CN103987434A - System and process for recovering products using simulated-moving-bed adsorption - Google Patents

Abstract

In a process for separating components in a feed stream by simulated countercurrent adsorptive separation, the process according to various aspects includes withdrawing an extract stream through one transfer line that contains residual fluid away from the adsorptive separation chamber. The process also includes directing an initial portion of the extract stream, including at least a portion of the residual fluid withdrawn through the one transfer line toward a first destination. The process further includes directing a subsequent portion of the extract stream withdrawn through the one transfer line toward a second destination.

Description

Use moving-bed adsorption to reclaim the system and method for product

Prioity claim

The application advocates in the U.S. Provisional Application the 61/570th of application on December 15th, 2011, the right of 938 and 61/570, No. 940.

Invention field

The present invention relates to a kind of for the method from incoming flow adsorbing separation by preferential absorbed component.More specifically, the present invention relates to a kind of method of the continuous analog adverse current adsorbing separation for aromatic hydrocarbon.

Background of invention

In chemistry and fiber industry, paraxylene and meta-xylene are important raw material.Derived from the terephthalic acid (TPA) of paraxylene for the production of widely used polyester textile and other article now.Meta-xylene is for the manufacture of the raw material of a large amount of useful products that comprises pesticide and M-phthalic acid.By adsorbing separation, crystallization with fractionation is a kind of or combination is used for obtaining these xylene isomers, wherein adsorbing separation is captured as main paraxylene isomers and the thumping majority market share of newly-built factory.

Method for adsorbing separation is described in document widely.For example, the generality that relevant paraxylene reclaims is described the 70th page of 1970 editions September that is presented on CHEMICAL ENGINEERING PROGRESS (the 66th volume, the 9th phase).Available reference document is existing long historical, and it is described useful adsorbent and strippant, comprises the machine components of the simulated moving bed system of the rotary valve flowing for dispense liquid, inside and the control system of adsorbent chamber.Use simulation moving-bedly by make continuously principle that the component of fluid mixture separates as US2 with solid absorbent contact, institute sets forth in 985,589.US3,997,620 reclaim paraxylene by simulation moving-bed application of principle in the incoming flow that certainly contains C8 aromatic hydrocarbons, and US4, and 326,092 teachings reclaim from the meta-xylene of C8 aromatic hydrocarbons stream.

The adsorption separation unit of processing C8 aromatic hydrocarbons is generally used the simulation adverse current of adsorbent and incoming flow to move.Carry out this simulation with the commercial technology of setting up, wherein adsorbent is immobilizated in the appropriate location in one or more cylindrical adsorbent chamber, and in method, the related position that flows to into and leave chamber is shifted lentamente along the length of implantation.Typical case's adsorption separation unit illustrate and comprises at least four streams (charging, strippant, extract and extract remainder) for this program in Fig. 8, and incoming flow and strippant flow to and enter the room and position that extract stream and raffinate stream are left chamber is shifted with setting interval in same direction simultaneously.Each displacement of the position of point of delivery removes liquid by liquid delivery to indoor different beds or from indoor different beds.Generally speaking, for adsorbent in simulating chamber moves with respect to the adverse current of fluid stream, described stream is at indoor general direction (, the downstream direction) superior displacement flowing at fluid, move up in contrary (, upstream) side with simulation solid absorbent.When each flows to into or leave while being associated bed, reuse the pipeline at these point of delivery places, and therefore certain four kinds of of processing in stream of each pipeline carrying of place a bit of circulation.

This technology thinks that the existence of residual compounds in feed-line can have adverse effect to simulated moving bed process.US3,201,491, US5,750,820, US5,884,777, US6,004,518 and US6,149,874 teachings are rinsed pipeline for incoming flow being delivered to adsorbent chamber using the means as increasing the purity that reclaims extract or sorbate component.When this pipeline is subsequently for taking out when extract stream from chamber, this flushing avoids extract stream to be subject to remaining in the pollution of the extract remainder component of the charging in this pipeline.US5,912,395 teachings are when this pipeline is when being delivered to adsorbent chamber by incoming flow, the flushing of this pipeline just for removing raffinate stream to avoid charging to be subject to the pollution of extract remainder.All these bibliography teachings are rinsed these pipelines and are back in adsorbent chamber, therefore increase indoor separating load.US7,208,651 disclose one or two inclusion that removes the feed-line of raffinate stream of rinsing previously the material for taking out by incoming mixture with from adsorption zone makes it away from adsorbent chamber.Remaining extract remainder in flushing feed-line is to engage as the charging to raffinate column with raffinate stream.US6,149,874 announcements are rinsed remaining charging to boost-up circuit from the common section of fluid distribution pipe.

A previous illustrative system utilization is rinsed for three times and is disposed the residual fluid remaining in feed-line at the most.First flushing is certainly lucky for removing the remaining extract of feed-line dislocation of extract stream by the fluid of the desorption zone of the chamber under desorbent stream, and via rotary valve, remaining extract is guided to the feed-line just flowing for injecting feeding.Because the volume in feed-line equates, so extract is displaced to the previously remaining charging in feed-line in the adsorbent chamber directly over current incoming flow position with strippant fluid, the incoming flow that remaining charging can be indoor with adsorbing separation is separated, and avoid extract stream to be subject to remaining in the pollution of the remaining charging in feed-line in the time that extract stream is displaced to the feed-line previously being occupied by incoming flow subsequently.In addition, the charging that remains in feed-line for dislocation from the remaining extract of first flushing is for being taken out by extract stream subsequently, thus the productive rate of increase extraction product.

Illustrative system comprises that secondary rinses sometimes.Secondary rinses and utilizes flush fluid (being generally strippant) by feed-line and to the chamber under extract pipeline.Secondary rinses to be provided by this feed-line of strippant " washing " to minimize the amount that comprises extract remainder, charging and can remain in the pollutant of other component in feed-line after first flushing, and these materials are not taken out from feed-line by extract.Because previously rinsed this feed-line by strippant and extract via first flushing, so rinsing, secondary is generally used for needing in the application of high-purity extract.Secondary rinses and the previously extract in feed-line and desorbent material propelling movement will be back in adsorbing separation chamber.Secondary rinses the optional flushing for the high-purity demand for meeting extraction product.

In some systems, also utilize for the third time and rinse.Rinse for the third time the feed-line that comprises that flushing had previously been occupied by extract remainder taking-up stream.Rinse for the third time and remove remaining extract remainder for feed-line since then and in the time that feed-line is arrived soon after in incoming flow, be back to adsorbent chamber with charging note to limit this extract remainder.Because raffinate stream consumes the extract component of wanting, make remaining extract remainder note be not back to otherwise will increase separation demand to remove in the adsorbing separation chamber of this extra extract remainder material so rinse for the third time.Rinse to complete away from adsorbing separation chamber for the third time by using from the fluid flushing feed-line of interface of the chamber that is adjacent to feed-line.

Summary of the invention

According to various schemes, provide a kind of for carry out the method for the component of separating feed stream by simulation adverse current adsorbing separation.The method comprises along many adsorbing separation chambers and via two different corresponding feed-lines, incoming flow and desorbent stream being introduced in two distinct interfaces.This incoming flow has at least one preferential absorbed component and at least one non-preferential absorbed component.These many adsorbing separation chambers have the multiple beds connected in series with fluid mode of communicating, and comprise a predetermined number interval interface and be communicated with for fluid being introduced into the corresponding feed-line of adsorbing separation chamber neutralization from adsorbing separation chamber removing fluids with described interface fluid.The method also comprises via two distinct interfaces of many adsorbing separation chambers takes out extract stream and raffinate stream through two different corresponding feed-lines.Comprise via a feed-line that contains residual fluid and take out in extract stream and raffinate stream one with away from adsorbing separation chamber according to the method for this scheme.The method further comprises the initial part of at least a portion that comprises the residual fluid of taking out via a feed-line of in extract stream and raffinate stream first destination of leading.The method also comprises the further part of second destination of leading in extract stream and the raffinate stream of taking out via a feed-line.

According to one side, this second destination is the entrance of in extract fractionating column and extract remainder fractionating column.According on the other hand, this first destination is the destination that is different from the entrance of extract fractionating column or the entrance of extract remainder fractionating column.In this way, at least this part of the method restriction residual fluid enters in extract fractionating column and extract remainder fractionating column, at least this part of this residual fluid otherwise can pollute from the product of described fractionating column or increase energy consumption.According on the one hand, this first destination is for this part of of extract stream and raffinate stream and residual fluid is recycled to adsorbing separation chamber to reduce the recirculation line of energy requirement.

Accompanying drawing summary

Fig. 1 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 2 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 3 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 4 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 5 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 6 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 7 is according to the reduced graph of the moving-bed adsorption method of various embodiments of the present invention;

Fig. 8 is according to the composition diagram of the fluid in the moving-bed adsorption separation chamber of various embodiments of the present invention;

Fig. 9 is according to the perspective view of the rotary valve of various embodiments of the present invention;

Figure 10 to Figure 12 is the rate of volume flow of feed-line is passed through in explanation curve map according to the fluid of various embodiments of the present invention; With

Figure 13 is the reduced graph of prior art moving-bed adsorption method.

It will be apparent to those skilled in the art that for simple and clear for the purpose of and illustrate that assembly and described assembly in each figure may not draw in proportion.For example, can lavish praise on oneself with respect to other assembly size and/or relative positioning understanding to various embodiment of the present invention with help improvement of some assemblies in each figure.In addition, conventionally common and understandable assembly useful or necessary in commericially feasible embodiment is not described, to promote less the inspecting of the obstruction of these various embodiments of the present invention.To further understand, can specificly occur that order describes some action and/or step, it will be appreciated by those skilled in the art that this particularity in fact not requiring about order simultaneously.Also will understand, term used herein and expressing have as above set forth by understood by one of ordinary skill in the art as meet the general technology implication of these terms and expression, otherwise set forth in this article except the situation of different specific meanings.

