CN100408169C - Ag catalyst for producing epoxyethane, its preparation method and uses - Google Patents
Ag catalyst for producing epoxyethane, its preparation method and uses Download PDFInfo
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- CN100408169C CN100408169C CNB2005100004643A CN200510000464A CN100408169C CN 100408169 C CN100408169 C CN 100408169C CN B2005100004643 A CNB2005100004643 A CN B2005100004643A CN 200510000464 A CN200510000464 A CN 200510000464A CN 100408169 C CN100408169 C CN 100408169C
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- Y—GENERAL 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
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Abstract
The present invention relates to silver catalyst for producing epoxy ethane by ethylene oxidation, which is obtained by the following methods: a solution containing silver compounds, organic amine, an alkali metal auxiliary agent, a cerium auxiliary agent, an optional alkaline earth metal auxiliary agent, an optional rhenium auxiliary agent and a co-auxiliary agent thereof is impregnated and forms porous alpha-alumina carrier by high temperature baking. After the solution is leached and dried, the solution is activated by mixing gas containing oxygen to prepare the silver catalyst. The silver catalyst prepared by the method has the advantages of high activity and high selectivity. The present invention also relates to the use of the catalyst in the epoxy ethane production by ethylene oxidation.
Description
Technical field
The present invention relates to a kind of silver catalyst and preparation method thereof, more particularly the present invention relates to a kind of silver catalyst of producing by the ethene oxidation in oxirane and preparation method thereof that is used for, also relate to this catalyst and produce purposes in the oxirane in the ethene oxidation.
Background technology
The ethene oxidation mainly generates oxirane under the silver catalyst effect, side reaction takes place simultaneously generate carbon dioxide and water, and wherein activity, selectivity and stability are the main performance index of silver catalyst.So-called activity is meant reaction temperature required when process for ethylene oxide production reaches certain reaction load.Reaction temperature is low more, and activity of such catalysts is high more.So-called selectivity is meant that conversion of ethylene in the reaction becomes the ratio of the overall reaction molal quantity of the molal quantity of oxirane and ethene.So-called stability then is expressed as active and selectivity fall off rate in time, and fall off rate is more little, and the stability of catalyst is good more.The silver catalyst that uses high activity, high selectivity and have good stability in the process of ethene oxidation production oxirane can be increased economic efficiency greatly, and the silver catalyst of therefore making high activity, high selectivity and good stability is the main direction of silver catalyst research.The performance of silver catalyst has the important relationship except that composition and the preparation method with catalyst, and also the performance and the preparation method of the carrier that uses with catalyst have important relationship.
In the prior art preparation method of silver catalyst comprise the preparation and administration to active component of porous carrier (as aluminium oxide) and auxiliary agent to as described in this two processes on the carrier.
The method that active component silver and various auxiliary agents are applied on the carrier mainly is an infusion process, promptly alumina support is dipped in the solution that silver salt, organic amine and various auxiliary agent make, and removes to add thermal reduction behind the solution and make the soaked carrier activation.Alkali metal is the most frequently used auxiliary agent, uses the patent of base earth metal promoter few.Silver catalyst baric 0.01-0.25% and alkali metal promoter that US4305844 (corresponding to EP0017725, Huels ChemischeWerke AG, 1981) makes, initial activity and selectivity are all very low; US4350616 (The Dow Chemical Company, 1982) has also used caesium and barium in the silver catalyst manufacture process, but the activity of the silver catalyst of making is all very low, and selectivity is no more than 84.0%; The epimere that US4376718 (Huels Chemische Werke AG, 1983) has described at reactor is provided with the auxiliary agent bed, and auxiliary agent is selected from the compound of potassium, rubidium, caesium, barium, has improved the stability of beds; The carrier specific surface that the silver catalyst preparation method that US4400308 (EC Erdoelchemie Gmbh, 1983) discloses is used is 0.4-0.5m
2/ g, the particle diameter of load silver are 0.3-0.4 μ m, use the alkali metal caesium of 0.001-0.03% and the alkaline-earth metal barium of 0.05-0.5%, and the silver catalyst selectivity of making is the highest only to reach 81.5%; SU1685510 (Chlorine Ind.Res.Des.Int., 1991) uses specific surface less than 1m
2The alumina support of/g, amido complex compound, alkali metal salt, alkaline earth metal compound with silver salt are handled carrier, handle with alkali metal salt and surfactant again after the drying, the alkali salt that patent is used is calcium nitrate and barium nitrate, add the DeGrain that alkaline-earth metal is obtained, space-time yield during less than 180gEO/l/h selectivity be up to 78.2%; DD289413A and DD288067 (Veb Leuna-Werke AG, 1991) have disclosed with organic acid silver, excessive lactic acid, alkaline-earth metal and alkali-metal acid solution and have been coated onto specific surface less than 0.3m
2The method for preparing silver catalyst on the carrier of/g, the alkaline-earth metal that uses is barium, and catalyst selectivity is made moderate progress, but high selectivity only is 77%; US4812437 (corresponding to EP0247414, Mitsubishi Petrochemical Co., 1989) is with silver and be selected from least a of sodium, potassium, rubidium, caesium, is deposited on to contain Al
6Si
2O
13Carrier on, sodium content has also used barium salt up to 0.08-1.2% on the carrier in catalyst preparation process, the selectivity of the silver catalyst of making is up to 81.2%; The first depositing silver of DE3310752 (corresponding to US4760042) and US4841080 (Scientific Design Co., 1988,1989) is 0.3-0.8m at specific surface
2On the carrier of/g, deposit alkali metal 50-300ppm after the activation again, patent claims that catalyst also comprises base earth metal promoter, preferred barium, and the selectivity of the silver catalyst that this patent is made only reaches 79.7%; WO9613493 is (corresponding to EP789693, Shell Int.Research, 1996) when preparation rhenium-containing silver catalyst, deposit alkaline-earth metal earlier before depositing silver, alkali metal promoter, rhenium auxiliary agent and the assistance agent thereof, preferred barium and/or magnesium, the initial activity that only deposits the catalyst that alkaline-earth metal and silver and alkali metal promoter make in the patent is higher, but selectivity only reaches 81.5%, and this patent is improved the initial activity of rhenium-containing silver catalyst by the pre-deposition alkaline-earth metal.
