CN103373890A - Method for separating p-xylene and ethylbenzene from C8 aromatic hydrocarbons by adsorption - Google Patents

Method for separating p-xylene and ethylbenzene from C8 aromatic hydrocarbons by adsorption Download PDF

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CN103373890A
CN103373890A CN2012101252439A CN201210125243A CN103373890A CN 103373890 A CN103373890 A CN 103373890A CN 2012101252439 A CN2012101252439 A CN 2012101252439A CN 201210125243 A CN201210125243 A CN 201210125243A CN 103373890 A CN103373890 A CN 103373890A
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adsorption
ethylbenzene
xylol
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aromatic hydrocarbons
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CN103373890B (en
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梁自斗
王德华
王辉国
郁灼
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Sinopec Research Institute of Petroleum Processing
China Petroleum and Chemical Corp
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China Petroleum and Chemical Corp
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Abstract

The invention discloses amethod for separating p-xylene and ethylbenzene from C8 aromatic hydrocarbons by adsorption. The method comprises the following steps of: obtaining extract oil containing p-xylene and raffinate oil containing ethylbenzene, m-xylene and o-xylene from C8 aromatic hydrocarbons via liquid-phase adsorption separation; and obtaining pressure swing adsorption raffinate and desorption solution from the raffinate oil obtained via liquid-phase adsorption separation via gas-phase pressure swing adsorption separation, and separating non-aromatic hydrocarbons in the desorption solution to obtain ethylbenzene. The method is capable of separating out high-purity p-xylene and ethylbenzene from C8 aromatic hydrocarbons.

Description

From C 8The method of adsorption stripping dimethyl benzene and ethylbenzene in the aromatic hydrocarbons
Technical field
The present invention is a kind of method of fractionation by adsorption arene isomer, specifically, is a kind of from C 8The method of adsorption stripping dimethyl benzene and ethylbenzene in the aromatic hydrocarbons.
Background technology
P-Xylol and ethylbenzene all are important industrial chemicals, and p-Xylol is mainly for the production of terephthalic acid (PTA) and dimethyl terephthalate (DMT) (DMT), and purity requirement is at least 99.5%, is preferably greater than 99.7%.Above-mentioned monomer is mainly used in synthetic textile product and various plastics.Ethylbenzene is mainly used in dehydrogenation and produces vinylbenzene, and vinylbenzene is the important monomer of producing macromolecular material, and mainly for the preparation of polystyrene, purity requirement is greater than 99.7%.
In the prior art, extensively adopt simulation moving-bed liquid phase adsorption separation technology from C 8Separate in the aromatic hydrocarbons and obtain p-Xylol.C 8Ethylbenzene typically is drawn out of as raffinating oil together with m-xylene, o-Xylol in the aromatic hydrocarbons, then is sent to isomerization unit and makes wherein part ethylbenzene, m-xylene and o-Xylol be converted into p-Xylol to be re-used as feed cycle and to go back to the simulated moving bed adsorption unit.USP2985589 has described the method for utilizing the simulation moving-bed separating paraxylene of adverse current; USP3686342, USP3734974, CN98810104.1 have described sorbent material that fractionation by adsorption uses and have been X or the Y zeolite of barium type or barium potassium type; USP3558732, USP3686342 use respectively toluene and p-Diethylbenzene as the desorbing agent of fractionation by adsorption.
USP5510562 is first with C 8Aromatic hydrocarbons mixture is divided into two kinds of logistics, contains respectively p-Xylol and ethylbenzene, and then m-xylene and o-Xylol adopt distillation then method separating paraxylene and the ethylbenzene of crystallization.The operating reflux ratio of fractionation by distillation is 50~80, needs 300~400 blocks of column plates, and ethylbenzene and the purity that can be met specification are the p-Xylol of 90~99wt%, the cut that is rich in p-Xylol is sent to crystallization can obtain more highly purified p-Xylol.