Detailed description of the invention

Adsorbing separation is applied to the recovery of hydrocarbons and other chemical products.Use the Chemical Decomposition of the method for having disclosed comprise by the mixture of aromatic hydrocarbons be separated into specific arene isomer, by linear aliphatic hydrocarbon from non-linear aliphatic hydrocarbon separates with in alkene, separating and for example sugared separation of carbohydrate by separating in the incoming mixture of any self-contained aromatic hydrocarbons of paraffin or aromatic hydrocarbons and paraffin, for the separating of the chipal compounds of medicine and fine chemicals, for example alcohol of oxygenate and ether.Aromatic hydrocarbons separator comprises the mixture of mononuclear aromatics and the mixture of dimethylnaphthalene that dialkyl group replaces.Be applied as that the mixture from C8 aromatic hydrocarbons reclaims paraxylene and/or meta-xylene owing to the high-purity to these products requires conventionally so not limiting the primary commercial that forms the focus of previous bibliography and the following description of the present invention in situation of the present invention.The restructuring of the catalysis by naphtha conventionally of these C8 aromatic hydrocarbons, then carries out extraction and fractionation and derivative in aromatic hydrocarbons complex, or derivative in these complexs by being rich in the transalkylation of stream of aromatic hydrocarbons or isomerization; C8 aromatic hydrocarbons generally comprises the mixture of xylene isomer and ethylbenzene.Use moving-bed adsorption processing C8 aromatic hydrocarbons to relate generally to the recovery of high-purity paraxylene or high pureness meta-dimethyl benzene; High-purity is normally defined the product of wanting of at least 99.5 weight-%, and preferred at least 99.7 weight-%.Although should be understood that to describe in detail below to pay close attention to from the dimethylbenzene mixing and ethylbenzene and flow back to receipts high-purity paraxylene, the invention is not restricted to this, and also applicable to separating in the stream of self-contained two or more components of other component.As used herein, term " preferential absorbed component " refers to one or more components of the incoming flow of more preferably adsorbing than the one or more non-preferential absorbed component of incoming flow.

The present invention is generally used for simulating as described above in the adsorption separating method that the adverse current of adsorbent and surrounding liquid moves, but the present invention also can as be disclosed in US4,402,832 and US4, in the concurrent continuation method of the concurrent continuation method in 478,721, put into practice.Adsorbent and strippant are what know in the function aspect the chromatography of liquid component and character, and the additional description of these absorption general principles can be with reference to the US4 being incorporated herein, 642,397.Counter-flow moving bed or simulation moving-bed counter-current flow system has the separative efficiency more much bigger than fixed bed system to these separation, this is because in the quantity-produced situation of continuous feed stream and extract and extract remainder, and sorption and desorption operation is recurred.The best explain of simulated moving bed process provides in the adsorbing separation chapters and sections (Adsorptive Separation section) of the 563rd page of Kirk-Othmer chemical encyclopedia (Kirk-Othmer Encyclopedia of Chemical Technology).

Fig. 1 is according to the schematic diagram of moving-bed adsorption method on the one hand.The method makes incoming flow 5 sequentially contact with separating and extracting logistics 15 and raffinate stream 20 with desorbent stream 10 with the adsorbent being contained in container.In simulation moving-bed counter-current flow system, multiple liquid chargings and product access point or interface 25 along adsorbent chamber 100 and 105 downwards gradually displacement simulation be contained in moving up of adsorbent in chamber.Adsorbent in moving-bed adsorption method is contained in the multiple beds in one or more containers or chamber; In Fig. 1, show two chambers 100 and 105 of serial, but can use single ventricle 902 as illustrated in Figure 13 or other several chambers of serial.Each container 100 and 105 contains multiple adsorbent beds in processing space.Each in container has the several interfaces 25 relevant with the number of adsorbent bed, and the position of incoming flow 5, desorbent stream 10, extract stream 15 and raffinate stream 20 is shifted to simulate mobile adsorbent bed along interface 25.The circulating fluid that comprises strippant, extract and extract remainder cycles through chamber via pump 110 and 115 respectively.The system of controlled circulation liquid flow is described in US5, and in 595,665, but the details of these systems is not by the present invention is essential.As for example, at () US3, the carousel-type valve 300 characterizing in 040,777 and US3,422,848 is carried out stream and is shifted to simulate counter-current flow along adsorbent chamber.Although describe in this article rotary disc valve 300, but also expection is used for making other system and the device of stream along adsorbent chamber displacement in this article, comprise the mobile system of utilizing multiple valves to control to flow to self-absorbent chamber 100 and/or 105, as for example, at () US6, described in 149,874.

Referring to Fig. 9, describe the simplification exploded view for the exemplary rotary valve 300 of adsorption separation system and method.Base plate 474 comprises several interfaces 476.The number of interface 476 equals the total number of the feed-line on chamber.Base plate 474 also comprises several tracks 478.The number of track 478 equals the number for clean input, output and the clean-up line of adsorption separation unit (not showing at Fig. 9).Clean input, output and clean-up line are communicated with dedicated track 478 fluids separately.Crossover line 470 makes given track 478 and is communicated with to stationary interface 476 fluids.In an example, clean input comprises charging input and strippant input, and clean output comprises extract output and extract remainder output, and clean-up line is included in the clean-up line between and four.In the time that rotor 480 rotates as indicated, by crossover line 470, continuous interface 476 fluids of each track 478 and next are communicated with.Sealing sheet 472 is also provided.

Can characterize as follows as illustrated in all figure and in the moving-bed adsorption of below further discussing about each aspect of the present invention described herein related various streams." incoming flow " is for containing the mixture of the one or more extract components that separate by method or preferential absorbed component and one or more extract remainder components or non-preferential absorbed component." extract stream " comprises the extract component that is easy to selection or preferential absorption by adsorbent, is generally wanted product." raffinate stream " comprises the one or more extract remainder components that are not easy to selective absorption or non-preferential absorption." strippant " refers to make the material of extract component desorb, its component for incoming flow be generally inertia and can be easy to (for example) via distillation separate with in extract remainder from extract.

Contain concentration with respect to the product out of the ordinary from the method strippant between 0% and 100% from the extract stream 15 of illustrated scheme and raffinate stream 20.Strippant generally respectively raffinate column 150 as illustrated in Figure 1 with in extract tower 175, separate with in extract component from extract remainder by conventional fractionation, and be recycled to stream 10' to be back to method by extract remainder column bottoms pump 160 and extract column bottoms pump 185.Fig. 1 shows that strippant is as the bottoms from tower out of the ordinary, and hint strippant is than extract or extract remainder weight; The different commercial that are used for the separation of C8 aromatic hydrocarbons are used light or heavy strippant, and therefore in some applications, strippant can separate at diverse location place with 175 along fractionating column 150.In tower 150 and 175 out of the ordinary, retrieve raffinate product 170 and the extraction product 195 from method from raffinate stream and extract stream; Conventionally mainly comprise one or both in paraxylene and meta-xylene from the extraction product 195 of the separation of C8 aromatic hydrocarbons, wherein raffinate product 170 is mainly non-absorption C8 aromatic hydrocarbons and ethylbenzene.

The liquid stream (for example, incoming flow 5, adsorbent stream 10, raffinate stream 20 and extract stream 15) that enters and leave adsorbent chamber 100 and 105 via liquid access point or interface 25 is on divided into adsorbent chamber 100 and 105 single area of moving in the time that interface 25 is shifted at stream effectively.Should note, although many discussions are herein referring to the position of the stream in Fig. 1 and Fig. 1, Fig. 1 only illustrate circulation be everlasting the different step place of circulation while being shifted downstream in the current location of one step place stream or the instantaneous state (snapshot) of method.In the time flowing to downstream displacement, fluid composition and corresponding district are shifted downstream with it.In one embodiment, stream simultaneously when advanced downstream relative to each other conventionally keeps constant at described stream along interface 25 with respect to the access point of adsorbing separation chamber 100 and 105 or the position of interface 25.In an example, for each step, described stream is advanced downstream single face 25 separately, and in whole cycle period, often first-classly occupies each interface 25 once.According to an embodiment, described stream steps to follow-up interface 25 by rotary valve 300 is rotated simultaneously, and maintains the predetermined stepping time interval at special interface 25 or step place.In one embodiment, interface 25 between having 4 and 100, there is in another embodiment the interface between 12 and 48, and have the interface between 20 and 30 in another embodiment, and have an equal number corresponding feed-line.In one embodiment, one or more adsorbing separation chamber 100 and 105 comprises 24 interfaces, and every first-class each being displaced to during complete cycle in 24 interfaces 25, makes often first-classly to occupy each interface 25 and corresponding feed-line in cycle period.In this example, circulation in one embodiment can be between 20 minutes and 40 minutes, and in another embodiment between 22 minutes and 35 minutes.In one embodiment, stepping time interval is between 30 seconds and 2 minutes.In another embodiment, stepping time interval is between 45 seconds and 1 point 30 seconds.In another embodiment, stepping time interval is between 50 seconds and 1 point 15 seconds.The example at typical case's stepping time interval can be 1 minute.

Consider this situation, Fig. 8 illustrates the instantaneous state of composition distribution of the fluid in adsorbing separation chamber (for the purpose of simple, single adsorbing separation chamber 100 being described in Fig. 8) and the corresponding district that adsorbing separation chamber 100 is divided into.Adsorption zone 50 is between feed entrance stream 5 and extract remainder outlet stream 20.In Ci district, incoming flow 5 Contact-sorption agent, sorption extraction thing component, and take out raffinate stream 20.As illustrated in figure, can comprise at composition the position taking-up raffinate stream 20 of extract remainder fluid 454 and a little (if yes) extract fluid 450.Zone purification 55 is immediately in the upstream with respect to fluid stream, and zone purification 55 is defined as the adsorbent between extract outlet stream 15 and feed entrance stream 5.In zone purification 55, the non-selective voidage dislocation of extract remainder component self-absorbent and pore volume or the surface desorption of self-absorbent, leave desorption zone 60 and be shifted so far in district by transmitting the part of extract stream material.Be defined as the adsorbent between desorbent stream 10 and extract stream 15 in the desorption zone 60 of 55 upstreams, zone purification.Transmit strippant in district be so far displaced in adsorption zone 50 by with the previous extract component of adsorbing that contacts of charging.Can take out extract stream 15 in the position that comprises extract fluid 450 and a little (if yes) extract remainder fluid 454 of chamber 100.Buffering area 65 between extract remainder outlet stream 20 and strippant inlet streams 10 prevents the pollution of extract, and this is to be back in adsorption zone 50 because the part of desorbent stream enters the extract remainder material dislocation existing in buffering area Yi Jiangbi district.Buffering area 65 contains enough adsorbents to prevent that extract remainder transfer components is in desorption zone 60 and pollute extract stream 15.