WO9713579 uses the catalyst selectivity of making to reach 85.0% with alkali metal, alkaline-earth metal and optional rhenium auxiliary agent cerium salt; CN1038411 has disclosed and has consisted of Ag
aBa
bK
cCs
dNa
eLa
fCe
gLoad aluminium oxide silver catalyst, wherein during a=100, b=0.01~10, c=0.1~10, d=0.1~10, e=0.01~0.05, f=0.5~5, g=0.5~5, the silver catalyst selectivity of patented invention can reach 83.5%.
Although above-mentioned patent documentation has used base earth metal promoter and Ce, the effect that obtains still is difficult to satisfactory, so this area still needs a kind of silver catalyst that comprehensively is improved and preparation method thereof on active and selectivity.
Summary of the invention
Situation in view of above-mentioned prior art, the present inventor has carried out research extensively and profoundly in the silver catalyst field, found that the porous alumina carrier solution impregnation that is mixed with by silver compound, organic amine and specific auxiliary agent, through air or oxygen content less than 21% nitrogen oxygen atmosphere in after the heat treatment prepared initial activity and the initial selectivity of silver catalyst in ethylene oxidation reactions all be improved.The present invention uses specific surface at 0.2-2.0m
2α-Al between the/g
2O
3Carrier is immersed in the mixed solution of silver salt, organic amine, alkali metal promoter, cerium auxiliary agent, non-essential base earth metal promoter and non-essential rhenium auxiliary agent and coassist agent thereof composition, makes silver catalyst after the drying activation, has higher initial performance.
Therefore, an object of the present invention is to provide a kind of novel silver catalyst, it demonstrates good initial activity and initial selectivity in the process of ethene oxidation production oxirane.
Another object of the present invention provides a kind of preparation method of above-mentioned silver catalyst.
A further object of the present invention provides the application of above-mentioned silver catalyst in ethene oxidation production oxirane.
These and other purposes of the present invention, feature and advantage will become more clear after reading this specification.
Detailed Description Of The Invention
One aspect of the present invention provides a kind of novel silver catalyst, and described catalyst is prepared by a method comprising the following steps:
1) usefulness contains the solution impregnation porous alpha-alumina supports of silver compound, organic amine, alkali metal promoter, cerium auxiliary agent, non-essential base earth metal promoter and the non-essential rhenium auxiliary agent and the coassist agent thereof of q.s;
2) after the elimination maceration extract, dry impregnated carrier; With
3) in containing oxygen gas mixture to step 2) the gained carrier activates, and makes described silver catalyst.
The present invention relates to the application of above-mentioned novel silver catalyst in ethene oxidation production oxirane on the other hand.
Porous α-the Al that is used for silver catalyst of the present invention
2O
3Carrier is α-Al
2O
3Content 〉=90%, the porous α-Al of preferred 〉=95%
2O
3Carrier.The salt that can add alkaline-earth metal such as magnesium, calcium, strontium and barium when this carrier of preparation is as sulfate, phosphate, carbonate etc., preferably sulfuric acid salt and carbonate, more preferably barium sulfate and brium carbonate.Based on porous α-Al
2O
3The gross weight of carrier, the content of alkaline-earth metal are in metal≤2.0%, preferably≤0.8%.The crushing strength of this carrier is 20N/ grain~150N/ grain, preferred 30N/ grain~120N/ grain; Specific surface is 0.2~2.0m
2/ g, preferred 0.3~1.5m
2/ g; Water absorption rate 〉=30%, preferred 〉=40%; Pore volume is 0.35-0.85ml/g, preferred 0.4-0.7ml/g.Porous α-Al
2O
3Carrier can be any conventional carrier format, for example granular, spherical, annular, bar shaped, porous column etc. radially, preferred annular.