CN02142747.X contains the C of m-xylene, p-Xylol, ethylbenzene and a part of o-Xylol in simulation moving-bed middle separation 8During aromatic hydrocarbons mixture, a plurality of adsorption beds that will be connected with loop by charging, strippant, contain p-Xylol extraction oil, contain the middle runnings of ethylbenzene and contain o-Xylol and the raffinate of m-xylene is divided into five districts.Injecting and extract out between the oil extraction at strippant is the p-Xylol desorption zone, extracting out and adsorb between the charging injection at extraction oil is ethylbenzene, m-xylene and o-Xylol desorption zone, middle runnings discharge and charging are the p-Xylol adsorption zones between injecting, being the ethylbenzene adsorption zone between middle runnings discharge and raffinate discharge, is the 5th district between raffinate discharge and strippant injection.Middle runnings is removed strippant through the distillation tower distillation, obtain containing the first cut of ethylbenzene, extract oil out, raffinate is removed whole strippants basically through distillation, obtain respectively being rich in p-Xylol the second cut, be rich in the 3rd cut of m-xylene and o-Xylol.The second cut is sent at least one section crystallizing field, to obtain the p-Xylol crystal; First and third cut is sent to the isomerization reaction that isomerization unit carries out gas phase or liquid-phase operation, and isomerization product loops back the simulated moving bed adsorption charging.The sorbent material that the method is used is the Y zeolite that is rich in the X zeolite of barium or is rich in potassium, or is rich in the Y zeolite of barium and potassium.
CN1592326A has described a kind of method that adopts ultra-fine rectifying that ethylbenzene and m-xylene, o-Xylol are separated.The method is raffinated oil as raw material take p-Xylol, formed by two independent towers and to take off ethylbenzene tower, namely first takes off ethylbenzene tower and second and takes off ethylbenzene tower, 1 layer of 250Y and the structured packing of 3 layers of 350Y waveform are housed respectively in the tower, and ethylbenzene tower tower top pressure, tower top temperature, column bottom temperature and reflux ratio are taken off in control can realize separating of ethylbenzene and m-xylene, o-Xylol.
USP3729523 has described a kind of from C 8Reclaim the method for isomers in the aromatic hydrocarbons.The method is with C 8Aromatic hydrocarbons is by the first adsorption stage, be separated into the first burst of logistics that contains p-Xylol, ethylbenzene and the second logistics that contains o-Xylol, m-xylene, with first burst of logistics crystallization recovery p-Xylol wherein, the crystalline mother solution distillation obtains ethylbenzene, simultaneously distillation is removed second strand of solvent in the logistics and is obtained m-xylene and o-Xylol mixture, mixture mixed with toluene carry out isomerization, isomerization product and C 8As the p-Xylol of charging to obtain adding of adsorption stage, sorbent used in the method is ZSM-5 to aromatic hydrocarbons together.
USP3724170 is with C 8Aromatic hydrocarbons obtains wherein p-Xylol and ethylbenzene by at least two different adsorption stages.C 8Aromatic hydrocarbons is brought into first adsorbent bed by carrier gas, the m-xylene that is not adsorbed and o-Xylol are as inhaling excess oil first from the first adsorbent bed outflow, discharge through after the condensation, it is adsorbent bed that the p-Xylol that is adsorbed and ethylbenzene are proposed outflow first by Xian, brought into second adsorbent bedly by carrier gas, ethylbenzene is adsorbed again, and m-xylene and o-Xylol flow out adsorbent bed, discharge through condensation, second adsorbent bed process Xian raises ethylbenzene.The sorbent used ZSM-5 that is preferably silane modified processing or ZSM-8 or be the two mixture.
CN101045671A is by adsorbing C 8Aromatic hydrocarbons is divided into the first strand of material that contains ethylbenzene and p-Xylol and contains second strand of material of m-xylene o-Xylol, obtains first strand of p-Xylol in the logistics by low temperature crystallization again, and crystalline mother solution obtains ethylbenzene through fractionation by adsorption.
