said silicon source is selected from solid silicone or white carbon.
9. according to the method for claim 6, wherein, said roasting removes organic formwork agent, and its condition is ingress of air roasting 0.5-50h at 300-800 DEG C.
10. according to the method for claim 6, wherein, said hydrothermal treatment consists, its condition is in airtight still, temperature 105-180 DEG C, pressure 0.11-1Mpa.
11. according to the method for claim 6, wherein, said hydrothermal treatment consists, its condition is in airtight still, temperature 105-150 DEG C, pressure 0.12-0.7Mpa.
12. according to the method for claim 6, wherein, the butt of said fluosilicic acid and said roasting powder mass ratio be 0.001-0.05.
13. according to the method for claim 12, wherein, the butt of said fluosilicic acid and said roasting powder mass ratio be 0.002-0.01.
14. according to the method for claim 6, and wherein, in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 4-15.
15. according to the method for claim 14, and wherein, in said molecular sieve pulp, the mass ratio of the butt of water and roasting powder is 5-10.
16. according to the method for claim 6, wherein, the activation processing that said pickling filter cake carries out phosphorus-containing compound and compounds containing rare earth is by water-soluble the soluble inorganic phosphor-contained compound of required amount of calculation, fully be mixed into activator with the aqueous solution containing the soluble salt that is selected from one or more rare earth elements in yttrium, lanthanum, cerium and praseodymium of required amount of calculation, activator is mixed to then dry, roasting at 80-800 DEG C of temperature with the making beating of ZSM-5 molecular sieve pickling filter cake.
The method of 17. 1 kinds of Methanol light olefins, is characterized in that the active component of the method taking the ZSM-5 molecular sieve composition of one of claim 1-5 as catalyst.
18. according to the method for claim 17, and wherein, said light olefin is propylene.
19. according to the method for claim 17, adds steam or inert gas and regulates methanol feeding dividing potential drop, and reaction temperature used is 250 DEG C-600 DEG C; Reaction pressure used is 0.1-50 atmospheric pressure, and weight space velocity used is 0.01-50h -1.
20. according to the method for claim 19, and wherein, reaction temperature used is 350 DEG C-500 DEG C; Reaction pressure used is 0.5-5 atmospheric pressure, and weight space velocity used is 0.1-10h -1.
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CN110860306B (en) * 2018-08-27 2022-08-09 中国石油化工股份有限公司 Regeneration method of inactivated ZSM-5 molecular sieve
CN111068752A (en) * 2018-10-18 2020-04-28 中国石油化工股份有限公司 MFI structure molecular sieve rich in mesopores and preparation method thereof
CN111068758A (en) * 2018-10-18 2020-04-28 中国石油化工股份有限公司 Mesoporous-rich phosphorus-and-rare earth-containing MFI structure molecular sieve and preparation method thereof
EP3868471A4 (en) * 2018-10-18 2022-07-13 China Petroleum & Chemical Corporation Phosphorus-containing rare-earth-containing mfi structure molecular sieve rich in mesopore, preparation method, and catalyst containing same and application thereof
US11964262B2 (en) 2018-10-18 2024-04-23 China Petroleum & Chemical Corporation Phosphorus-containing rare-earth-containing MFI structure molecular sieve rich in mesopore, preparation method, and catalyst containing same and application thereof
CN112138711A (en) * 2019-06-28 2020-12-29 中国石油化工股份有限公司 Catalytic cracking auxiliary agent, preparation method thereof and hydrocarbon oil catalytic cracking method
CN112138711B (en) * 2019-06-28 2022-06-28 中国石油化工股份有限公司 Catalytic cracking auxiliary agent, preparation method thereof and method for catalytic cracking of hydrocarbon oil
CN115959677A (en) * 2021-10-11 2023-04-14 中国石油化工股份有限公司 ZSM-5 molecular sieve with silicon-rich surface and preparation method thereof
CN115959677B (en) * 2021-10-11 2024-11-05 中国石油化工股份有限公司 ZSM-5 molecular sieve with silicon-rich surface and preparation method thereof

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