Silver catalyst of the present invention is by preparing with the above-mentioned alumina support of solution impregnation of a kind of Ag-containing compound, organic amine, alkali metal promoter, cerium auxiliary agent, non-essential base earth metal promoter and non-essential rhenium auxiliary agent and coassist agent thereof and subsequent drying and calcining.
The silver compound that uses among the present invention can be those skilled in the art know those, for example silver oxide, silver oxalate, silver nitrate, silver sulfate, silver carbonate and silver orthophosphate, preferred silver nitrate.For the purpose of the present invention, operable organic amine be those skilled in the art know those, for example pyridine, ethamine, n-propylamine, isopropylamine, n-butylamine, sec-butylamine, isobutylamine, tert-butylamine, ethylenediamine, 1,3-propane diamine, 1,2-propane diamine, 1,4-butanediamine, 1,2-butanediamine, 1,3-butanediamine, monoethanolamine, Propanolamine, butanolamine, perhaps their mixture.Organic amine is pyridine, butylamine, ethylenediamine, 1 preferably, 3-propane diamine, monoethanolamine or its mixture.
Silver catalyst of the present invention for example can prepare as follows: at first make the aqueous solution and the ammonium oxalate or the oxalic acid aqueous solution reaction of silver nitrate, separate out the silver oxalate precipitation, after the filtration, spend deionised water, until no nitrate ion, then silver oxalate is dissolved in organic amine such as pyridine, butylamine, ethylenediamine, 1, in the aqueous solution of 3-propane diamine, monoethanolamine or its mixture, add auxiliary agent, be made into dipping solution.Flood above-mentioned alumina support with the gained dipping solution then, drain, in being not more than 21% nitrogen oxygen atmosphere, air stream or oxygen content in 150~700 ℃, preferred 200-500 ℃ temperature range, kept 0.5 minute~120 minutes, and preferred 1 minute~60 minutes, to carry out thermal decomposition.Also available silver oxide replaces silver nitrate, and silver oxalate also can not analysed filter, direct and organic amine complexing, impregnated carrier then.The amount of the silver compound that uses in the dipping process of the present invention should be enough to make argentiferous 1-30% weight in the finally prepd catalyst, and preferred 5~25% weight are in total catalyst weight.
Alkali metal promoter among the present invention can be compound or its any two kinds combination of lithium, sodium, potassium, rubidium or caesium, the for example oxide of lithium, sodium, potassium, rubidium or caesium, hydroxide, hydrochloride, sulfate, nitrate, carbonate, phosphate etc., the oxide of preferred caesium, hydroxide, hydrochloride, sulfate, nitrate, carbonate, phosphate etc., more preferably cesium sulfate and cesium carbonate.In final silver catalyst, alkali-metal content is 5~2000ppm based on final catalyst weight, preferred 10~1200ppm.Alkali metal promoter can be before dipping silver, simultaneously or be applied to afterwards on the carrier, also can after impregnated carrier activation, be immersed on the carrier.
Base earth metal promoter among the present invention can be the compound of magnesium, calcium, strontium or barium, as oxide, oxalates, sulfate, acetate or nitrate, or its mixture, preferred acetate, more preferably strontium acetate or barium acetate.In final silver catalyst, the content of alkaline-earth metal is 0~22000ppm based on final catalyst weight, preferred 0~10000ppm.Base earth metal promoter can be before dipping silver, simultaneously or be applied to afterwards on the carrier, also can after impregnated carrier activation, be immersed on the carrier.
Cerium auxiliary agent among the present invention can be oxide, oxalates, sulfate, acetate or the nitrate of cerium, or its mixture, the oxalates of preferred cerium and acetate, for example cerous acetate and cerium oxalate.In final silver catalyst, the content of cerium is 1~495ppm based on final catalyst weight, preferred 5~200ppm.The ce metal auxiliary agent can be before dipping silver, simultaneously or be applied to afterwards on the carrier, also can after impregnated carrier activation, be immersed on the carrier.
Rhenium auxiliary agent among the present invention can be oxide, perrhenic acid, the perrhenate of rhenium, or its mixture, preferred perrhenic acid and perrhenate, for example perrhenic acid, perrhenic acid caesium and ammonium perrhenate.In final silver catalyst, the content of rhenium is 0~1000ppm based on final catalyst weight, preferred 0~400ppm.The rhenium auxiliary agent can be before dipping silver, simultaneously or be applied to afterwards on the carrier, also can after impregnated carrier activation, be immersed on the carrier.