Summary of the invention
The purpose of this invention is to provide a kind of from C 8The method of adsorption stripping dimethyl benzene and ethylbenzene in the aromatic hydrocarbons, this method combines liquid phase adsorption-gas phase pressure-variable adsorption, can be from C 8Isolate highly purified p-Xylol and ethylbenzene in the aromatic hydrocarbons.
Provided by the invention from C 8The method of adsorption stripping dimethyl benzene and ethylbenzene comprises C in the aromatic hydrocarbons 8Aromatic hydrocarbons obtains containing the extraction oil of p-Xylol and containing raffinating oil of ethylbenzene, m-xylene and o-Xylol by liquid phase adsorption separation; With raffinating oil by the separation of gas phase pressure-variable adsorption that liquid phase adsorption separation obtains, obtain pressure-variable adsorption and inhale remaining liquid and desorption liquid, the non-aromatics in the desorption liquid is separated, obtain ethylbenzene.
The inventive method uses two step adsorption method of separations from C 8Separating paraxylene and ethylbenzene in the aromatic hydrocarbons are first with C 8Aromatic hydrocarbons is isolated p-Xylol through liquid phase adsorption separation, again with remaining C 8Aromatic hydrocarbons is isolated wherein ethylbenzene with gas phase pressure-variable adsorption partition method, obtains simultaneously containing the remaining liquid of suction of m-xylene and o-Xylol.Two step adsorption method of separations of the present invention can be from C 8Isolate highly purified p-Xylol and ethylbenzene in the aromatic hydrocarbons.
Description of drawings
Fig. 1 is the schematic flow sheet of the inventive method.
Fig. 2 is that the inventive method is used simulation moving-bed operation chart of carrying out liquid phase adsorption separation.
Embodiment
The present invention is by liquid phase adsorption separation, with C 8The strippant that the raffinate that aromatic hydrocarbons is separated into the Extract that contains p-Xylol and contains ethylbenzene, m-xylene and o-Xylol, distillation are removed in the Extract obtains extracting oil out, is highly purified p-Xylol.Raffinate is removed strippant raffinated oil, will raffinate oil and separate by the transformation Gas Phase Adsorption, isolate high purity ethylbenzene, can be used as and produce cinnamic raw material, gained is inhaled remaining liquid as xylene isomerization raw material production p-Xylol.
The inventive method is first with C 8Aromatic hydrocarbons carries out liquid phase adsorption separation, isolates p-Xylol wherein.The preferred simulation moving-bed liquid phase adsorption separation of described liquid phase adsorption separation, fractionation by adsorption C 8The temperature of aromatic hydrocarbons is 130~230 ℃, preferred 130~210 ℃.Adsorptive pressure is normal pressure.
In the simulation moving-bed liquid phase adsorption separation process, the desorption that is adsorbed component need be used strippant, and the process operation method is: with C 8Aromatic hydrocarbons is by adsorbent bed, and p-Xylol wherein is adsorbed, and all the other components flow out adsorbent bed, for containing the raffinate of strippant.Adsorb saturated after, carry out the desorption of p-Xylol with strippant flushing sorbent material, obtain containing the Extract of strippant.Raffinate and Extract are removed strippant separately, raffinated oil respectively and extract oil out, extracting oil out is highly purified p-Xylol, and wherein the content of p-Xylol is not less than 99.5 quality %, preferably is not less than 99.7 quality %.Raffinate oil and contain ethylbenzene, o-Xylol, m-xylene and non-aromatics.The preferred toluene of described strippant or p-Diethylbenzene.
The used sorbent material of liquid phase adsorption separation of the present invention comprises the zeolite of 90~96 quality % and the binding agent of 4~10 quality %.The preferred kaolin of described binding agent, attapulgite or wilkinite, the preferred BaX of described zeolite, KX or BaKX zeolite.
The preparation method of above-mentioned sorbent material is: roller forming, roasting after the NaX zeolite is mixed with binding agent.With the compound solution dipping of baric and/or potassium, namely get sorbent material after solid drying, the activation behind the dipping again.The described preferred potassium of compound of potassium, barium, nitrate or the muriate of barium of containing.