Each in district as described above is generally carried out via multiple compartments or " bed ", as US2, described in 985,589.The position of described various streams is by horizontal liquid collection/distribution grid and structurally separated from one another.Each grid is connected to the feed-line of definition point of delivery, wherein processes stream and enters and leave adsorbent chamber at this some place.This configuration promotes the distribution at indoor fluid via eliminating channel and other unavailable component, prevent with reverse mixing of convection current of fluid in the direction of main fluid flowing opposite, and prevent that adsorbent from passing the migration of chamber.That each in district as described above comprises is conventionally multiple (2 to 10, and be more typically 3 to 8) bed.Typical moving-bed adsorption unit comprises 24 adsorbent beds.

In Fig. 1, be easy to obvious, when when transporting that specific stream enters or the feed-line that departs from access point 25 places of adsorbent chamber keeps idle in a step end, it forms compound whole of those streams by retaining until these compounds flow to flow by second removes in pipeline.Thus, should note, in Fig. 1, only feed-line is (in illustration, these pipelines that current promotion fluid flows through), sentence and in the time that fluid stream is displaced to follow-up interface 25, promote fluid to flow but middle feed-line is present in each in interface 25 along chamber 100 and 105.After stream is displaced to subsequent delivery pipeline, staying existing residual fluid in feed-line or the compound of not using therefore will take out the initial part that flows as the processing removing from method or at feed-line, stream carrying pressure in adsorbent chamber time is pressed in adsorbent chamber from method.Figure 13 explanation will not used feed-line to be shown as dotted line and the current feed-line for example, being occupied by stream (, stream 920) will be shown as to the solid line extending from the interface of adsorbing separation chamber 902.

Be back to Fig. 1, as described above, the existence of the residual fluid in feed-line can have adverse effect to the usefulness of moving-bed adsorption separation method.For example, the remaining extract remainder that had previously removed the feed-line of raffinate stream 20 for self-absorbent chamber can rinse to adsorbent chamber 105 by incoming flow 5 in the time that incoming flow 5 is displaced to those feed-lines in subsequent step.Similarly, previously can in the time that being displaced to feed-line in subsequent step, extract stream 15 remove from those feed-lines by raffinate stream 15 for the remaining charging of the feed-line that incoming flow 5 is introduced into adsorbent chamber.The remaining extract that equally, had previously removed the feed-line of extract stream for self-absorbent chamber can be rinsed and is back in adsorbent chamber 100 by desorbent stream 10 in the time that desorbent stream 10 is arrived soon after those feed-lines.

According to one side, the first flushing of method and system comprises pours 30 for the first time, pours for the first time 30 the remaining charging in the feed-line previously being occupied by incoming flow 5 is rinsed to adsorbing separation chamber 105, and more specifically, rinse to zone purification 55.Can, advantageously by pouring for the first time near the 30 feed-lines current feed-line being occupied by incoming flow 5 that guide to zone purification 55 with near incoming flow 5 during remaining charging is introduced into adsorbing separation chamber 105, remaining charging can be separated in adsorbing separation chamber 105.In one embodiment, can guide to the feed-line in two feed-lines of incoming flow 5 of zone purification 55 by pouring for the first time 30, and more preferably guide to the feed-line that is adjacent to incoming flow 5, as illustrated in Figure 1.In one embodiment, pour for the first time the flush fluid that 30 utilizations mainly comprise preferential absorbed component, strippant and/or inert component.In other words a little (if yes) non-preferential absorbed component that, flush fluid preferably includes charging to limit the pollution of extract stream 15 in the time that extract stream arrives feed-line during subsequent step.

The first flushing of method and system can comprise from the feed-line cleaning and removing residual extract fluid previously being occupied by extract stream makes it go out for the first time 35 away from adsorbent chamber.Extract fluid is then delivered to and pours for the first time 30 feed-lines as flush fluid together with the first flush fluid rinsing, and for remaining charging is rinsed to the zone purification of adsorbing separation chamber 105, as described previously from the feed-line previously being occupied by incoming flow.In one embodiment, go out for the first time 35 utilizations and rinse from the fluid of the desorption zone 60 of chamber 100 feed-line that mainly comprises strippant.In this way, after the remaining extract fluid of going out for the first time in the feed-line that 35 flushings had previously occupied by extract stream 15, few extract fluid remains in feed-line.Advantageously, by will go out for the first time 35 with pour 30 for the first time and couple, residual fluid in feed-line can be used for rinsing other feed-line, thereby the total amount of the required fluid of minishing method and increase the productive rate of method by catching these fluids, reaches the feed-line of previously discussing simultaneously and rinses object.In addition, first pairing of rinsing be provided for pouring for the first time 30 mainly comprise strippant and the flush fluid from the preferential absorbed component of remaining extract fluid.Equally, this pairing is provided for pouring for the first time 30 the flush fluid that comprises few non-preferential absorbed component.In one embodiment, comprise strippant and the preferential absorbed component higher than 99 % by weight for pouring for the first time 30 flush fluid.In another embodiment, flush fluid comprises the non-preferential absorbed component lower than 0.005 % by weight.

According to an embodiment, secondary rinse 40 for from subsequently by the feed-line cleaning and removing residual fluid being occupied by extract stream 15 to remove pollutant from feed-line.Secondary rinse 40 by with feed-line to remove pollutant and advantageously provide the increase purity of extract stream before via its taking-up extract stream 15 from this feed-line.Previous system utilization rinses to feed-line and towards adsorbing separation chamber strippant to rinse subsequently by the inclusion of the feed-line for taking out extract stream.This rinse transport towards adsorbing separation chamber via feed-line and in the zone purification of adsorbing separation chamber so that its purifying to be provided.

The secondary of having identified the previous system of previously discussing rinses and produces effectiveness or energy punishment.Particularly, because secondary rinses 40 use strippants, preferential the remnants in feed-line absorbed component/strippant fluid is rinsed to adsorbing separation chamber, so this feed-line almost comprises strippant completely after secondary rinses.Before removing extract, take out remaining strippant initially the surging as fluid in this feed-line by extract stream subsequently.This extract stream of surging that comprises remaining strippant is guided to extract fractionating column 175, and wherein extract stream fractionates out as bottom product and is recycled to the first Room 100 with strippant recirculation flow.But in order to enter tower 175, surging of the remaining strippant in the time starting to remove extract in feed-line also must be heated before entering the 175 confession fractionation of extract tower.For example, in the incoming flow of dimethylbenzene certainly mixing when separating paraxylene, the strippant taking out is heated to 300 DEG C from 150 DEG C, thereby causes energy or effectiveness punishment by extract stream.In other words, because this initial residual piece stream (slug) of strippant contains seldom (if yes) extraction product of wanting, so need sizable energy to input, temperature is increased to extract Fractionator Bottom outlet temperature, the benefit in the extraction product yield aspects increasing is not provided simultaneously.

For fear of this effectiveness and energy punishment, according to one side, secondary rinses 40 makes it away from adsorbing separation chamber 100 (that is, contrary with previous system) from feed-line 45 cleaning and removing residual fluids, and remaining strippant is not accumulated in feed-line 45.It should be noted that in step illustrated in fig. 1, feed-line 45 rinses 40 for secondary, but formerly, during front or rear continuous step, secondary rinses 40 can be together with stream displacement and for removing residual fluid from other feed-line.More specifically, be better than and use desorbent stream from feed-line 45 cleaning and removing residual fluids (this residual fluid can mainly be included in to pour for the first time and remain in preferential absorbed component and the strippant in feed-line after 30), make it away from adsorbent chamber 100 from the fluid being adjacent to corresponding to the zone purification of the feed-line interface 45' of this feed-line for cleaning and removing residual fluid.Then can feeding secondary flushing flow for further processing.In one embodiment, by pipeline 40', secondary flushing flow is transported to fluid re-circulation pipeline 10'.Fluid re-circulation pipeline 10' can mainly comprise and separate and recycle the strippant that is back to adsorbing separation chamber 100 via fractionating column 150 with 175, and in adsorbing separation chamber 100, this strippant is reused in method.In one embodiment, the bottom that secondary flushing flow is transported to extract remainder fractionating column 150 via pipeline 40' divides 155, in this bottom points 155 secondary flushing flow with the strippant combination separating by extract remainder fractionating column 150 and at the bottom of via extract remainder pump 160 be transported to fluid re-circulation pipeline 10'.In another embodiment, the bottom that secondary flushing flow is transported to extract fractionating column 175 via pipeline 40' divides 180, in this bottom points 180 secondary flushing flow with the strippant combination separating by extract fractionating column 175 and at the bottom of via extract pump 185 be transported to fluid re-circulation pipeline 10'.

Because be similar to subsequently the extract stream of taking out from feed-line 45 15 from the composition of this fluid of zone purification 55, will be advantageously similar to wanted extract and form so rinse at the secondary of amendment the composition that remains in the residual fluid in a pipeline after 40.For this reason, in one embodiment, by in two feed-lines of the current feed-line being occupied by extract stream 15 or interface and better secondary in feed-line or the interface of the current feed-line being occupied by extract stream 15 rinse 40 and rinse feed-lines 45, this is will to have the composition that is similar to extract stream 15 most because be adjacent near the zone purification fluid of interface extract feed-line.In one embodiment, zone purification fluid has strippant and the preferential absorbed component higher than 99%.In another embodiment, zone purification fluid has the non-preferential absorbed component lower than 0.005%.In addition, as described previously with pouring for the first time 30 while carrying out cleaning and removing residual charging, rinse 40 according to the secondary of an embodiment and be positioned the current feed-line being occupied by extract stream 15 and current by pouring for the first time between 30 feed-lines that occupy, make feed-line 45 mainly by from pouring for the first time 30 but not the residual fluid filling of incoming flow 5.The method advantageously reduces extract stream 15 and is subject to the degree of the pollution of remaining charging.