The coassist agent of the rhenium auxiliary agent among the present invention can be the compound of arbitrary transition metal in the periodic table of elements, or the mixture of several transistion metal compounds, the oxyacid and the salt thereof of preferred group vib and VIIB family element, for example wolframic acid, wolframic acid caesium, molybdic acid, ammonium molybdate.In final silver catalyst, the content of the coassist agent of rhenium auxiliary agent is 0~500ppm based on final catalyst weight, preferred 0~300ppm.The coassist agent of rhenium auxiliary agent can be before dipping silver, simultaneously or be applied to afterwards on the carrier, also can after impregnated carrier activation, be immersed on the carrier.
The mensuration of catalyst performance
Various silver catalyst of the present invention is tested its initial performance and stability with laboratory reaction device (following letter " little anti-") evaluating apparatus.The reactor that the micro anti-evaluation device uses is the stainless steel tube of internal diameter as 4mm, and reactor places heating jacket.The admission space of catalyst is 1ml, and inert filler is arranged at the bottom, makes beds be positioned at the flat-temperature zone of heating jacket.
Initial activity, optionally measure
The activity that the present invention uses and optionally condition determination is as follows:
Reacting gas is formed (mol%)
Ethene (C
2H
4) 28 ± 1
Oxygen (O
2) 7.4 ± 0.2
Carbon dioxide (CO
2)<8
Cause steady gas (N
2) surplus
Inhibitor dichloroethanes 0.1ppm-2.0ppm
Reaction pressure 2.1MPa
Air speed 7000/h
Reactor outlet EO concentration 1.35%
Space-time yield 185gEO/mlCat./h
Stable back METHOD FOR CONTINUOUS DETERMINATION reactor is gone into, the exit gas composition when reaction reaches.Measurement result carries out calculating as follows after volume contraction is proofreaied and correct selectivity:
Wherein AEO be work off one's feeling vent one's spleen poor with the inlet gas ethylene oxide concentration, ACO
2Be to work off one's feeling vent one's spleen poorly with the inlet gas gas concentration lwevel, the average of getting 10 groups of above test datas is as result of the test.
The present invention has compared following advantage with prior art: silver catalyst uses porous alumina carrier made in accordance with the present invention, add more a spot of ce metal auxiliary agent, prepare and have higher activity and silver catalyst optionally, this catalyst is specially adapted to the reaction that oxirane is produced in the ethene oxidation.
Embodiment
The present invention is described further below in conjunction with embodiment, but scope of the present invention is not limited to these embodiment.
Carrier 1 and 2:
With 30~500 purposes, three water α-Al
2O
3312g, the false water Al of 30~200 purposes
2O
3104g, petroleum coke 81g, NH
4F 7g, Mg (NO
3)
28.5g and BaSO
4Be respectively 0g, 1.2g puts into blender and mixes, and changes in the kneader, adds 0.18 liter in rare nitric acid (nitric acid: water=1: 3, weight ratio), but be kneaded into the paste of extrusion molding.Extrusion molding is the ring of external diameter 8.0mm, long 6.0mm, internal diameter 2.0mm, dries more than 2 hours down at 80~120 ℃, and free water content is reduced to below 10%.
Above-mentioned 2 rings are put into top-hat kiln, and through being elevated between 1350 ℃~1550 ℃ from room temperature about 30 hours, constant temperature 2 hours obtains white α-Al
2O
3Support samples 1 and support samples 2.
Carrier 3:
With 30~500 purposes, three water α-Al
2O
3312g, the false water Al of 30~200 purposes
2O
3104g, NH
4F 7g, Mg (NO
3)
2Mix 8.5g put into blender, change in the kneader, add 0.15 liter in rare nitric acid (nitric acid: water=1: 3, weight ratio), but be kneaded into the paste of extrusion molding.Extrusion molding is the ring of external diameter 8.0mm, long 6.0mm, internal diameter 2.0mm, dries more than 2 hours down at 80~120 ℃, and free water content is reduced to below 10%.
Above-mentioned ring is put into top-hat kiln, and through being elevated between 1350 ℃~1550 ℃ from room temperature about 30 hours, constant temperature 2 hours obtains white α-Al
2O
3Support samples 3.
After measured, the composition of gained carrier and physical data see Table 1.
The physical data of table 1 carrier 1~3
Carrier 1 | Carrier 2 | Carrier 3 | |
Alpha-alumina content (%) | 98.2 | 97.8 | 98.4 |
Barium monoxide content (%) | 0 | 0.35 | 0 |
Crushing strength (N/ grain) | 52 | 47 | 86 |
Water absorption rate (%) | 61 | 64 | 47 |
Bulk density (gram per centimeter 3) | 0.54 | 0.52 | 0.64 |
Specific surface (rice 2/ gram) | 0.87 | 0.98 | 0.91 |
Pore volume (milliliter/gram) | 0.68 | 0.65 | 0.58 |
Distribute (accounting for total pore volume %)<0.5 microns 0.5~1 micron 1~5 micron 5~10 microns 10~30 microns 30~51 microns>51 microns of pore radius | 20.5 4.1 51.4 10.7 9.2 1.5 1.6 | 19.8 4.9 53.5 9.8 9.6 1.5 0.9 | 17.0 4.5 63.7 9.6 3.4 0.9 0.9 |
Preparation of catalysts:
Comparative example 1-3:
Get the 700g silver nitrate and be dissolved in the 750ml deionized water, obtain liquor argenti nitratis ophthalmicus.Get in the deionized water that the 325g ammonium oxalate is dissolved in 50 ℃ of 250ml, obtain ammonium oxalate solution.Under vigorous stirring, mix these two kinds of solution, generate white silver oxalate precipitation.Ageing was filtered more than 30 minutes, spent deionised water and was precipitated to no nitrate ion.The filter cake argentiferous is about 60%, and is moisture about 15%, is paste.