C 8Raffinating oil that aromatic hydrocarbons process liquid phase adsorption separation obtains separates through the gas phase pressure-variable adsorption, ethylbenzene is separated from raffinate oil, the process operation method is: raffinating oil of obtaining of liquid phase adsorption separation under high pressure is heated into gas phase by adsorbent bed, wherein ethylbenzene and non-aromatics are adsorbed, other component is discharged adsorbent bed, for inhaling remaining liquid, its main ingredient is o-Xylol, m-xylene, and the ethyl-benzene level of inhaling in the remaining liquid is not more than 1.5 quality %.
With adsorbent bed pressure decreased, use inert gas purge, make the absorbed component desorption, obtain desorption liquid, wherein contain ethylbenzene and non-aromatics, non-aromatics is removed namely obtain highly purified ethylbenzene.
In the above-mentioned pressure-variable adsorption lock out operation, the temperature of adsorption and desorption is 170~300 ℃, preferred 190~270 ℃, the preferred 0.4~2.0MPa of adsorptive pressure, the preferred 0.1~0.3MPa of desorption pressure.
The sorbent material that the present invention is used for the separation of gas phase pressure-variable adsorption comprises the active ingredient of 80~97 quality % and the binding agent of 3~20 quality %, the preferred kaolin of described binding agent, wilkinite or attapulgite, active ingredient preferred MFI type zeolite or MEL type zeolite.
The preferred ZSM-5 of described MFI type zeolite, the preferred ZSM-11 of MEL type zeolite.The silicon oxide of described ZSM-5 zeolite and the mol ratio of aluminum oxide are 200~800, preferred 200~600.
The preferred potassium of positively charged ion or the caesium of MFI type zeolite or MEL type zeolite.The preferred KZSM-5 zeolite of the active ingredient of described sorbent material or CsZSM-5 zeolite.
The preparation method of above-mentioned sorbent material is: roller forming, roasting namely made sorbent material after MFI zeolite or MEL zeolite were mixed with binding agent, with the compound solution dipping that contains potassium or caesium, the MFI/MEL zeolite that the rear solid drying of dipping, activation namely obtain potassium/caesium modification is the sorbent material of active ingredient.The described preferred potassium of compound of potassium, caesium, the muriate of caesium of containing.MFI zeolite or MEL zeolite are after potassium or cesium ion exchange, and the cationic exchange degree that calculates by sodium content residual after the exchange is 80~95 % by mole.
In the above-mentioned absorbent preparation method, described maturing temperature is 480~560 ℃, and drying temperature is 90~130 ℃, and activation temperature is 180~240 ℃.
C of the present invention 8Aromatic hydrocarbons is selected from the C that catalytic reforming, steam cracking or transalkylation reaction obtain 8Aromatic hydrocarbons, C 8Aromatic hydrocarbons is the mixture of ethylbenzene, p-Xylol, o-Xylol and m-xylene, and wherein ethyl-benzene level is preferably 1~30 quality %, and all the other are mainly xylene isomer, in addition, also contains a small amount of non-aromatics.
Below by description of drawings the present invention.
