CN105646130B - The method of producing ethylene from dehydration of ethanol - Google Patents
The method of producing ethylene from dehydration of ethanol Download PDFInfo
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- CN105646130B CN105646130B CN201410713986.7A CN201410713986A CN105646130B CN 105646130 B CN105646130 B CN 105646130B CN 201410713986 A CN201410713986 A CN 201410713986A CN 105646130 B CN105646130 B CN 105646130B
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Abstract
The invention discloses a kind of method of producing ethylene from dehydration of ethanol.This method is catalyst A and catalyst B including at least two beds, and catalyst A compositions are as follows:Active component is ammonium heteropoly acidses, and auxiliary agent is boron oxide, and carrier is silica, and catalyst B compositions are as follows:Active component is ammonium heteropoly acidses, and auxiliary agent is boron oxide, and carrier is the molecular sieve of amorphous silica-alumina cladding.The present invention is cooperated using above two catalyst, is given full play to respective advantage, is improved the combined reaction performance of reaction system, has higher activity, selectivity and stability.
Description
Technical field
The present invention relates to the method for producing ethylene from dehydration of ethanol, is taken off more particularly to one kind using combination catalyst for ethanol
The method of water ethene.
Background technology
Ethene is as basic Organic Chemicals and the flagship product of petro chemical industry, about 75% chemical products
It is prepared by raw material of ethene, therefore the size of ethylene yield has become one national oil development of chemical industry water of measurement
Flat important symbol.Traditional ethene mainly by light petroleum fraction crack made from, heavy dependence petroleum resources.With
The day of international energy situation is becoming tight, and petroleum resources are increasingly exhausted, and it has been the task of top priority to develop new renewable alternative energy source.
Recently, ethanol particularly recyclable organism preparing ethylene by dehydrating ethanol is increasingly valued by people, and it has
Green, sustainable, reaction condition is gentle and many advantages such as product ethylene purity height.Bio-ethanol is mainly derived from agriculture
The fermentation of byproduct, the dependence to petroleum resources can be avoided, deficient in some petroleum resources such as Brazil, India, Pakistan
Country continues to use this method production ethene always, and this point more has realistic meaning to the country of oil-poor and few oil.Ethanol dehydration prepares second
Alkene, which has, partly or entirely replaces the great potential that ethene is obtained from oil.Therefore, research producing ethylene from dehydration of ethanol has great
Economic value and strategic importance.
Catalyst for ethanol delydration to ethylene report is a lot, mainly activated alumina, molecular sieve and heteropoly acid etc..It is living
Property aluminum oxide is cheap as catalyst, and activity and selectivity is preferable, but reaction temperature is high, and reaction velocity is low, energy
Consumption is high, and utilization rate of equipment and installations is low.The catalytic activity and selectivity of molecular sieve are high, stable;Reaction temperature is low, and reaction velocity is big, but
Catalyst life is short, and multiplication factor is small, limits its industrialized production.Heteropoly acid is with one by central atom and coordination atom
The oxygen-containing polyacid that fixed structure is formed by oxygen atom ligand bridging, has the advantages that highly acid.In producing ethylene from dehydration of ethanol
In reaction, heteropolyacid catalyst has the characteristics of reaction temperature is low, selectivity height and high income.
CN201310509561.X discloses the ZSM-5 molecular sieve catalyst that a kind of heteropoly acid is modified, for low concentration second
Dehydration of alcohols is ethylene reaction produced.Catalyst shows higher catalytic activity and selectivity, but the ratio surface due to carrier and
Aperture is relatively small, it is impossible to loads more heteropoly acids, excessive heteropoly acid can block the duct of carrier, cause catalyst activity
Decline, therefore which limit the further raising of catalyst activity.
[Chemical Engineering Technology and exploitation, 2010,5 (39) such as Li Benxiang:7-9] report entitled MCM-41 load silico-tungstic acid and urge
Change the article of producing ethylene from dehydration of ethanol, catalyst is prepared using infusion process.CN200910057539.X discloses a kind of ethanol and taken off
The catalyst of water ethene.For the catalyst using aluminum oxide as carrier, active component is heteropoly acid, is prepared using kneading method.It is above-mentioned
Catalyst shows higher catalytic activity and selectivity when using high concentration ethanol as raw material, but when using low-concentration ethanol as
During raw material, catalyst activity is decreased obviously, and stability is bad.