In addition, in one embodiment, will will subsequently the fluid in the feed-line taking out by extract stream 15 45 be transported to extract fractionating column 175 with via separated.Interior to be transported to the residual fluid heating in the feed-line 45 of extract fractionating column 175 by extract stream at extract fractionating column 175.The cause for this reason composition of residual fluid is similar to extract stream 15, so the fractionation of this fluid will cause the increase of wanted extraction product 195 to be reclaimed.Therefore, be different from existing system, that carries and be transported to extract fractionating column 175 by extract stream 15 subsequently rinses 40 remain in fluid in feed-line 45 and will can not cause unnecessary effectiveness punishment from secondary, and this is will to cause the extra productive rate of wanted extraction product 195 but not mainly produce strippant because of the distillation of fluid for this reason.

According on the other hand illustrated in fig. 2, can during a step, take out extract stream 15 via feed-line as described previously.In the method, extract stream 15 is removed together with the residual fluid remaining in feed-line, makes extract stream cleaning and removing residual fluid make it away from feed-line.Via feed-line, the initial residual piece stream of extract stream of at least a portion that comprises residual fluid is guided to the first destination.Then via feed-line, the further part of extract stream is guided to the second destination.At least a portion of residual fluid in feed-line is guided to the first destination.In one embodiment, guide to the first destination by least 90% of residual fluid.In another embodiment, guide to the first destination by least 95% of residual fluid.In one embodiment, the second destination is the entrance 190 of extract fractionating column 175.The first destination can be the recirculation line 10' for the part of extract stream and residual fluid being recycled to adsorbing separation chamber 100.

As illustrated in fig. 2, pour for the first time 30 and can be used for the remaining feed fluid remaining in the feed-line previously being occupied by incoming flow 5 to rinse to adsorbing separation chamber 105 (as described previously), taken out by extract stream as the residual fluid in feed-line in the time that extract stream 15 arrives this feed-line in subsequent step to limit remaining feed fluid.Flush fluid preferably mainly comprise strippant and/or preferential absorbed component and comprises few non-preferential absorbed component, makes to comprise seldom non-preferential absorbed component pouring the residual fluid remaining in feed-line 30 after for the first time.In one embodiment, flush fluid comprises the non-preferential absorbed component lower than 1%, and comprises in another embodiment the non-preferential absorbed component lower than 0.005%.As described previously, can rinse the remaining extract that remain in the feed-line previously being occupied by extract stream 15 from feed-line via going out for the first time 35, and remaining extract fluid can be delivered to and pour for the first time 30 feed-lines with the flush fluid as pouring for the first time 30.Can take out fluid via going out for the first time 35 cleaning and removing residual extract fluids by being certainly adjacent to the desorption zone 60 of going out for the first time the interface 25 that 35 feed-lines are communicated with.Thus, in the time that extract stream 15 is displaced to feed-line, the residual fluid in feed-line can mainly comprise remaining extract and for example, via going out for the first time 35 flush fluids that take out from desorption zone 60 (, remaining extract and strippant).

Then referring to the more details in Fig. 2, according to the method, taking out extract stream 15 via the feed-line that comprises residual fluid, the initial residual piece stream that makes extract stream remains in the residual fluid in feed-line by being included in extract stream 15 before arriving.As previously mentioned, this initial residual piece stream of extract stream can be transported to recirculation line 10' and be back to adsorbing separation chamber 100 with recirculation.For this reason, the initial residual piece stream of extract stream can be transported to extract remainder Fractionator Bottom part 155.At point 155 places, raffinate column bottom, the residual block of fluid flows and leaves the combination of fluids of the bottom of extract remainder fractionating column 150, and this fluid is mainly included in the strippant having separated in extract remainder fractionating column 150 in one embodiment.Extract remainder column bottoms pump 160 can be used for via recirculation line 10', this residual block stream and the strippant of fluid being led back to adsorbing separation chamber 100.Or, the initial residual piece stream of extract stream can be transported to extract Fractionator Bottom part 180.Divide 180 places at extract tower bottom, the residual block of fluid flows and leaves the combination of fluids of the bottom of extract fractionating column 175, and this fluid is mainly included in the strippant having separated in extract fractionating column 175 in one embodiment.Extract column bottoms pump 185 can be used for via recirculation line 10', this residual block stream and the strippant of fluid being led back to adsorbing separation chamber 100.

In this way, at least a portion of the residual fluid of taking out by extract stream 15 is not guided to extract fractionating column entrance 190.Because the residual fluid in feed-line from first flushing 30 will contain the strippant of the percentage larger than extract stream 15, advantageously this excessive strippant is not separated in extract fractionating column 175.Because to entering the fluid heating of extract fractionating column entrance 190, if so the excessive strippant in residual fluid is introduced in extract fractionating column 175, this strippant will be heated to outlet at bottom temperature and the extra productive rate of extraction product is not provided, and therefore causes energy punishment.Therefore,, by the initial residual piece diverting flow of fluid is made excessive strippant not to be introduced in extract fractionating column 175, the amount of the required energy of system reduces.

According on the one hand, take out extract stream 15 from adsorbing separation chamber 100 and it is transported along feed-line 15'.In one embodiment, provide rotary valve 300 to make take out extract stream 15 and guided to rotary valve via feed-line, in rotary valve extract stream 15 with as single extract feed-line 15' combination illustrated in fig. 2, but expect herein and comprise other structure for each feed-line of adsorbing separation chamber 100 and 105 special extract feed-line 15' is provided.Feed-line 15' can have the extract suction line 205 being communicated with extract fractionating column entrance 190 fluids.Feed-line 15' can have with extract tower bottom divide 180 and raffinate column bottom points 155 in one or two another bottom point pipeline 210 being communicated with.Valve 215 can be provided, and it is for dividing the mobile shunting between pipeline 210 by extract stream 15 at extract tower suction line 205 and extract tower bottom.In this way, method comprise by valve 215 move to primary importance with divide via extract tower bottom pipeline 210 by the initial part extract stream 15 of at least a portion that comprises residual fluid guide to extract tower bottom divide 180 and raffinate column bottom points 155 in one.In this example, method comprise by valve 215 branch to the second place with guiding extract stream 15 by extract tower suction line 205 and guiding extract fractionating column entrance 190 for separating and extracting logistics therein 15.

According to one side, in the predetermined portions at first scheduled time or stepping time interval, the extract stream of at least a portion that comprises the residual fluid of rinsing from feed-line by extract stream is guided to the first destination by (in the time that extract stream occupies current feed-line), for example, extract tower bottom divide 180 and raffinate column bottom points 155 in one or two.Then in the predetermined portions at second scheduled time or stepping time interval, extract stream is guided to the second destination, for example, the entrance of extract fractionating column 175.Can the flow rate based on extract stream select for first scheduled time so that the residual fluid of the scheduled volume in feed-line is rinsed to the second destination or by fluid flushing to the second destination of scheduled volume.In one embodiment, 50% to 250% the fluid that it is the volume of feed-line and associated valve assembly that first scheduled time can be enough to volume guides to the first destination, and is that 80% to 150% fluid of the volume of feed-line and associated valve assembly guides to the first destination in another embodiment by volume.In one embodiment, second scheduled time can be the remainder at stepping time interval, made in the remainder at stepping time interval, extract stream 15 to be guided to extract tower entrance 190 for separating and extracting logistics 15 in extract fractionating column 175.Also can select the scheduled time so that whole or at least a portion of the residual fluid in feed-line is guided to the first destination, make residual fluid not to be introduced in extract fractionating column to provide energy to save.Similarly, the extract stream of the first predetermined can be guided to the first destination and the extract stream of the second predetermined can be guided to the second destination.The first predetermined can be with identical for the first described volume of the scheduled time above.The second predetermined can be the residual volume of the extract stream of taking out via feed-line in stepping time interim.In one embodiment, first scheduled time stepping time interval 10% and 90% between.In this embodiment, second scheduled time stepping time interval 10% and 90% between.In another embodiment, first scheduled time stepping time interval 20% and 40% between.In this another embodiment, second scheduled time stepping time interval 60% and 80% between.

In another embodiment, method comprises that the composition that monitors extract stream (comprising any residual fluid) is with amount or the percentage of the component in decision set compound.For example, component can be the one in preferential absorbed component, strippant component or non-preferential absorbed component.Be included in when composition comprises the component of the first predetermined content extract stream 15 and any residual fluid are guided to the first destination according to the method for this embodiment, and in the time that composition comprises the component of the second predetermined content, extract stream 15 is guided to the second destination.For example, method can comprise that the composition that monitors extract stream 15 is to judge the amount that is present in the strippant in stream.According to this example, the amount that method can be included in strippant guides to extract stream during higher than critical value the first destination and extract stream is guided to the second destination in the amount of strippant during lower than critical value.In this way, the amount that is transported to the strippant of extract fractionating column entrance 190 can reduce.

Advantageously, according to the method, the secondary of previous system rinses 40 and can omit.In this way, method can be used a feed-line on less.For example, method only can be used six or seven feed-lines but not as seven or eight feed-lines required in previous system.In one embodiment, method can be used the rotary valve 300 only with six or seven tracks, and these six or seven tracks comprise for extract stream, raffinate stream, incoming flow and desorbent stream and go out for the first time 35, pour for the first time 30 and optionally rinse for the third time 46 track.The method advantageously allows to improve the existing adsorption separation system with six and seven track rotary valves to utilize according to the present invention of the method.