In the glass container that band stirs, add the 300g ethylenediamine, 110g monoethanolamine, 375g deionized water.Stir following silver oxalate paste that makes above and slowly add in the mixed liquor, temperature remains on below 40 ℃, and silver oxalate is all dissolved, and the addition of silver oxalate makes the maceration extract argentiferous 22% (weight) that makes.Add 2.2g cesium sulfate, 1.1g barium acetate, add deionized water again and make the solution gross mass reach 2000g, make solution for later use.
Get the support samples 1,2 and 3 that 100g prepares above respectively and put into the container that can vacuumize.Be evacuated to more than the 10mmHg, put into above maceration extract, the submergence carrier kept 30 minutes.Excessive solution is gone in leaching.Soaked carrier heated 5 minutes in 400 ℃ air stream, and silver catalyst for ethylene oxide comparative example 1, comparative example 2 and comparative example 3 are promptly made in cooling.
Embodiment 1-9:
Repeat the program identical with comparative example 1-3, different is the cerous sulfate that maceration extract contains amount as shown in table 2 below in addition.
The addition of cerium auxiliary agent in the table 2 embodiment 1-9 catalyst sample preparation process
Embodiment number | Bearer number | Cerous sulfate addition (g) |
Embodiment 1 | 1 | 0.09 |
Embodiment 2 | 1 | 0.17 |
Embodiment 3 | 1 | 0.35 |
Embodiment 4 | 2 | 0.09 |
Embodiment 5 | 2 | 0.17 |
Embodiment 6 | 2 | 0.35 |
Embodiment 7 | 3 | 0.09 |
Embodiment 8 | 3 | 0.17 |
Embodiment 9 | 3 | 0.35 |
Silver and auxiliary agent content to the catalyst made are analyzed, and the results are shown in following table 3, and wherein content is in metal.
Use the microreactor evaluating apparatus to measure the activity and the selectivity of catalyst sample under aforementioned process conditions, result of the test is listed in the table below 3.
The result of the test of table 3 embodiment 1-9 catalyst sample
Embodiment number | Silver content (%) | The content of Cs (ppm) | The content of Ce (ppm) | Reaction temperature (℃) | EO (%) | Selectivity (%) |
Comparative example 1 | 16.5 | 639 | 0 | 226.5 | 1.36 | 83.1 |
Embodiment 1 | 17.0 | 642 | 15 | 221.8 | 1.36 | 83.7 |
Embodiment 2 | 16.8 | 638 | 41 | 220.5 | 1.35 | 83.9 |
Embodiment 3 | 17.1 | 635 | 103 | 223.6 | 1.37 | 83.6 |
Comparative example 2 | 16.9 | 642 | 0 | 224.8 | 1.35 | 83.3 |
Embodiment 4 | 17.2 | 645 | 16 | 221.0 | 1.36 | 83.9 |
Embodiment 5 | 16.6 | 634 | 43 | 220.4 | 1.36 | 84.3 |
Embodiment 6 | 17.1 | 640 | 112 | 222.0 | 1.34 | 83.7 |
Comparative example 3 | 14.6 | 554 | 0 | 220.7 | 1.35 | 82.9 |
Embodiment 7 | 17.2 | 668 | 11 | 217.4 | 1.38 | 83.5 |
Embodiment 8 | 17.2 | 666 | 36 | 215.6 | 1.36 | 83.7 |
Embodiment 9 | 17.3 | 662 | 87 | 216.8 | 1.35 | 83.6 |
Comparative example 4
In the glass container that band stirs, add the 300g ethylenediamine, 110g monoethanolamine, 375g deionized water.Stir following and slowly add in the mixed liquor as the silver oxalate silver paste that makes as described in the comparative example 1-3, temperature remains on below 40 ℃, and silver oxalate is all dissolved, and the addition of silver oxalate makes the maceration extract argentiferous 22% (weight) that makes.Add 2.2g cesium sulfate, 2.3g strontium acetate, add deionized water again and make the solution gross mass reach 2000g, make solution for later use.
Get the support samples 2 that 100g prepares above and put into the container that can vacuumize.Be evacuated to more than the 10mmHg, put into above maceration extract, the submergence carrier kept 30 minutes.Excessive solution is gone in leaching.Soaked carrier heated 5 minutes in 300 ℃ air stream, and silver catalyst for ethylene oxide comparative example 4 is promptly made in cooling.