Producing ethylene from dehydration of ethanol is the endothermic reaction, and main reaction is that a molecules of ethanol catalytic reaction obtains a molecule ethene and one
Molecular water, with the progress of reaction, along reactor axis to dehydration content, which occurs, for the ethanol in raw material gradually reduces, water
Content gradually rises, and the larger temperature difference also occurs in catalyst bed interlayer, and the catalyst contact of bottom bed is containing big all the time
The low-concentration ethanol raw material of water is measured, and catalyst bottom bed temperature substantially reduces, and this can directly influence lower catalytic agent
Performance, cause the catalyst activity of reactor lower part substantially to reduce, so as to influence the activity of integer catalyzer, selectivity and steady
It is qualitative.
The content of the invention
In order to overcome weak point of the prior art, the invention provides a kind of method of producing ethylene from dehydration of ethanol.Should
When method is used for producing ethylene from dehydration of ethanol, have the advantages that high ethanol conversion, selectivity and stability are good.
The method of producing ethylene from dehydration of ethanol of the present invention, including two beds are catalyst A and catalyst B, wherein
Ethanol raw material first contacts with catalyst A, is then contacted again with catalyst B;
Catalyst A composition is as follows:Active component is that ammonium heteropoly acidses are shown in formula(1), auxiliary agent is boron oxide, and carrier is oxidation
Silicon;On the basis of the weight of catalyst, the content of ammonium heteropoly acidses is 3% ~ 35%, preferably 10% ~ 30%, more preferably
15% ~ 28%, for auxiliary agent using the content that oxide is counted as 3% ~ 8%, the content of carrier is 57% ~ 94%, preferably 62% ~ 87%;
Hu(NH4)vBA12O40(1)
Wherein A represents W or Mo, B represent Si or P;When B represents Si, u+v=4, v values are 0.1 ~ 1.0;When B represents P
When, u+v=3, v values are 0.1 ~ 1.0.
The property of the silica support is as follows:Specific surface area is 500 ~ 820 m2/ g, pore volume are 0.62 ~ 0.92 mL/g,
Average pore diameter is 4.6 ~ 6.6 nm.
Catalyst B composition is as follows:
Active component is that ammonium heteropoly acidses are shown in formula(2), auxiliary agent is boron oxide, and carrier is the molecule of amorphous silica-alumina cladding
Sieve, described molecular sieve be ZSM-5,4A, 5A in one or more, preferably ZSM-5;The weight of amorphous silica-alumina accounts for molecule
The 15% ~ 45% of sieve weight, preferably 20% ~ 40%;On the basis of the weight of catalyst, the content of ammonium heteropoly acidses is 3% ~ 35%,
Preferably 10% ~ 30%, for auxiliary agent using the content that oxide is counted as 3% ~ 7%, the content of carrier is 58% ~ 94%, preferably 63% ~ 87%;
Hm(NH4)nYX12O40(2)
Wherein X represents W or Mo, Y represent Si or P;When Y represents Si, m+n=4, n values are 0.1 ~ 1.0;When Y represents P
When, m+n=3, n values are 0.1 ~ 1.0.
The molecular sieve is hydrogen type molecular sieve, and its property is as follows:SiO2/Al2O3Mol ratio is 25 ~ 300.
In described catalyst A, ammonium heteropoly acidses and auxiliary agent boron oxide are distributed on silica support for eggshell type, i.e., miscellaneous
More acid ammonium salt and auxiliary agent boron oxides are distributed in the outer surface of silica support, and do not have heteropoly acid ammonium substantially in catalyst duct
With auxiliary agent boron oxide;In described catalyst B, ammonium heteropoly acidses and auxiliary agent boron oxide are uniform type distribution on carrier, i.e., miscellaneous
More acid ammonium salt and auxiliary agent boron oxides are evenly distributed on the surfaces externally and internally of carrier.
In the inventive method, the weight content of ammonium heteropoly acidses is not less than heteropoly acid in catalyst A in described catalyst B
The weight content of ammonium salt.