Now transfer referring to Fig. 3, basis adsorption separation system and method is on the other hand described.According in this respect, can during a step, take out raffinate stream 20 via feed-line as described previously.In the method, raffinate stream 20 is removed together with the residual fluid remaining in raffinate stream feed-line, makes raffinate stream 20 cleaning and removing residual fluids make it away from feed-line.Be similar in this respect described above and aspect illustrated in fig. 2 part be, the initial residual piece stream of raffinate stream is guided to the first destination.Then the further part of raffinate stream is guided to the second destination.At least a portion of residual fluid in feed-line is guided to the first destination.In one embodiment, guide to the first destination by least 90% of residual fluid.In another embodiment, guide to the first destination by least 95% of residual fluid.In one aspect, the second destination is the entrance 165 of extract remainder fractionating column 150.The first destination can be the recirculation line 10' for the part of raffinate stream and residual fluid being recycled to adsorbing separation chamber 100.Thus, by the part recirculation of fluid is back to adsorbing separation chamber 100, the amount of the fluid of processing by extract remainder fractionating column 150 can reduce.

As illustrated in Figure 3, in one embodiment, previously occupied by desorbent stream 10 feed-line being occupied by raffinate stream 20.Thus, in the time that raffinate stream arrives feed-line in subsequent step, feed-line can mainly comprise remaining strippant fluid.

Then referring to the more details in Fig. 3, according in this respect, taking out raffinate stream 20 via the feed-line that comprises residual fluid, the initial residual piece stream that makes raffinate stream remains in the residual fluid in feed-line by being included in raffinate stream 20 before arriving.As previously mentioned, this initial residual piece stream of raffinate stream can be transported to recirculation line 10' and be back to adsorbing separation chamber 100 with recirculation., be similar to previously about the described method of Fig. 2 for this reason, the initial residual piece stream of raffinate stream 20 can be transported to extract remainder Fractionator Bottom part 155.At point 155 places, raffinate column bottom, the residual block of fluid flows and leaves the combination of fluids of the bottom of extract remainder fractionating column 150, and this fluid is mainly included in the strippant having separated in extract remainder fractionating column 150 in one embodiment.Extract remainder column bottoms pump 160 can be used for via recirculation line 10', this residual block stream and the strippant of fluid being led back to adsorbing separation chamber 100.Or, the initial residual piece stream of raffinate stream 20 can be transported to extract Fractionator Bottom part 180.Divide 180 places at extract tower bottom, the residual block of fluid flows and leaves the combination of fluids of the bottom of extract fractionating column 175, and this fluid is mainly included in the strippant having separated in extract fractionating column 175 in one embodiment.Similarly, extract column bottoms pump 185 can be used for via recirculation line 10', this residual block stream and the strippant of fluid being led back to adsorbing separation chamber 100.

In this way, at least a portion of the residual fluid of taking out by raffinate stream 20 is not guided to extract remainder fractionating column entrance 165.Because the residual fluid in feed-line will contain the strippant of the percentage larger than raffinate stream fluid, separate so advantageously this excessive strippant is not transported in extract remainder fractionating column 150 and in extract remainder fractionating column 150.Because in tower to entering the fluid heating of extract remainder fractionating column entrance 165, if so the excessive strippant in residual fluid is introduced in extract remainder fractionating column 150, this strippant will be heated and the extra productive rate of extraction product is not provided, and therefore cause energy punishment.Therefore,, by the initial residual piece diverting flow of fluid is made excessive strippant not to be introduced in extract remainder fractionating column 150, the amount of the required energy of system reduces.

In one embodiment, take out raffinate stream 20 from adsorbing separation chamber 100 and it is transported along feed-line 20'.In one embodiment, provide rotary valve 300 to make take out raffinate stream 20 and guided to rotary valve 300 via feed-line, in rotary valve 300, raffinate stream 20 combines with single extract remainder feed-line 20' as illustrated in Figure 3, but expect herein and comprise other structure for each feed-line of adsorbing separation chamber 100 and 105 special extract remainder feed-line 20' is provided.Feed-line 20' can have the extract remainder suction line 305 being communicated with extract remainder fractionating column entrance 165 fluids.Feed-line 20' can have with extract tower bottom divide 180 and raffinate column bottom points 155 in another bottom of being communicated with of one or two fluid divide pipeline 310.Valve 315 can be provided, and it is for the mobile shunting between raffinate column suction line 305 and raffinate column bottom point pipeline 310 by raffinate stream 20.In this way, method comprise by valve 315 move to primary importance with via raffinate column bottom point pipeline 310 by the initial part raffinate stream 20 of at least a portion that comprises residual fluid guide to extract tower bottom divide 180 and raffinate column bottom points 155 in one of.In this example, method comprise by valve 315 move to the second place with guiding raffinate stream 20 by raffinate column suction line 305 and guiding extract remainder fractionating column entrance 165 for separating therein raffinate stream 20.

In one aspect, in the predetermined portions at first scheduled time or stepping time interval, the raffinate stream 20 of at least a portion that comprises the residual fluid of rinsing from feed-line by raffinate stream is guided to the first destination by (in the time that raffinate stream occupies current feed-line), for example, extract tower bottom divide 180 and raffinate column bottom points 155 in one or two.Then in the predetermined portions at second scheduled time or stepping time interval, raffinate stream is guided to the second destination, for example, extract remainder fractionating column entrance 165.Can the flow rate based on raffinate stream 20 select for first scheduled time so that the residual fluid of the scheduled volume in feed-line is rinsed to the second destination or by total fluid flushing to the second destination of scheduled volume.In one embodiment, 50% to 250% the fluid that it is the volume of feed-line and associated valve assembly that first scheduled time can be enough to volume guides to the first destination, and is that 80% to 150% fluid of the volume of feed-line and associated valve assembly guides to the first destination in another embodiment by volume.In one embodiment, second scheduled time can be the remainder at stepping time interval, made in the remainder at stepping time interval, raffinate stream 20 to be guided to raffinate column entrance 165 for separate raffinate stream 20 in extract remainder fractionating column 150.Also the scheduled time can be chosen as to other value to whole or at least a portion of the residual fluid in feed-line is guided to the first destination, make residual fluid not to be introduced in extract remainder fractionating column 150 to provide energy to save.In one embodiment, first scheduled time stepping time interval 10% and 90% between.In this example, second scheduled time stepping time interval 10% and 90% between.In one embodiment, first scheduled time stepping time interval 10% and 30% between.In this example, second scheduled time stepping time interval 70% and 90% between.Similarly, the raffinate stream of the first predetermined can be guided to the first destination and the raffinate stream of the second predetermined can be guided to the second destination.The first predetermined can be and the percentage of describing the volume of identical feed-line and associated valve assembly above for first scheduled time.The second predetermined can be the residual volume of the raffinate stream of taking out via feed-line in stepping time interim.

In another aspect, method comprises that the composition that monitors raffinate stream 20 (comprising any residual fluid) is with amount or the percentage of the component in decision set compound.For example, component can be the one in preferential absorbed component, strippant component or non-preferential absorbed component.Be included in when composition comprises the component of the first predetermined content raffinate stream 20 and any residual fluid are guided to the first destination according to the method for this embodiment, and in the time that composition comprises the component of the second predetermined content, raffinate stream 20 is guided to the second destination.For example, method can comprise that the composition that monitors raffinate stream is to judge the amount that is present in the strippant in stream.According to this example, the amount that method can be included in strippant guides to raffinate stream during higher than critical value the first destination and raffinate stream is guided to the second destination in the amount of strippant during lower than critical value.In this way, the amount that is transported to the strippant of extract remainder fractionating column entrance 165 can reduce.

Then referring to Fig. 4, according on the other hand, adsorption separating method comprises goes out 405 for the first time, go out for the first time 405 and make it away from adsorbing separation chamber 100 and 105 for the residual fluid of the middle feed-line that rinses the zone purification 55 between the feed-line occupying at the feed-line being occupied by incoming flow 5 and by extract stream 15, remove at least a portion of residual fluid with this centre feed-line certainly.Further comprise another feed-line that guides to the feed-line that is not zone purification 55 from the residual fluid of middle feed-line flushing is introduced in zone purification 55 with restriction residual fluid according to method in this respect.In this way, as previous system, the residual fluid note in middle feed-line is not back in zone purification, wherein will separates the component of residual fluid, but before taking out via extract stream 15 without the top place in zone purification 55, flow through the benefit of whole zone purification 55.

In one aspect, will be delivered to incoming flow 5 by the residual fluid of going out for the first time 405 flushings and combine to be introduced in adsorbing separation chamber 105 with incoming flow 5 via incoming flow feed-line with incoming flow 5.The component of the residual fluid of introducing with incoming flow in this way, can separate with the feed fluid of introducing via incoming flow 5 in adsorption separation unit.This situation provides than via middle feed-line, residual fluid being directly introduced into the situation component separation more completely in zone purification 55, and this is because the component in residual fluid can flow through the whole zone purification 55 between incoming flow 5 and extract stream 15 before taking out via extract fluid 15.Owing to separating more completely of the component of residual fluid, the method can increase the purity of extract stream 15.

Can comprise remaining feed fluid via the residual fluid of going out for the first time in the middle feed-line of remaining in of 405 flushings according to an embodiment.For this reason, middle feed-line can previously be occupied by incoming flow 5, and in the middle of making, feed-line is shifted away from comprising at that time remaining feed fluid in incoming flow in the time that step finishes.Remaining feed fluid can advantageously combine with incoming flow 5 and be injected in zone purification via incoming flow feed-line and interface, therefore the component in the remaining feed fluid of separation in the degree identical with the component of incoming flow 5 self.

Can be lower than the pressure in incoming flow feed-line because go out for the first time pressure in 405 feed-lines, so can need pump to take out first flush fluid to overcome pressure differential and make it and incoming flow 5 is combined.Thus, can provide pump 410, it is taken out first flush fluid by middle feed-line and makes first flush fluid and incoming flow 405 is combined for pump.In one embodiment, system can comprise rotary valve, and wherein first flushing flow is rinsed by middle feed-line and to rotary valve 300, and in rotary valve 300, first flushing flow and incoming flow 5 are combined.But, in the situation that using two or more adsorbing separation chambers 100 and 105, at some feed-line along adsorbing separation chamber 100 and 105 or interface 25 places, the pressure at incoming flow 5 places can be higher than going out stream 405 pressure for the first time, wherein go out for the first time stream 405 between near the feed-line bottom of adsorbing separation chamber 100 and 105, carry with another top in adsorbing separation chamber 100 and 105 near incoming flow 5 engage.In these positions, the remaining charging in pipeline can pour in to extract stream, and this is because contiguous feed-line fluid communication with each other usually in the method for utilizing rotary valve 300.Therefore, in one embodiment, the downstream that pump 410 is positioned rotary valve is as illustrated in Figure 4 rinsed and is back to extract stream 15 in the time that stream is arranged in some position along adsorbing separation chamber 100 and 105 with the remaining charging in feed-line in the middle of limiting.