Embodiment 10-12
Repeat the program identical with comparative example 4, different is cerous acetate or the cerium oxalate that maceration extract contains amount as shown in table 4 below in addition.
The addition of cerium auxiliary agent in the table 4 embodiment 10-12 catalyst sample preparation process
Embodiment number | Cerium auxiliary agent kind | Addition (g) |
Embodiment 10 | Cerous acetate | 0.19 |
Embodiment 11 | Cerous acetate | 0.38 |
Embodiment 12 | Cerium oxalate | 0.15 |
Silver and auxiliary agent content to the catalyst made are analyzed, and the results are shown in following table 5, and wherein content is in metal.
Use the microreactor evaluating apparatus to measure the activity and the selectivity of catalyst sample under aforementioned process conditions, result of the test is listed in the table below 5.
The result of the test of table 5 embodiment 10-12 catalyst sample
Embodiment number | Silver content (%) | The content of Cs (ppm) | The content of Ce (ppm) | Reaction temperature (℃) | EO (%) | Selectivity (%) |
Comparative example 4 | 16.5 | 639 | 0 | 224.7 | 1.36 | 83.3 |
Embodiment 10 | 17.0 | 642 | 43 | 220.8 | 1.36 | 83.7 |
Embodiment 11 | 16.8 | 638 | 98 | 219.3 | 1.35 | 84.3 |
Embodiment 12 | 17.1 | 635 | 47 | 221.6 | 1.37 | 83.8 |
Comparative example 5
In the glass container that band stirs, add the 300g ethylenediamine, 110g monoethanolamine, 375g deionized water.Stir following and slowly add in the mixed liquor as the silver oxalate paste that makes as described in the comparative example 1-3, temperature remains on below 40 ℃, and silver oxalate is all dissolved, and the addition of silver oxalate makes the maceration extract argentiferous 22% (weight) that makes.Add the 2.2g cesium sulfate, add deionized water again and make the solution gross mass reach 2000g, make solution for later use.
Get the support samples 2 that 100g prepares above and put into the container that can vacuumize.Be evacuated to more than the 10mmHg, put into above maceration extract, the submergence carrier kept 30 minutes.Excessive solution is gone in leaching.Soaked carrier heated 5 minutes in 300 ℃ air stream, and silver catalyst for ethylene oxide comparative example 5 is promptly made in cooling.
Embodiment 13-14
Repeat the program identical with comparative example 5, different is that maceration extract contains 0.35g and 3.8g cerous sulfate in addition.
Silver and auxiliary agent content to the catalyst made are analyzed, and the results are shown in following table 6, and wherein content is in metal.
Use the microreactor evaluating apparatus to measure the activity and the selectivity of catalyst sample under aforementioned process conditions, result of the test is listed in the table below 6.
Comparative example 6
Repeat the program identical with comparative example 5, different is that maceration extract contains the cerous sulfate of measuring shown in the 5.0g in addition.
Silver and auxiliary agent content to the catalyst made are analyzed, and the results are shown in following table 6, and wherein content is in metal.
Use the microreactor evaluating apparatus to measure the activity and the selectivity of catalyst sample under aforementioned process conditions, result of the test is listed in the table below 6.
The result of the test of table 6 embodiment 13 catalyst samples
Embodiment number | Silver content (%) | The content of Cs (ppm) | The content of Ce (ppm) | Reaction temperature (℃) | EO (%) | Selectivity (%) |
Comparative example 5 | 16.5 | 639 | 0 | 223.7 | 1.36 | 82.7 |
Embodiment 13 | 17.0 | 642 | 43 | 217.3 | 1.34 | 83.5 |
Embodiment 14 | 16.8 | 633 | 452 | 221.9 | 1.35 | 83.0 |
Comparative example 6 | 16.1 | 612 | 623 | 227.0 | 1.35 | 82.6 |
Comparative example 7
In the glass container that band stirs, add the 300g ethylenediamine, 110g monoethanolamine, 375g deionized water.Stir following and slowly add in the mixed liquor as the silver oxalate paste that makes as described in the comparative example 1-3, temperature remains on below 40 ℃, and silver oxalate is all dissolved, and the addition of silver oxalate makes the maceration extract argentiferous 22% (weight) that makes.Add 2.0g cesium sulfate, 0.6g perrhenic acid and 0.1g ammonium molybdate, add deionized water again and make the solution gross mass reach 2000g, make solution for later use.
Get the support samples 2 that 100g prepares above and put into the container that can vacuumize.Be evacuated to more than the 10mmHg, put into above maceration extract, the submergence carrier kept 30 minutes.Excessive solution is gone in leaching.Soaked carrier heated 5 minutes in 230 ℃ air stream, and silver catalyst for ethylene oxide comparative example 7 is promptly made in cooling.