In the present invention, catalyst A preparation method, including:
(1)Silica support is added in alkane solvent, then filtered, at 20 DEG C ~ 50 DEG C, preferably 30 DEG C ~ 50 DEG C
Lower drying is to carrier surface without liquid phase;
(2)By step(1)Obtained material is added in aqueous solutions of organic acids, and stirring to solution steams at 60 DEG C ~ 90 DEG C
It is dry;
(3)By step(2)Obtained material is added in the alkaline solution containing ammonium, filtered, is done at 50 DEG C ~ 90 DEG C
It is dry, or by step(2)Obtained material adsorbs ammonia at 50 DEG C ~ 90 DEG C;
(4)The mixed aqueous solution of auxiliary agent presoma and heteropoly acid is added to step(3)In obtained material, 60 DEG C ~
Stirring to solution is evaporated at 90 DEG C;
(5)By step(4)Then obtained solid is calcined 2 in the h of 90 DEG C ~ 120 DEG C 3 h of drying ~ 12 at 300 DEG C ~ 550 DEG C
The h of h ~ 6, produces catalyst.
Step(1)Described silica support is prepared with the following method:
A, template is added in the aqueous solution containing organic acid, obtains solution I;
B, silicon source is added in solution I, obtains solution II, then stirred at 60 DEG C ~ 90 DEG C extremely into gel;
C, by gel at 20 DEG C ~ 50 DEG C the h of the h of aging 8 ~ 24, then in the h of 90 DEG C ~ 120 DEG C 3 h of drying ~ 12, through into
Type, the h of 2 h ~ 6 is calcined at 300 DEG C ~ 800 DEG C, obtains silica support.
In step A, the template is cetyl trimethylammonium bromide, hexadecyltrimethylammonium chloride, dodecane
Base sodium sulphate, triblock polymer P123, triblock polymer F127, triblock polymer F108, molecular weight be 1000 ~
One or more in 10000 polyethylene glycol, SiO in described template and carrier2Mol ratio be 0.01 ~ 1.2;It is described
Organic acid is citric acid, the one or more in tartaric acid, malic acid, SiO in described organic acid and carrier2Mol ratio be
0.1~1.2。
In step B, described silicon source is the one or more in tetraethyl orthosilicate, Ludox.
In step C, the shaping of described silica support can use existing conventional molding techniques to carry out, such as extrusion
Shaping, compression molding etc., shape can be bar shaped, spherical, sheet etc..In forming process, bonding can be added as needed
Agent and shaping assistant, binding agent typically use small porous aluminum oxide.Shaping assistant such as peptizing agent, extrusion aid etc..
Step(1)In, described solvent is C5~C10One or more in liquid n-alkane, gasoline, diesel oil, solvent
Volume ratio with silica support is 1 ~ 3.Silica support add time for being impregnated in alkane solvent be generally 5 min ~
20 min。
Step(2)In, the organic acid is the one or more in citric acid, tartaric acid, malic acid.Described organic acid
With SiO in carrier2Mol ratio be 0.05 ~ 0.50.
Step(3)In, by step(2)Obtained material, which is added in the alkaline solution containing ammonium, to be impregnated, dip time
The min of generally 5 min ~ 30.By step(2)Obtained solid absorption ammonia, adsorption time are generally the min of 5 min ~ 30.Step
Suddenly(3)In, the alkaline solution containing ammonium is the one or more in ammoniacal liquor, sal volatile, ammonium bicarbonate soln.
Step(3)In, described ammonia can use pure ammonia, can also use the gaseous mixture containing ammonia, in mixed gas
In addition to ammonia, other is the one or more in inert gas such as nitrogen, argon gas.
Step(4)In, auxiliary agent presoma is boric acid;Described heteropoly acid is one kind in phosphotungstic acid, silico-tungstic acid, phosphomolybdic acid
It is or a variety of.
It can also be added in described silica support in mesopore molecular sieve, such as SBA-15, SBA-3, MCM-41 etc.
One or more, the weight content of molecular sieve in the carrier is below 10%, and generally 1% ~ 8%.Mesopore molecular sieve can aoxidize
Introduce, can also be introduced during plastic before silicon plastic, can also be introduced after silica plastic, can be with silica support
Kneading introduces in forming process.