According on the one hand, go out for the first time 405 and comprise via the interface 25 of feed-line 415 and take out fluid from the zone purification 55 of adsorbing separation chamber 100.The position taking-up zone purification fluid that is adjacent to interface 25 in zone purification 55 and be delivered in the middle of in feed-line, so that the residual fluid in feed-line makes it away from adsorbing separation chamber 100 in the middle of rinsing.Advantageously carry out fill line line 415 by the concentration of preferential absorbed component higher than the fluid of non-preferential absorbed component by feed-line 415 in the middle of the fluid flushing of zone purification, reduce the pollution of extract stream 15 when to arrive centre feed-line 415 in subsequent step in extract stream 15.In one embodiment, zone purification material is taken out near the feed-line of the position current feed-line being occupied by extract stream 15, the composition of the fluid in the zone purification 55 that makes just taking out is similar to extract stream fluid.In one embodiment, take out zone purification fluid via interface 25 and be taken out in the feed-line in two feed-lines of the current feed-line being occupied by extract stream 15.In another embodiment, take out zone purification fluid via interface 25 and be taken out in the middle feed-line of the current feed-line being occupied by extract stream 15 of being adjacent to of zone purification 55.In this way, after going out for the first time by the composition that remains in the zone purification fluid for feed-line in the middle of rinsing in feed-line by be similar to the composition of extract stream fluid and comprise from only a small amount of (if yes) of incoming flow otherwise pollute the non-preferential absorbed component of extract stream 15 when arrives centre feed-line during subsequent step in extract stream 15.In one embodiment, the zone purification fluid taking out from adsorbing separation chamber comprises the non-preferential absorbed component lower than 0.5%.In another embodiment, comprise the non-preferential absorbed component lower than 0.005% for going out for the first time 405 zone purification material.As will readily appreciate that, according in this respect, go out for the first time 405 and itself and incoming flow 5 are combined by carrying, with can need less a feed-line by being delivered to from the residual fluid of going out for the first time in the middle of another when system of feed-line is compared.

In Fig. 5 explanation according on the other hand for the method and system from incoming flow adsorbing separation by component.According to method in this respect can comprise be similar to above about Fig. 4 described go out for the first time go out for the first time 505.But, go out for the first time 405 and compare with as described above, 505 be directed to another feed-line of zone purification 55 but not combine with incoming flow 5 according to going out for the first time in this respect.More specifically, method comprises that the residual fluid in the middle feed-line 510 that rinses zone purification 55 between incoming flow 5 feed-lines and extract stream 15 feed-lines makes it away from adsorbing separation chamber 100 or 105, to remove at least a portion of residual fluid via going out for the first time 505 from middle feed-line 510.Method further comprises that another middle feed-line 515 that the residual fluid of rinsing from middle feed-line 510 is guided to zone purification 55 is to rinse the residual fluid in feed-line 515 in the middle of another to being adjacent in the zone purification of another middle feed-line 515 via pouring for the first time 520.

According to one side, another middle feed-line 515 comprises the remaining feed fluid in middle feed-line 515 that remains in from the incoming flow 5 of feed-line 515 in the middle of occupying during previous steps.Therefore,, in the time flush fluid being introduced in middle feed-line 515 during pouring 520 for the first time, remaining feed fluid is introduced in the zone purification 55 of adsorbing separation chamber 100 or 105.But, because being shifted, incoming flow pours feed-line 515 downstreams in for the first time, so remaining charging is incorporated in the centre position of zone purification.Therefore, in one embodiment, in order to be increased in the amount of separation of the component occurring in remaining feed material in zone purification 55, pour for the first time feed-line 515 and be positioned to go out for the first time between feed-line 510 and the current feed-line being occupied by incoming flow 5, remaining feed fluid is introduced near part incoming flow of zone purification.In one embodiment, pour for the first time in two feed-lines that feed-line 515 is positioned incoming flow feed-line, and be positioned in another embodiment in a feed-line of incoming flow feed-line the amount of the separation of the component to be increased in the remaining feed fluid occurring in zone purification 55.

Above be also applicable to go out for the first time 505 according to aspect illustrated in fig. 5 about the description of going out for the first time 405 (about Fig. 4), except because the residual fluid in middle feed-line is delivered to the feed-line 515 for pouring for the first time 520, and feed-line 510 will mainly not comprise outside feed fluid in the middle of going out for the first time when going out for the first time as described above 405 situation and equally starting.Thus, residual fluid in middle feed-line 510 was previously rinsed to pouring for the first time the fluid of feed-line 515 and therefore will mainly comprising the zone purification fluid taking out from zone purification 55 from going out feed-line 510 for the first time during being alternatively included in previous steps, as above about go out for the first time 405 describe.

Then referring to Fig. 6, show according to the method for the adsorbing separation of the component for incoming flow on the other hand.According in this respect, as described previously, take out extract stream 15 from adsorbing separation chamber 100.Extract stream 15 can be delivered to extract separator (for example, extraction and fractionation tower 175) for separate preferential absorbed component in extract stream 15.Can remove pipeline 15' via extract stream extract stream 15 is guided to extract fractionating column entrance 190.

Comprise via secondary and rinse the 605 middle feed-lines 610 that rinse desorption zone 60 between extract stream 15 feed-lines and desorbent stream 10 feed-lines with away from adsorbing separation chamber 100 according to method in this respect, thereby remove residual fluid from middle feed-line 610.The method further comprises the residual fluid of rinsing from middle feed-line 610 is guided to downstream separation device to separate the component of residual fluid.According on the one hand, because middle feed-line 610 was previously occupied by extract stream 15, so the residual fluid in middle feed-line 610 mainly comprises extract fluid in the time that secondary rinses 605 beginning.Thus, remaining extract fluid can be guided to downstream separation device so that preferential absorbed component is separated in extract fluid, thereby increase the productive rate of preferential absorbed component.

According on the one hand, the remaining extract fluid rinsing from middle feed-line 610 is guided to extract fractionating column entrance 175, make preferential absorbed component can in remaining extract stream body, separate via distillation the productive rate to increase extraction product 195.

By one side, secondary rinses 605 and comprises that the desorption zone flush fluid taking out from the desorption zone 60 of adsorbing separation chamber 100 by the corresponding interface via middle feed-line 610 rinses the residual fluid in middle feed-line 610.In one embodiment, middle feed-line 610 is in two feed-lines of the current feed-line being occupied by desorbent stream 10, and in a feed-line of the current feed-line being occupied by desorbent stream 10, make the composition of desorption zone flush fluid be similar to desorbent stream 10 in another embodiment.In this way, desorption zone flush fluid remains in middle feed-line 610 after there is secondary flushing 605.After desorbent stream being displaced to middle feed-line 610 in subsequent step, by desorbent stream, the remaining desorption zone fluid in feed-line 610 in the middle of remaining in is introduced in adsorbing separation chamber 100, makes the composition of strippant district fluid be similar to desorbent stream 10.

According on the other hand, be provided for the method for the adsorbing separation of the component of incoming flow, the method comprises that the middle feed-line rinsing between two in incoming flow 5, extract stream 15, desorbent stream 10 and raffinate stream 20 is to remove residual fluid from middle feed-line.Generally comprise during at least two different pieces at stepping time interval and rinse middle feed-line with dynamic or non-constant rate of volume flow according to method in this respect.

As described previously, according to various aspects of the present invention, adverse current adsorbing separation comprises that along many adsorbing separation chambers via two different corresponding feed-lines, the incoming flow that comprises at least one preferential absorbed component and at least one non-preferential absorbed component 5 and desorbent stream 10 being introduced into two distinct interfaces 25 neutralizes via two different corresponding feed-lines and take out extract stream 15 and raffinate stream 20 through two distinct interfaces of many adsorbing separation chambers, these many adsorbing separation chambers have the multiple beds connected in series with fluid mode of communicating and comprise a predetermined number interval interface and be communicated with for fluid being introduced into the corresponding feed-line of adsorbing separation chamber neutralization from adsorbing separation chamber removing fluids with described interface fluid.Be introduced into adsorbing separation chamber 100 and 105 and the various downstreams that flow to of taking out from adsorbing separation chamber 100 and 105 be sequentially shifted or step to follow-up interface.Various stream conventionally (for example) steps to follow-up interface 25 by rotary valve 300 is rotated simultaneously, and maintains the predetermined stepping time interval at special interface 25 or step place.As discussed above, in one embodiment,, there is in another embodiment the interface between 12 and 48 in the interface 25 between having 4 and 100, and in another embodiment, there is the interface between 20 and 30, and have an equal number corresponding feed-line.In one embodiment, one or more adsorbing separation chamber 100 and 105 comprises 24 interfaces, and every first-class each being displaced to during complete cycle in 24 interfaces 25, makes often first-classly to occupy each interface 25 and corresponding feed-line in cycle period.In this example, circulation in one embodiment can be between 20 minutes and 40 minutes, and in another embodiment between 22 minutes and 35 minutes.In one embodiment, stepping time interval is between 30 seconds and 2 minutes.In another embodiment, stepping time interval is between 45 seconds and 1 point 30 seconds.In another embodiment, stepping time interval is between 50 seconds and 1 point 15 seconds.

Thus, it is current by the middle feed-line between two in typical stream two pipelines that occupy with non-homogeneous or the flushing of dynamic volume flow rate that the method is included in stepping time interim, and typical stream comprises incoming flow 5, desorbent stream 10, extract stream 15 and raffinate stream 20.According on the one hand, feed-line in the middle of the method is included in and rinses with the first flow rate in the Part I at stepping time interval.Feed-line in the middle of the method is included in and rinses with the second flow rate in the Part II at stepping time interval that stepping time interim is later than Part I.In this way, during in the Part I at stepping time interval and Part II than the fluid that rinses more volume during another part from middle feed-line.Rinsing feed-line with Transient Flow speed can provide rinsing to the composition of the fluid rinsing in middle feed-line or from middle feed-line and in the middle of fluid is introduced into feed-line or introduce the usefulness advantage aspect the sequential of fluid from middle feed-line.