Embodiment 15
Repeat the program identical with comparative example 5, different is that maceration extract contains the cerous sulfate of measuring shown in the 0.35g in addition.
Silver and auxiliary agent content to the catalyst made are analyzed, and the results are shown in following table 7, and wherein content is in metal.
Use the microreactor evaluating apparatus to measure the activity and the selectivity of catalyst sample under aforementioned process conditions, result of the test is listed in the table below 7.
The result of the test of table 7 embodiment 15 catalyst samples
Embodiment number | Silver content (%) | The content of Cs (ppm) | The content of Ce (ppm) | The content of Re (ppm) | The content of Mo (ppm) | Reaction temperature (℃) | EO (%) | Selectivity (%) |
Comparative example 7 | 16.5 | 639 | 0 | 205 | 32 | 227.4 | 1.36 | 83.9 |
Embodiment 15 | 17.0 | 642 | 43 | 210 | 35 | 222.6 | 1.34 | 84.7 |
Claims (32)
1. produce the used silver catalyst of oxirane by the ethene oxidation for one kind, by the method preparation that may further comprise the steps:
1) usefulness contains the solution impregnation porous alpha-alumina supports of silver compound, organic amine, alkali metal promoter, cerium auxiliary agent, non-essential base earth metal promoter and the non-essential rhenium auxiliary agent and the coassist agent thereof of q.s;
2) after the elimination maceration extract, dry impregnated carrier; With
3) in containing oxygen gas mixture to step 2) the gained carrier activates, and makes described silver catalyst; It is 1ppm~495ppm that the addition of wherein said cerium auxiliary agent should make the content of cerium in described silver catalyst, based on the gross weight of described silver catalyst.
2. silver catalyst as claimed in claim 1, wherein the porous alpha-alumina supports has following feature: Alpha-alumina content 〉=90%, alkaline earth metal content are in metal≤2.0%, and specific surface is 0.2~2.0m
2/ g, pore volume are 0.35~0.85ml/g, water absorption rate 〉=30%, and crushing strength is 20N/ grain~150N/ grain.
3. silver catalyst as claimed in claim 2, wherein the porous alpha-alumina supports has following feature: Alpha-alumina content 〉=95%, alkaline earth metal content are in metal≤0.8%, and specific surface is 0.3~1.5m
2/ g, pore volume are 0.4~0.7ml/g, water absorption rate 〉=40%, and crushing strength is 30N/ grain~120N/ grain.
4. silver catalyst as claimed in claim 1, wherein silver compound is silver oxide, silver nitrate or silver oxalate.
5. silver catalyst as claimed in claim 1, wherein should to make the content of silver in described silver catalyst be 1%~30% to the addition of silver compound, based on the gross weight of described silver catalyst.
6. silver catalyst as claimed in claim 5, wherein should to make the content of silver in described silver catalyst be 5%~25% to the addition of silver compound, based on the gross weight of described silver catalyst.
7. silver catalyst as claimed in claim 1, wherein said alkali metal promoter are compound or its any two kinds combination of lithium, sodium, potassium, rubidium or caesium.
8. silver catalyst as claimed in claim 7, the alkali metal in the wherein said alkali metal promoter are caesium.
9. it is 5ppm~2000ppm that silver catalyst as claimed in claim 7, the addition of wherein said alkali metal promoter should make the content of alkali metal in described silver catalyst in the described alkali metal promoter, based on the gross weight of described silver catalyst.
10. it is 10ppm~1200ppm that silver catalyst as claimed in claim 9, the addition of wherein said alkali metal promoter should make the content of alkali metal in described silver catalyst in the described alkali metal promoter, based on the gross weight of described silver catalyst.
11. silver catalyst as claimed in claim 1, wherein said base earth metal promoter are oxide, oxalates, sulfate, acetate or the nitrate of magnesium, calcium, strontium or barium, or its mixture.
12. silver catalyst as claimed in claim 11, the alkaline-earth metal in the wherein said base earth metal promoter are calcium.
13. silver catalyst as claimed in claim 11, the alkaline-earth metal in the wherein said base earth metal promoter are barium.
14. silver catalyst as claimed in claim 11, the alkaline-earth metal in the wherein said base earth metal promoter are strontium.
15. it is 0ppm~22000ppm that silver catalyst as claimed in claim 11, the addition of wherein said alkaline-earth metal should make the content of described alkaline-earth metal in described silver catalyst, based on the gross weight of described silver catalyst.
16. it is 0ppm~10000ppm that silver catalyst as claimed in claim 15, the addition of wherein said base earth metal promoter should make the content of alkaline-earth metal in described silver catalyst in the described base earth metal promoter, based on the gross weight of described silver catalyst.
17. silver catalyst as claimed in claim 1, oxide, oxalates, sulfate, acetate or nitrate that wherein said cerium auxiliary agent is a cerium, or its mixture.
18. it is 5ppm~200ppm that silver catalyst as claimed in claim 17, the addition of wherein said cerium auxiliary agent should make the content of cerium in described silver catalyst, based on the gross weight of described silver catalyst.