Catalyst B preparation method, including:
I, molecular sieve carrier is prepared;
II, the molecular sieve carrier for preparing amorphous silica-alumina cladding;
III, the obtained carriers of step II are added in aqueous solutions of organic acids, stirring is to solution at 60 DEG C ~ 90 DEG C
It is evaporated;
IV, the obtained materials of step III are added in the alkaline solution containing ammonium, it is filtered, done at 50 DEG C ~ 90 DEG C
It is dry;Or the material that step III is obtained is adsorbed into ammonia at 50 DEG C ~ 90 DEG C;
V, the mixed aqueous solution of auxiliary agent presoma and heteropoly acid is added in the material that step IV is obtained, 60 DEG C ~ 90
Stirring to solution is evaporated at DEG C;
VI, by the solid that step V is obtained in the h of 90 DEG C ~ 120 DEG C 3 h of drying ~ 12, then in 300 DEG C ~ 550 DEG C roastings
The h of 2 h ~ 6 is burnt, produces catalyst.
In step I, described molecular sieve carrier be by dry powder through being molded, dry and roasting and obtain.Described molecular sieve can
It is made using conventional method, it is possible to use the commercial product directly bought.Described roasting condition:Sintering temperature be 400 DEG C ~
700 DEG C, roasting time is the h of 2 h ~ 6.The shape of molecular sieve carrier can determine according to being actually needed, such as using spherical,
The mm of its particle diameter 0.1 mm ~ 0.5.
In step II, the molecular sieve carrier of described amorphous silica-alumina cladding can use method commonly used in the prior art
Carry out, for example prepared using rolling balling method, method is as follows:The molecular sieve prepared in step I is put into bowling machine, rolled
During be equably sprinkled into amorphous silica-alumina dry powder and spray into binding agent, carrier is constantly grown up.Carrier after balling-up exists
The h of 3 h ~ 24 is dried at 20 DEG C ~ 50 DEG C, preferably 30 DEG C ~ 50 DEG C, the h of 2 h ~ 6 is then calcined at 400 DEG C ~ 700 DEG C.Step II
In, described binding agent is the dilute acid soln that mass concentration is the % of 5 % ~ 10, such as the one or more in acetic acid, nitric acid;Bond
The addition of agent is 0.5 ~ 1.5 with the mass ratio of amorphous silica-alumina dry powder.
In step II, silica weight content is the % of 15 % ~ 50 in described amorphous silica-alumina.
In step III, the organic acid is the one or more in citric acid, tartaric acid, malic acid.Described organic acid
Mass ratio with carrier is 0.1 ~ 0.4.
In step IV, the obtained materials of step III are added in the alkaline solution containing ammonium and impregnated, dip time one
As for the min of 5 min ~ 30.The solid absorption ammonia that step III is obtained, adsorption time are generally the min of 5 min ~ 30.Step
In IV, the alkaline solution containing ammonium is the one or more in ammoniacal liquor, sal volatile, ammonium bicarbonate soln.
In step IV, described ammonia can use pure ammonia, can also use the gaseous mixture containing ammonia, be removed in mixed gas
Outside ammonia, other is the one or more in inert gas such as nitrogen, argon gas.
In step V, auxiliary agent presoma is boric acid;Described heteropoly acid be phosphotungstic acid, silico-tungstic acid, one kind in phosphomolybdic acid or
It is a variety of.
Described catalyst A and catalyst B admission space ratio are 4:1 ~1:4.
The method of preparing ethylene by dehydrating ethanol of the present invention is as follows using fixed-bed process, reaction condition:Mass space velocity 0.5
h-1~15.0 h-1, 160 DEG C ~ 400 DEG C of reaction temperature.
Compared with prior art, the present invention has advantages below:
In the inventive method, the catalyst B of use, still have low temperature active high in the case where ethanol raw material concentration is low
Advantage, catalyst A downstream is seated in, can be obviously improved bed temperature reduces the negative shadow brought to catalyst system
Ring, catalyst A and catalyst B is cooperated and give full play to respective advantage, make catalyst system that there is low-temperature reactivity
The characteristics of height, feed throughput are big, concentration of alcohol wide adaptability, can keep higher activity and selectivity for a long time, make
The combined reaction performance of reaction system improves, and has higher product yield.
Embodiment
With reference to embodiment, the present invention is described in detail.In the present invention, wt% is mass fraction.