In one aspect, Transient Flow speed can be included in that the slope increasing during at least a portion at stepping time interval or reduce changes or by exponent increase or the flow rate that reduces.Thus, slope changes flow rate can increase or reduce and can (for example, press index at those time durations) linearly or non-linearly to change during the part at stepping time interval.By on the other hand, Transient Flow speed can comprise that the stepping of flow rate increases or reduces, and makes one in one or two in the first flow rate and the second flow rate constant and the first flow rate and the second flow rate to be different from another.In aspect another, Transient Flow speed can comprise the slope changing unit of rate of volume flow and the combination that stepping increases and reduces.Transient Flow speed also can be included in the additional flow speed during the extra section at stepping time interval.Flow rate can increase, reduce or remain unchanged during any particular step.In addition, flow rate can change to high value, lower value or zero from initial value in the time that step finishes.Figure 10 to Figure 12 illustrates according to the example of the Transient Flow speed of various aspects of the present invention.The slope that Figure 10 explanation increases along with the time 1020 during at least a portion at stepping time interval changes flow rate 1015.In this example, the first flow rate 1005, lower than the second flow rate 1010, makes during the Part II at stepping time interval than the fluid that rinses more volume during Part I.In another embodiment, slope changes flow rate and reduces to make the first flow rate higher than the second flow rate along with the time, makes during the Part I at stepping time interval than the fluid that rinses more volume during Part II.On the other hand, Figure 11 illustrates the example of non-constant stepping flow rate.In this example, flow rate 1115 in the first common constant flow rate 1105 times, and is increased to second and constant higher flow rate 1110 conventionally during the Part I at stepping time interval 1120 during the Part II at stepping time interval 1120.In another embodiment, stepping flow rate has the second common constant flow rate lower than the first flow rate during the Part II at stepping time interval, makes to rinse the fluid of more volumes during the Part I at stepping time interval.According to various aspects, the rate of volume flow during in Part I and Part II can be zero.In another example illustrated in fig. 12, start with the first flow rate 1205 and be then included in the second flow rate 1210 reducing by index in time during the Part II at stepping time interval 1220 in the flow rate 1215 of the First office at stepping time interval 1220.According to various aspects of the present invention, also expect that other flow rate during the corresponding Part I at stepping time interval and Part II with different the first flow rates and the second flow rate distributes, and can have the extra section with other flow rate at stepping time interval.

According to one side, in the first flow rate and the second flow rate one is enough to rinse the feed-line of decent flushing and the volume of associated valve assembly between 50% and 400%, makes to rinse most of or whole in the residual fluid in feed-line during the Part I at stepping time interval or Part II.According on the other hand, in the first flow rate and the second flow rate one is enough to rinse feed-line and the associated valve assembly volume between 75% and 200% during the Part I at stepping time interval or Part II.In aspect another, in the first flow rate and the second flow rate one is enough to rinse feed-line and the associated valve assembly volume between 90% and 150% during the Part I at stepping time interval or Part II.According to various aspects, another in the first flow rate and the second flow rate can be enough to rinse feed-line and the valve module volume between 0% and 75% in one embodiment, rinse in another embodiment feed-line and valve module volume between 0% and 50%, and rinse the feed-line valve module volume between 0% and 25% in another embodiment.

According to one side, the first flow rate, higher than the second flow rate, makes during the Part I at stepping time interval than the fluid that rinses more volume during the Part II at stepping time interval.Can be especially useful when the following situation according to method in this respect: method comprises rinses the residual fluid in middle feed-line to adsorbing separation chamber 100 and 105, make residual fluid before being removed subsequently, have than otherwise in flow rate large time of staying in chamber 100 and 105 in the situation that stepping time interim is constant or in the situation that the second flow rate is greater than the first flow rate.

According on the other hand, the second flow rate, higher than the first flow rate, makes during the Part II at stepping time interval than the fluid that rinses more volume during the Part I at stepping time interval.Can in following situation, be particularly useful according to method in this respect: make it away from adsorbing separation chamber 100 and 105 by the flush fluid cleaning and removing residual fluid taking out from adsorbing separation chamber 100 and 105.Thus, flush fluid is provided than large in the indoor time of staying of adsorbing separation in the time using constant flow speed or in the time that the first flow rate is greater than the second flow rate.This situation advantageously provides the larger separation of the component in flush fluid, and the ratio of components that makes flush fluid takes out or be introduced into subsequent flows in adsorbing separation chamber 100 and 105 from adsorbing separation chamber 100 and 105 similar.

Then referring to more details, following instance generally comprises via the different feed-lines of adsorbing separation chamber 100 and 105 incoming flow 5 and desorbent stream 10 is introduced into the method in distinct interface 25.Two different feed-lines via adsorbing separation chamber 100 and 105 take out extract stream 15 and raffinate stream 20 through two other interfaces 25.According to one side, as for example, () illustrated in fig. 7, pour for the first time 720 and comprise the flushing current feed-line being occupied by incoming flow 5 and the middle feed-line 715 between the feed-line being occupied by extract stream 15 during this step during step.Residual fluid in feed-line 715 can mainly comprise remaining feed fluid.Be included in the Part I at stepping time interval according to method in this respect during, rinse feed-line 715 with the first high rate of volume flow of the second rate of volume flow than during the Part II at stepping time interval.In this way, during the initial Part I at stepping time interval than during follow-up Part II, the remaining feed fluid of more volume being rinsed to adsorbing separation chamber 100 or 105.Thus, rinse to the remaining feed fluid in adsorbing separation chamber 100 or 105 and be provided at the larger time of staying in adsorbing separation chamber 100 and 105, and access adsorbent in chamber separated non-preferential absorbed component before being to take out remaining feed fluid via extract stream 15 in subsequent step.According on the other hand, method comprises goes out 710 for the first time, goes out for the first time in the middle of 710 fluid flushings that comprise by taking out from adsorbing separation chamber 100 or 105 feed-line 705 with away from chamber, as described previously.In one embodiment, method is rinsed feed-line 705 with the first rate of volume flow of the second rate of volume flow during the second further part lower than stepping time interval during being included in the Part I at stepping time interval, and this feed-line 705 can comprise the remaining extract fluid from the feed-line 705 previously being occupied by extract stream.In this way, the flush fluid taking out from desorption zone 60 can comprise that composition is similar to the fluid of desorbent stream 10.Method can comprise rinses remaining extract fluid to middle feed-line 715 so that the remaining feed fluid in middle extract stream 715 is rinsed to zone purification 55 from middle feed-line 705.In one embodiment, the Part I that method is included in stepping time interval is sentenced the first flow rate flush fluid of the second flow rate during the Part II that is greater than stepping time interval, make early during part, the remaining feed fluid of more volume is introduced in zone purification 55 at stepping time interval, make can be in the middle of extract stream 15 be arrived soon after feed-line 715 and take out via middle feed-line 715 before in zone purification 55, reach feed fluid more separation, to increase the purity of extract stream.

Similarly, briefly referring to Fig. 6 as described earlier, method alternately comprises that secondary rinses 605, secondary rinses 605 and comprises the middle feed-line 610 of flushing and the residual fluid of rinsing from middle feed-line 610 is guided to downstream separation device, and downstream separation device comprises the extract knockout tower 175 that preferential absorbed component is separated in the remaining extract fluid in middle feed-line 610 in one embodiment.Can be included according to method in this respect rinse with the first rate of volume flow of the second rate of volume flow during the second further part lower than stepping time interval during the Part I at stepping time interval in the middle of feed-line 610.In this way, the flush fluid taking out from desorption zone 60 can comprise that composition is similar to the fluid of desorbent stream 10.

According on the other hand, can rinse middle feed-line 725 so that the residual fluid in middle feed-line is introduced in zone purification 55 by flush fluid.According in this respect, the first flow rate that method can be included in during the Part I at stepping time interval the second flow rate during the follow-up Part II to be greater than stepping time interval rinse in the middle of feed-line 725, make during the Part I at stepping time interval than during Part II, the residual fluid of the more volume in feed-line 725 being rinsed to zone purification 55.In this way, residual fluid is lasted more long residence time separate component wherein before taking out by extract stream 15 when feed-line 725 in the middle of arriving in extract stream 15 for residual fluid in subsequent step being present in zone purification.

In another aspect, in the middle of can rinsing by flush fluid feed-line 735 with away from adsorbing separation chamber 100 or 105, thereby remove residual fluid from middle feed-line 735.In one embodiment, middle feed-line comprise occupy during the previous steps of comfortable circulation in the middle of the remaining extract remainder of raffinate stream 20 of feed-line 735.According in this respect, feed-line 735 in the middle of method is included in and rinses by the flush fluid taking out from adsorption zone 50 with the first flow rate of the Part II lower than stepping time interval during the Part I at stepping time interval.In this way, flush fluid will take out and last the more substantial time for be present in adsorbing separation chamber 100 or 105 before middle feed-line cleaning and removing residual feed fluid in via middle feed-line.Therefore, will there is the composition of the incoming flow of being similar to from the flush fluid of adsorption zone 50, and will comprise the less non-preferential absorbed component of raffinate stream.After rinsing middle feed-line, flush fluid will remain in wherein as residual fluid, residual fluid will be introduced with incoming flow 5 in the time that incoming flow 5 is introduced via middle feed-line 735 during subsequent step, to reduce the pollution to incoming flow by excessive non-preferential absorbed component.