19. silver catalyst as claimed in claim 1, wherein said rhenium agent is rheium oxide, perrhenic acid or perrhenate, or its mixture.
20. it is 0ppm~1000ppm that silver catalyst as claimed in claim 19, the addition of wherein said rhenium auxiliary agent should make the content of rhenium in described silver catalyst, based on the gross weight of described silver catalyst.
21. it is 0ppm~400ppm that described silver catalyst as claimed in claim 20, the addition of wherein said rhenium auxiliary agent should make the content of rhenium in described silver catalyst, based on the gross weight of described silver catalyst.
22. silver catalyst as claimed in claim 1, the coassist agent of wherein said rhenium auxiliary agent are the compound of arbitrary transition metal in the periodic table of elements, or the mixture of several transistion metal compounds.
23. silver catalyst as claimed in claim 22, the coassist agent of wherein said rhenium auxiliary agent are the oxyacid and the salt thereof of group vib and VIIB family element.
24. it is 0ppm~500ppm that silver catalyst as claimed in claim 22, the addition of the coassist agent of wherein said rhenium auxiliary agent should make the content of this coassist agent in described silver catalyst, based on the gross weight of described silver catalyst.
25. it is 0ppm~300ppm that silver catalyst as claimed in claim 24, the addition of the coassist agent of wherein said rhenium auxiliary agent should make the content of this coassist agent in described silver catalyst, based on the gross weight of described silver catalyst.
26. silver catalyst as claimed in claim 1, wherein said auxiliary agent before dipping silver, simultaneously or be applied on the carrier afterwards, or after impregnated carrier activation, be immersed on the carrier.
27. silver catalyst as claimed in claim 1, wherein said activation process are to carry out in air or oxygen content are not more than 21% nitrogen oxygen atmosphere.
28. silver catalyst as claimed in claim 1, the temperature of wherein said activation process are controlled between 150 ℃~700 ℃.
29. silver catalyst as claimed in claim 28, the temperature of wherein said activation process are controlled between 200 ℃~500 ℃.
30. silver catalyst as claimed in claim 1, the time of wherein said activation process is 0.5 minute~120 minutes.
31. silver catalyst as claimed in claim 30, the time of wherein said activation process is 1 minute~60 minutes.
32. a method of producing oxirane by the ethene oxidation is wherein used as each described silver catalyst in the claim 1~31.
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CA2541992C (en) | 2003-10-16 | 2013-07-09 | Union Carbide Chemicals & Plastics Technology Corporation | Catalysts having enhanced stability, efficiency and/or activity for alkylene oxide production |
CN103831105A (en) * | 2012-11-20 | 2014-06-04 | 中国石油化工股份有限公司 | Olefin epoxidation catalyst and application thereof |
CN106311231A (en) * | 2015-06-30 | 2017-01-11 | 中国石油化工股份有限公司 | Method for preparing silver catalyst for alkene epoxidation, silver catalyst and application thereof |
CN110605115B (en) * | 2018-06-15 | 2022-05-24 | 中国石油化工股份有限公司 | Silver catalyst for producing ethylene oxide by ethylene epoxidation and preparation method and application thereof |
CN111659469A (en) * | 2019-03-05 | 2020-09-15 | 中国石油化工股份有限公司 | Silver catalyst for producing ethylene oxide by ethylene oxidation and preparation method and application thereof |
CN111659470A (en) * | 2019-03-05 | 2020-09-15 | 中国石油化工股份有限公司 | Silver catalyst for producing ethylene oxide by ethylene oxidation and preparation method and application thereof |
CN111659465A (en) * | 2019-03-05 | 2020-09-15 | 中国石油化工股份有限公司 | Silver catalyst for producing ethylene oxide by ethylene oxidation and preparation method and application thereof |
CN111659464A (en) * | 2019-03-05 | 2020-09-15 | 中国石油化工股份有限公司 | Silver catalyst for producing ethylene oxide by ethylene oxidation and preparation method and application thereof |
CN111905733B (en) * | 2019-05-09 | 2022-10-18 | 中国石油化工股份有限公司 | Method for activating silver catalyst and application |
CN114100684A (en) * | 2020-08-28 | 2022-03-01 | 中国石油化工股份有限公司 | Silver catalyst for olefin epoxidation and preparation method and application thereof |
CN114426527B (en) * | 2020-10-15 | 2023-11-10 | 中国石油化工股份有限公司 | Silver catalyst carrier for ethylene oxide, preparation method and silver catalyst and application |
CN115069247A (en) * | 2021-03-15 | 2022-09-20 | 中国石油化工股份有限公司 | Method for preparing supported silver catalyst, supported silver catalyst and application |
CN115869948B (en) * | 2021-09-27 | 2024-08-06 | 中国石油化工股份有限公司 | Preparation method of supported silver catalyst, silver catalyst and application |
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