Among Fig. 1, C 8Aroamtic hydrocarbon raw material enters rotary valve 4 through pipeline 1, mixes by pipeline 3 entering rotary valve 4 from the strippant of pipeline 2 and circulant solution vapor from pipeline 15, enters the adsorption bed in two adsorption columns 5 and 6 again, adopts the simulation moving-bed fractionation by adsorption of carrying out.Be divided into a plurality of beds in described adsorption column 5 and 6 posts, adsorption column 5 and 6 also can be independent adsorption column or the adsorption column of a plurality of series connection.Rotary valve 4 links to each other with each adsorption bed in the adsorption column 5 and 6, controls material in the turnover of adsorption column bed by the open and close of the valve that links to each other with each adsorption bed.Enter rectifying tower 9 from rotary valve 4 Extract (being mainly p-Xylol and strippant) out through pipeline 7, strippant enters pipeline 12 at the bottom of rectifying tower, enter pipeline 15, cat head obtains extracting out oil again, for highly purified p-Xylol through pipeline 11 dischargers.(mainly be strippant from rotary valve 4 raffinate out, ethylbenzene, m-xylene, o-Xylol and non-aromatics) enter rectifying tower 10 through pipeline 8, after entering pipeline 14 and strippant from pipeline 12 mixes, the strippant that obtains at the bottom of the tower recycles, raffinating oil that cat head obtains is ethylbenzene, m-xylene, the mixture of o-Xylol and non-aromatics, enter gas phase pressure-variable adsorption separator column 16 through pipeline 13, the sorbent material of filling is at high temperature in this post, ethylbenzene during optionally absorption is raffinated oil under the condition of high voltage, m-xylene and o-Xylol then are not adsorbed, need not strippant and make adsorbent ethylbenzene desorption by reducing pressure, obtain desorption liquid.Desorption liquid is ethylbenzene and non-aromatics, enters desorption liquid rectifying tower 19 through pipeline 18, and non-aromatics is discharged through pipeline 20 by cat head, and high purity ethylbenzene is discharged by tower bottom tube line 21.The remaining liquid of the suction that pressure-variable adsorption obtains is m-xylene and o-Xylol, discharges through pipeline 17.
Further specify the present invention below by example, but the present invention is not limited to this.
Example 1
The used sorbent material of preparation liquid phase adsorption separation.
X zeolite (the multiple rising sun molecular sieve company limited in Shanghai produces) is mixed with the mass ratio of kaolin by 92: 8, roller forming, 520 ℃ of roastings 6 hours, get particle diameter and be 0.5~1.0 millimeter spheroidal particle, carry out ion-exchange with nitrate of baryta solution, Gu the liquid/volume ratio of solution and sorbent material is 10, the concentration of nitrate of baryta solution is 0.5mol/L, and the exchange degree that calculates by sodium content residual after the exchange is 95 % by mole.Solid was 100 ℃ of dryings 3 hours after the exchange, and 220 ℃ of activation obtained adsorbent A in 2 hours, and wherein BaX content is that 93.41 amount %, kaolin content are 6.59 quality %.
Example 2
Xylol is carried out liquid phase adsorption separation, separate p-Xylol wherein.
Use a cover Small-Scale Simulated Moving Bed device, consisted of by 24 pillar series connection, column interior is used for holding the high 200mm of cavity of sorbent material, diameter 40mm, the 24th pillar and the 1st pillar are by a pump in succession, the post inner fluid is circulated, and material can be introduced or discharge in the junction of each pillar all.Between raffinate outlet and the feed(raw material)inlet 7 pillars are arranged; Between feed(raw material)inlet and the Extract outlet 3 pillars are arranged; Between Extract outlet and the strippant entrance 5 pillars are arranged; Between strippant entrance and the raffinate outlet 9 pillars are arranged, each burst turnover material position as shown in Figure 2, the import and export position of material changes with certain time interval, each timed interval feed inlet and outlet is pushed ahead a pillar, feed inlet and outlet moves on to the dotted arrow position by solid arrow position among the figure, next timed interval pushes ahead by set direction, the like change the feed inlet and outlet position.
Above-mentioned simulated moving bed adsorption is separated in 140 ℃ of operations, the raw material inlet amount is 1100 Grams Per Hours, use adsorbent A, strippant is p-Diethylbenzene, the strippant injection rate is 1300 Grams Per Hours, and extracting liquid measure out is 820 Grams Per Hours, and the raffinate amount is 1580 Grams Per Hours, switched a feed inlet and outlet in per 2 minutes, the recycle pump amount is 3850 ml/hours.Fractionation by adsorption composition raw materials used and the stable rear Extract of running and raffinate sees Table 1.