Embodiment 1
1st, catalyst preparation:
It is prepared by catalyst A
(1)The preparation of carrier:
Weigh 145.8g cetyl trimethylammonium bromides and 205g citric acids are made into mixed solution, by the positive silicic acid of 302mL
Tetra-ethyl ester is added in mixed solution, stirs 2 h, and then stirring is extremely into gel at 70 DEG C, the aging 12 at 40 DEG C by gel
H, 8 h are then dried at 110 DEG C, it is that 0.2mm is spherical that particle diameter, which is made, then through drying 8 h at 110 DEG C, in 580 DEG C of roastings
3 h, silica support is obtained, the wherein mol ratio of cetyl trimethylammonium bromide and silica is 0.3, citric acid and oxidation
The mol ratio of silicon is 0.8.Support is:Specific surface area is 525 m2/ g, pore volume are 0.64 mL/g, average pore diameter 4.9
nm。
(2)The preparation of catalyst:
The silica support of preparation is added in C6 alkane solvents, 10min is impregnated, then filters, is dried at 40 DEG C
To carrier surface without liquid phase;It is then added in the aqueous solution containing 26.9g citric acids, stirring to solution is evaporated at 70 DEG C;
Obtained material, which is added in sal volatile, impregnates 10min, is dried after filtering at 60 DEG C;It is then added to containing 7.1g boron
In the mixed aqueous solution of acid and 12.4g phosphotungstic acids, stirring to solution is evaporated at 70 DEG C;By obtained solid in 110 DEG C of dryings
8.0 h, 3.0 h then are calcined at 500 DEG C, (NH is made4)0.5H2.5PW12O40-B2O3/SiO2Catalyst, wherein B2O3Content is
4wt%, (NH4)0.5H2.5PW12O40Content is 12wt%.
It is prepared by catalyst B
(1)The preparation of carrier:
It is that the spherical HZSM-5 molecular sieves (silica alumina ratio 60) of 0.2mm are added to bowling machine by the 70g particle diameters prepared
In, bowling machine is started, 14g amorphous silica-aluminas are equably sprinkled into machine(Silica content 20wt%)Dry powder, while spray into matter
The acetic acid aqueous solution that concentration is 6% is measured, after balling-up, carrier is dried into 12 h at 40 DEG C, is then calcined 3 h at 500 DEG C,
The HZSM-5 molecular sieve carriers of amorphous silica-alumina cladding are obtained, wherein amorphous silica-alumina accounts for the 20% of HZSM-5 molecular sieves.
(2)The preparation of catalyst:
The carrier prepared is added in the aqueous solution containing 12.6g citric acids, stirring to solution is evaporated at 70 DEG C;
Obtained material, which is added in sal volatile, impregnates 10min, is dried after filtering at 60 DEG C;It is then added to containing 7.1g boron
In the mixed aqueous solution of acid and 12.4g phosphotungstic acids, stirring to solution is evaporated at 70 DEG C;By obtained solid in 110 DEG C of dryings
8.0 h, 3.0 h then are calcined at 500 DEG C, catalyst, wherein B is made2O3Content is 4wt%, (NH4)0.5H2.5PW12O40Content
For 12wt%.
2nd, the evaluation of catalyst:
Evaluating catalyst is carried out in atmospheric fixed bed tubular reactor, and raw material is 20wt% ethanol waters, first with being catalyzed
Agent A is contacted, and is then contacted again with catalyst B, and wherein catalyst A and catalyst B admission space ratio is 3:1, totally 20 mL, matter
Measure air speed 5h-1, 260 DEG C of reaction temperature.Before reaction, catalyst is in N22 h are activated in 400 DEG C under protection, are then down to reaction
After temperature starts reaction 200 hours, product is analyzed by gas-chromatography, calculates ethanol conversion and ethylene selectivity, as a result
It is shown in Table 1.
Embodiment 2
Catalyst A and B admission space ratio are 1 in selection example 1:1, mass space velocity 6h-1, 260 DEG C of reaction temperature, its
Its appreciation condition is constant, and ethanol conversion and ethylene selectivity the results are shown in Table 1.