Then referring to Fig. 1, Fig. 4 and Fig. 5, according to various aspects as described earlier, flushable in the middle of feed-line 45,415 or 510 with away from adsorbing separation chamber 100 or 105, thereby feed-line removes residual fluid in the middle of described.Middle feed-line 45,415 or 510 can be by flush fluid is rinsed with dislocation residual fluid and makes it away from adsorbing separation chamber 100 or 105 in feed-line in the middle of zone purification 55 is taken out to, and will fill by the remaining flush fluid from zone purification 55 subsequently.According on the one hand, method be included in during the Part I at stepping time interval with the first flow rate and during the follow-up Part II at stepping time interval be greater than the second flow rate of the first flow rate rinse in the middle of feed-line 45,415 or 510.In this way, flush fluid provides the extra time in zone purification 55 and accesses adsorbent wherein for separating non-preferential absorbed component, make taking out zone purification fluid for feed-line 45,415 in the middle of rinsing or at 510 o'clock, the composition of this flush fluid is similar to the extract stream 15 of taking out via feed-line in the middle of described during subsequent step.Advantageously reduce to remain in the amount of the non-preferential absorbed component in the residual fluid in middle feed-line 45,405 or 510 according to method in this respect, increase thus the purity of extract stream 15, non-preferential absorbed component otherwise will pollute extract stream 15 during taking out extract stream 15 via feed-line in the middle of described.In one embodiment, as described previously, middle feed-line 415 is communicated with the residual fluid and the incoming flow 5 that make from middle feed-line flushing and combines with incoming flow feed-line.In another embodiment, as described above, middle feed-line 510 is communicated with the residual fluid making in middle feed-line 510 and is rinsed to another middle feed-line 515, so that the remaining feed fluid in feed-line 515 in the middle of another is rinsed to the downstream part of zone purification 55 with feed-line 515 in the middle of another.

According to various aspects, can be controlled at during dynamic flushing feed-line by the rate of volume flow of the fluid of feed-line with valve module and controller.Valve module can be incorporated in feed-line self to control or to limit the rate of volume flow of the fluid that flows through feed-line.Controller can be provided, and it is for the flow rate of control valve and the fluid by feed-line.Valve module also can be incorporated in intrasystem other position, (for example) in the time being incorporated to rotary valve on the downstream of rotary valve 300, or at the downstream line (for example,, for delivering the fluid to respectively pipeline 15' and the 20' of extract fractionating column 175 or extract remainder fractionating column 150) of the downstream components for delivering the fluid to system.

In the time being simulated moving bed process selected adsorbent of the present invention, unique restriction is the validity of particular adsorbent in will separating/strippant combination.The key property of adsorbent be by strippant be exchanged for incoming mixture material extract component speed or, in other words, the relative speed of extract component desorb.This characteristic is directly relevant to the amount of desorbent material, and desorbent material must be used in method and reclaim extract component with self-absorbent.Exchange rate reduces the amount for removing the required desorbent material of extract component faster, and therefore, permits the running cost of minishing method.In exchange rate situation faster, must take out and separate to reuse in method in extract stream by pump via the less desorbent material of the method.

Practice of the present invention is therefore irrelevant with the use of any particular adsorbent or adsorbent/strippant combination or be not limited to the use of any particular adsorbent or the combination of adsorbent/strippant, and this is because different sieve/strippants combine to separate for difference.Adsorbent can be or not be zeolite.The example that can be used for the adsorbent in the inventive method comprises the non-zeolite molecular sieve that comprises carbon back molecular sieve, silicolites and the crystalline aluminosilicate molecular sieve that is categorized into X zeolite and Y zeolite.Synthetic details about said composition and many these micro porous molecular sieves provides at US4, and in 793,984, this case is incorporated herein for this teaching.Also can be from US4 about the information of adsorbent, 385,994, US4,605,492, US4,310,440 and US4,440,871 obtain.

At general substantially constant pressure and temperature, continued operation, to guarantee in the adsorption separating method of liquid phase, must select desorbent material to meet some criterions.First, this desorbent material should be in the situation that himself can not being adsorbed consumingly with rational mass flow rate by extract component from this adsorbent dislocation, thereby stoped undeservedly this desorbent material of extract component dislocation in sorption cycle subsequently.With regard to selective, for the adsorbent of all extract components with respect to extract remainder component preferably than for having more selectively with respect to the desorbent material of extract remainder component.Secondly, desorbent material must with particular adsorbent and specific incoming mixture compatibility.More specifically, desorbent material can not reduce or destroy for the capacity of the adsorbent of the extract component with respect to extract remainder component or selective.In addition, desorbent material should chemically not react or cause its any chemical reaction with any of extract component or extract remainder component.Extract stream and raffinate stream conventionally remove and relate to desorbent material and extract component or extract remainder component or its both any chemical reaction and will make product reclaim to become complicated or stop product to reclaim in the voidage of the adsorbent mixing with desorbent material.Strippant also should easily separate with in extract remainder component from extract, as by fractionation.Finally, desorbent material should be easy to utilize and be reasonable on cost.Depend on application-specific, strippant can comprise heavy or light strippant.Term weighs and is gently the boiling point with respect to C8 aromatic hydrocarbons (also, ortho-xylene, meta-xylene, paraxylene and ethylbenzene) with regard to strippant.It will be apparent to those skilled in the art that indicator " C8 " refers to the compound that comprises eight (8) carbon atoms.In certain embodiments, freely in the group of following each composition, select heavy strippant: p-Diethylbenzene, p-Diisopropylbenzene, tetralin and fellow thereof, with and combination.In certain embodiments, toluene and fellow thereof can be used as light strippant.P-Diethylbenzene (p-DEB) has the boiling point higher than C8 arene isomer, and thereby while separating in C8 isomers in fractionating column, p-DEB is bottom (, heavy) product.Similarly, toluene has the boiling point lower than C8 arene isomer, and thereby while separating in C8 isomers in fractionating column, toluene is tower top (, light) product.P-DEB has become the commercial criterion that is used as strippant in the separation of paraxylene.

Adsorption conditions generally comprises the temperature range from 20 DEG C to 250 DEG C,, for p-xylene separation, is wherein preferred from 60 DEG C to 200 DEG C.Adsorption conditions also comprises the pressure that is enough to maintain liquid phase, and it can be atmospheric pressure to 2MPa.Desorption condition generally comprises as the temperature and pressure of the same range for adsorption conditions.Different condition can be preferred for other extract compound.

More than describe and example wish illustrates the present invention and non-wish limits its category.Although illustrated and described specific embodiment of the present invention, but will be there is to numerous changes and amendment in understanding for those skilled in the art, and in additional claims, be intended to contain all that change and the amendment that belong in true spirit of the present invention and category.

Claims (10)

1. for carry out a method for the component of separating feed stream by simulation adverse current adsorbing separation, it comprises:

The incoming flow and the desorbent stream that comprise at least one preferential absorbed component and at least one non-preferential absorbed component are introduced in two distinct interfaces via two different corresponding feed-lines along many adsorbing separation chambers, take out extract stream and raffinate stream with two distinct interfaces via these many adsorbing separation chambers through two different corresponding feed-lines, these many adsorbing separation chambers have the multiple beds connected in series with fluid mode of communicating and comprise a predetermined number interval interface and be communicated with for fluid being introduced into the corresponding feed-line of adsorbing separation chamber neutralization from adsorbing separation chamber removing fluids with this interface fluid,

Take out in extract stream and raffinate stream one with away from adsorbing separation chamber via a feed-line that contains residual fluid;

By the initial part of at least a portion that comprises the residual fluid of taking out via this feed-line of one in extract stream and raffinate stream first destination of leading; With

By second destination of leading of the further part of in extract stream and the raffinate stream of taking out via this feed-line.

2. according to the process of claim 1 wherein that the first destination is the recirculation line for this part of of extract stream and raffinate stream and residual fluid being recycled to adsorbing separation chamber.

3. according to the method for claim 1, wherein in extract stream and raffinate stream is extract stream, and the second destination is the entrance of extract fractionating column, and the first destination is the destination that is different from the entrance of extract fractionating column, enters extract fractionating column and pollute extraction product to limit at least this part of residual fluid.

4. according to the method for claim 3, it rinses higher than preferential absorbed component and the concentration of the concentration in incoming flow the feed-line being positioned between incoming flow feed-line and previous extract stream feed-line by comprising concentration before being further included in and taking out extract stream via a feed-line lower than the flush fluid of the non-preferential absorbed component of the concentration in incoming flow, with the remaining charging of this feed-line dislocation certainly, make the residual fluid in this feed-line in the time taking out extract stream via this feed-line subsequently mainly comprise flush fluid.

5. according to the method for claim 4, wherein flush fluid takes out from the feed-line that previously occupies and be adjacent to desorption zone by extract stream, this desorption zone be defined as adsorbing separation chamber in region desorbent stream being introduced between interface in adsorbing separation chamber and interface from adsorbing separation chamber taking-up extract stream.

6. according to the method for claim 3, wherein via this feed-line, the extract stream of at least a portion that comprises residual fluid is transported to at least one bottom in extract fractionating column and the extract remainder fractionating column of the first destination and divides for recirculation and be back to adsorbing separation chamber, make residual fluid not to be introduced at least one in extract fractionating column entrance and extract remainder fractionating column entrance to pollute the product producing from described tower.

7. according to the method for claim 1, wherein in extract stream and raffinate stream is raffinate stream, and the second destination is the entrance of extract remainder fractionating column, and the first destination is the destination that is different from the entrance of extract fractionating column, enter extract remainder fractionating column to reduce energy consumption to limit at least this part of residual fluid.

8. according to the method for claim 7, wherein this feed-line previously occupies by desorbent stream the residual fluid making in this feed-line and mainly comprises strippant.

9. according to the method for claim 7, wherein the raffinate stream of at least a portion that comprises residual fluid of taking out via this feed-line is transported to the bottom of in extract remainder fractionating column and the extract fractionating column of the first destination and divides for recirculation and be back to adsorbing separation chamber, make this part of residual fluid not to be introduced in extract remainder fractionating column entrance and extract fractionating column entrance to reduce energy consumption.

10. according to the method for claim 1, it further comprises and monitors the composition of comprising from extract stream and this raffinate stream of any residual fluid of this feed-line, while comprising with in extract stream and raffinate stream one the residual fluid component that is greater than scheduled volume, be directed to the first destination by one in extract stream and raffinate stream, and in the time that this fluid comprises the residual fluid component that is less than scheduled volume, fluid be directed to the second destination.