Example 3
The Extract that example 2 obtains is removed the strippant p-Diethylbenzene through distillation, and obtaining p-Xylol purity is the extraction oil of 99.72 quality %, and the p-Xylol yield is 97 quality %.The strippant p-Diethylbenzene is removed in the raffinate distillation that example 2 obtains, raffinated oil, wherein ethyl-benzene level is 11.51 quality %, and all the other are m-xylene, o-Xylol and non-aromatics.
Example 4
The preparation pressure-variable adsorption separates used sorbent material.
Be that 360 NaZSM-5 (the multiple rising sun molecular sieve company limited in Shanghai) zeolite powder mixes with the mass ratio of kaolin by 92: 8 with silica/alumina molar ratio, roller forming was through 520 ℃ of roastings 6 hours.Get particle diameter and be 0.5~1.0 millimeter spheroidal particle, carry out ion-exchange with Klorvess Liquid, Gu the liquid/volume ratio of solution and sorbent material is 10, the concentration of Klorvess Liquid is 0.5mol/L, and the cationic exchange degree that calculates by sodium content residual after the exchange is 95 % by mole.Solid was 100 ℃ of dryings 3 hours after the exchange, and 220 ℃ of activation obtained adsorbent B in 2 hours, wherein contained the KZSM-5 of 92.10 quality %, the kaolin of 7.90 quality %.
Example 5
Method by example 4 prepares sorbent material C, different is, and to use silica/alumina molar ratio be that 200 NaZSM-5 zeolite and kaolin prepare sorbent material, through roller forming, roasting, ion-exchange, drying, activation, obtain sorbent material C, wherein contain the KZSM-5 of 92.16 quality %, the kaolin of 7.84 quality %, the cationic exchange degree that zeolite calculates take residual sodium content is as 82 % by mole.
Example 6
Method by example 4 prepares sorbent material D, different is with concentration is that the cesium chloride solution of the 0.55mol/L particle after to roller forming carries out ion-exchange, drying, activation, obtain sorbent material D, wherein contain the CsZSM-5 of 92.56 quality %, the kaolin of 7.44 quality %, the cationic exchange degree that zeolite calculates take residual sodium content is as 90 % by mole.
Example 7
Method by example 4 prepares sorbent material E, different is with silica/alumina molar ratio is that 500 NaZSM-5 and kaolin prepare sorbent material, after roller forming, roasting, cesium chloride solution with 0.55mol/L carries out ion-exchange, drying, activation, obtain sorbent material E, wherein contain the CsZSM-5 of 92.46 quality %, the kaolin of 7.54 quality %, the cationic exchange degree that zeolite calculates take residual sodium content is as 93.5 % by mole.
Example 8~11
It is in 150 the adsorption column that 150 gram sorbent materials are filled in aspect ratio, is that 240 ℃, pressure are that 0.45MPa, mass space velocity are 0.5h in temperature -1Condition under, with 30 the gram examples 3 obtain raffinate oil the gasification after pass into adsorption column, collect the component that is not adsorbed and be the remaining liquid of suction, then be decompressed to 0.1MPa, use 3 times to the nitrogen purging sorbent material of sorbent material volume, make the absorbed component desorption, collecting the desorption component is desorption liquid, the non-aromatics in the desorption liquid is removed in distillation, obtains ethylbenzene.The sorbent material that each example uses, charging, the remaining liquid of suction and desorption liquid composition and ethylbenzene purity and yield see Table 2.
Example 12~13
What obtain in the method fractionation by adsorption example 3 by example 8 raffinates oil, carrying out respectively pressure-variable adsorption under two kinds of different adsorption operations conditions separates, the remaining liquid of the raw material that uses and the suction that obtains and desorption liquid composition see Table 3, and the non-aromatics in the desorption liquid is removed in distillation, obtains ethylbenzene.The ethylbenzene purity that example 12 and 13 obtains is respectively 99.70 quality %, 99.71 quality %, and the ethylbenzene yield is respectively 98.69 quality %, 95.56 quality %.