Embodiment 3
Catalyst A preparation:
(1)The preparation of carrier:
Weigh 200g cetyl trimethylammonium bromides and 105.7g citric acids are made into mixed solution, by the positive silicic acid of 250mL
Tetra-ethyl ester is added in mixed solution, stirs 2 h, and then stirring is extremely into gel at 70 DEG C, the aging 12 at 40 DEG C by gel
H, 8 h are then dried at 110 DEG C, it is that 0.2mm is spherical that particle diameter, which is made, then through drying 8 h at 110 DEG C, in 600 DEG C of roastings
3 h, silica support is obtained, the wherein mol ratio of cetyl trimethylammonium bromide and silica is 0.5, citric acid and oxidation
The mol ratio of silicon is 0.5.Support is:Specific surface area is 570 m2/ g, pore volume are 0.72 mL/g, average pore diameter 5.1
nm。
(2)The preparation of catalyst:
The silica support of preparation is added in C6 alkane solvents, 10min is impregnated, then filters, is dried at 40 DEG C
To carrier surface without liquid phase;It is then added in the aqueous solution containing 42.3g citric acids, stirring to solution is evaporated at 70 DEG C;
Obtained material, which is added in sal volatile, impregnates 10min, is dried after filtering at 60 DEG C;It is then added to containing 8.9 boron
In the mixed aqueous solution of acid and 18.7g phosphotungstic acids, stirring to solution is evaporated at 70 DEG C;By obtained solid in 110 DEG C of dryings
8.0 h, 3.0 h then are calcined at 500 DEG C, (NH is made4)0.5H2.5PW12O40-B2O3/SiO2Catalyst, wherein B2O3Content is
5wt%, (NH4)0.5H2.5PW12O40Content is 18wt%.
Catalyst B preparation:
(1)The preparation of carrier:
It is that the spherical HZSM-5 molecular sieves (silica alumina ratio 150) of 0.3mm are added to spin by the 59.2g particle diameters prepared
In machine, bowling machine is started, 17.8g amorphous silica-aluminas are equably sprinkled into machine(Silica content 30%)Dry powder, spray into simultaneously
Mass concentration is 6% acetic acid aqueous solution, after balling-up, carrier is dried into 12 h at 40 DEG C, is then calcined 3 at 500 DEG C
H, obtains the HZSM-5 molecular sieve carriers of amorphous silica-alumina cladding, and wherein amorphous silica-alumina accounts for the 30% of HZSM-5 molecular sieves.
(2)The preparation of catalyst:
The carrier prepared is added in the aqueous solution containing 19.3g citric acids, stirring to solution is evaporated at 70 DEG C;
Obtained material, which is added in sal volatile, impregnates 10min, is dried after filtering at 60 DEG C;It is then added to containing 7.9g boron
In the mixed aqueous solution of acid and 18.7g phosphotungstic acids, stirring to solution is evaporated at 70 DEG C;By obtained solid in 110 DEG C of dryings
8.0 h, 3.0 h then are calcined at 500 DEG C, catalyst, wherein B is made2O3Content is 5wt%, (NH4)0.5H2.5PW12O40Content
For 18wt%.
Catalyst A and B admission space ratio are 1:2, mass space velocity 7h-1, 250 DEG C of reaction temperature, other appreciation conditions are not
Become, ethanol conversion and ethylene selectivity the results are shown in Table 1.
Embodiment 4
In embodiment 1, phosphotungstic acid is changed to silico-tungstic acid, with embodiment 1, gained catalyst A is (NH for remaining4)0.5H3.5SiW12O40-B2O3/SiO2Catalyst, wherein B2O3Content is 4wt%, (NH4)0.5H3.5SiW12O40Content is 10wt%.Urge
B in agent B2O3Content is 4wt%, (NH4)0.5H3.5SiW12O40Content is 12wt%.
The evaluation of catalyst the results are shown in Table 1 with embodiment 1, ethanol conversion and ethylene selectivity.
Comparative example 1
Catalyst A in embodiment 1 is used alone, the evaluation of catalyst is the same as embodiment 1, ethanol conversion and ethylene selectivity
It the results are shown in Table 1.
The evaluation result of 1 each example of table
Embodiment | Conversion ratio, wt% | Selectivity, wt% |
Embodiment 1 | 98.5 | 98.3 |
Embodiment 2 | 98.8 | 98.6 |
Embodiment 3 | 99.2 | 98.9 |
Embodiment 4 | 98.3 | 98.2 |
Comparative example 1 | 95.2 | 94.9 |
Claims (9)
1. a kind of method of producing ethylene from dehydration of ethanol, including two beds are catalyst A and catalyst B, wherein ethanol
Raw material first contacts with catalyst A, is then contacted again with catalyst B;
Catalyst A composition is as follows:Active component is that ammonium heteropoly acidses are shown in formula(1), auxiliary agent is boron oxide, and carrier is silica;
On the basis of the weight of catalyst, the content of ammonium heteropoly acidses is 3% ~ 35%, and auxiliary agent carries using the content that oxide is counted as 3% ~ 8%
The content of body is 57% ~ 94%;
Hu(NH4)vBA12O40(1)
Wherein A represents W or Mo, B represent Si or P;When B represents Si, u+v=4, v values are 0.1 ~ 1.0;When B represents P, u+
V=3, v value are 0.1 ~ 1.0;
In described catalyst A, the property of silica support is as follows:Specific surface area is 500 ~ 820 m2/ g, pore volume be 0.62 ~
0.92 mL/g, average pore diameter are 4.6 ~ 6.6 nm;Catalyst B composition is as follows:
Active component is that ammonium heteropoly acidses are shown in formula(2), auxiliary agent is boron oxide, and carrier is the molecular sieve of amorphous silica-alumina cladding, with
On the basis of the weight of catalyst, the content of ammonium heteropoly acidses is 3% ~ 35%, and auxiliary agent is using the content that oxide is counted as 3% ~ 7%, carrier
Content be 58% ~ 94%;
Hm(NH4)nYX12O40(2)
Wherein X represents W or Mo, Y represent Si or P;When Y represents Si, m+n=4, n values are 0.1 ~ 1.0;When Y represents P, m
+ n=3, n value are 0.1 ~ 1.0;
In described catalyst B, the weight of amorphous silica-alumina accounts for the 20% ~ 40% of molecular sieve,
In described catalyst A, ammonium heteropoly acidses and auxiliary agent boron oxide are distributed on silica support for eggshell type;Described urges
In agent B, ammonium heteropoly acidses and auxiliary agent boron oxide are uniform type distribution on carrier.
2. in accordance with the method for claim 1, it is characterised in that:Described catalyst A, on the basis of the weight of catalyst,
The content of ammonium heteropoly acidses is 10% ~ 30%, and for auxiliary agent using the content that oxide is counted as 3% ~ 8%, the content of carrier is 62% ~ 87%.
3. in accordance with the method for claim 1, it is characterised in that:Described catalyst B, on the basis of the weight of catalyst,
The content of ammonium heteropoly acidses is 10% ~ 30%, and for auxiliary agent using the content that oxide is counted as 3% ~ 7%, the content of carrier is the % of 63 % ~ 87.
4. in accordance with the method for claim 1, it is characterised in that:In described catalyst B, molecular sieve ZSM-5,4A, 5A
In one or more.
5. in accordance with the method for claim 1, it is characterised in that:In described catalyst B, molecular sieve ZSM-5.
6. in accordance with the method for claim 1, it is characterised in that:In described catalyst B, molecular sieve is hydrogen type molecular sieve,
Its property is as follows:SiO2/Al2O3Mol ratio is 25 ~ 300.
7. according to any described method of claim 1 ~ 6, it is characterised in that:The weight of ammonium heteropoly acidses in described catalyst B
Measure the weight content that content is not less than ammonium heteropoly acidses in catalyst A.
8. in accordance with the method for claim 1, it is characterised in that:Described catalyst A and catalyst B admission space ratio are
4:1 ~1:4。
9. in accordance with the method for claim 1, it is characterised in that:Using fixed-bed process, preparing ethylene by dehydrating ethanol it is anti-
Answer condition as follows:The h of mass space velocity 0.5-1~15.0 h-1, 160 DEG C ~ 400 DEG C of reaction temperature.
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CN103521257A (en) * | 2013-10-25 | 2014-01-22 | 连云港阳方催化科技有限公司 | ZSM-5 molecular sieve modified catalyst as well as preparation method and application thereof |
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