Table 1
Figure BSA00000707529800071
Table 2
Figure BSA00000707529800081
Table 3
Figure BSA00000707529800082

Claims (12)

1. one kind from C 8The method of adsorption stripping dimethyl benzene and ethylbenzene comprises C in the aromatic hydrocarbons 8Aromatic hydrocarbons obtains containing the extraction oil of p-Xylol and containing raffinating oil of ethylbenzene, m-xylene and o-Xylol by liquid phase adsorption separation; With raffinating oil by the separation of gas phase pressure-variable adsorption that liquid phase adsorption separation obtains, obtain pressure-variable adsorption and inhale remaining liquid and desorption liquid, the non-aromatics in the desorption liquid is separated, obtain ethylbenzene.
2. in accordance with the method for claim 1, it is characterized in that described liquid phase adsorption separation is simulation moving-bed liquid phase adsorption separation, fractionation by adsorption C 8The temperature of aromatic hydrocarbons is 130~230 ℃.
3. in accordance with the method for claim 1, it is characterized in that in the operation of raffinating oil that gas phase pressure-variable adsorption separation liquid phase adsorption separation obtains, the temperature of adsorption and desorption is 170~300 ℃, and adsorptive pressure is 0.4~2.0MPa, and desorption pressure is 0.1~0.3MPa.
4. the content that in accordance with the method for claim 1, it is characterized in that p-Xylol in the extraction oil that liquid phase adsorption separation obtains is not less than 99.5 quality %.
5. in accordance with the method for claim 1, it is characterized in that the ethyl-benzene level that pressure-variable adsorption is inhaled in the remaining liquid is not more than 1.5 quality %.
6. in accordance with the method for claim 1, it is characterized in that the used sorbent material of liquid phase adsorption separation comprises the zeolite of 90~96 quality % and the binding agent of 4~10 quality %.
7. in accordance with the method for claim 6, it is characterized in that described binding agent is kaolin, attapulgite or wilkinite, described zeolite is selected from BaX, KX or BaKX zeolite.
8. in accordance with the method for claim 1, it is characterized in that comprising the active ingredient of 80~97 quality % and the binding agent of 3~20 quality % for the sorbent material that the gas phase pressure-variable adsorption separates, described binding agent is selected from kaolin, wilkinite or attapulgite, and active ingredient is selected from MFI type zeolite or MEL type zeolite.
9. in accordance with the method for claim 8, it is characterized in that described MFI type zeolite is ZSM-5, MEL type zeolite is ZSM-11.
10. in accordance with the method for claim 8, it is characterized in that the silicon oxide of described ZSM-5 zeolite and the mol ratio of aluminum oxide are 200~800.
11. in accordance with the method for claim 8, it is characterized in that the positively charged ion of MFI type zeolite or MEL type zeolite is potassium or caesium, and the exchange degree of potassium or caesium replacement sodium ion is 80~95 % by mole.
12. in accordance with the method for claim 1, it is characterized in that described C 8The content of ethylbenzene is 1~30 quality % in the aromatic hydrocarbons.
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CN108017502A (en) * 2016-10-28 2018-05-11 中国石油化工股份有限公司 The method of paraxylene in moving-bed adsorption separation C8 aronmatic
CN108017502B (en) * 2016-10-28 2021-08-06 中国石油化工股份有限公司 Method for adsorbing and separating p-xylene from carbon octa-aromatic hydrocarbon by simulated moving bed
CN112573985A (en) * 2019-09-29 2021-03-30 中国石油化工股份有限公司 From C8Method for producing paraxylene and ethylbenzene by aromatic hydrocarbon
CN112573985B (en) * 2019-09-29 2023-04-07 中国石油化工股份有限公司 From C 8 Method for producing paraxylene and ethylbenzene by aromatic hydrocarbon
WO2023142770A1 (en) * 2022-01-26 2023-08-03 浙江大学杭州国际科创中心 Method for preferential adsorption and separation of ethylbenzene from c8 aromatic hydrocarbon isomeride mixture

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