DE3413861A1 - Adsorber and adsorption process using the adsorber - Google Patents

Abstract

An adsorber construction is proposed in which two adsorption zones are provided within a shared pressure vessel, which are separated from each other by a partition concentrically arranged to the adsorber vessel, a passageway from the one zone to the other zone existing at one end of the partition. A pipe can possibly open in the region of the passageway between the zones. The two adsorption zones can possibly contain different adsorption media. Various modes of operation and different application examples are described.

Description

Adsorbers and adsorption processes

Using the Adsorber The invention relates to an adsorber with an adsorber container filled with adsorbent. Also affects the Invention to carry out various adsorption processes using the adsorber according to the invention.

Adsorbers that are used for gas separation usually exist from a vertically arranged cylindrical container containing a bed of adsorbent and at its upper and lower end gas supply lines and gas discharge lines contains.

In many separation processes, several must be separated from one another Components available, so that several adsorbers are connected in series, what in practice often for the series connection of entire adsorption systems that each contain several adsorbers operated in parallel, leads. Also surrendered In many cases, large heights of adsorbers, which is both constructive and also raises operational problems.

The invention is therefore based on the object of a device to develop, which is the separation of one or more components from a gas stream permitted with a structurally simple adsorption system.

This object is achieved by an adsorber with an adsorbent filled adsorber, which is characterized in that in the adsorber a filled with adsorbent inner container is arranged so that two Adsorption zones arranged essentially concentrically around one another show that one end of the inner container is connected to the adsorber container in a gastight manner, that at the other end of the inner container there is an open connection between the two There is adsorption, and that in the area in which the inner container is gas-tight is connected to the adsorber container, both adsorption zones with at least one Gas supply line or gas discharge line are connected.

The adsorber construction according to the invention allows a large number of of constructive and procedural, technical advantages. A first constructive one The advantage can be seen, for example, in the reduced overall height if the inventive Adsorber should be used instead of a conventional long adsorber. Another The advantage is that the adsorber construction is considerably simplified, because instead of a large adsorber container only the smaller outer adsorber container must be made pressure-resistant so that it can withstand the pressure differences between the environment and withstands the pressures occurring in the adsorption process. According to the invention provided inner container can, however, for example, as a simple gas-tight sheet metal cylinder be trained, as it is not exposed to any significant fluctuations.

Although the shapes of the inner container and the adsorber container are not are critical, as it is considered to be structurally and aerodynamically favorable, that both containers are vertically arranged cylindrical and concentric to each other have arranged coats.

In a special embodiment of the invention are in the two Adsorption zones contain different adsorbents. Such differences can refer to both the shape and the type of adsorbent. For example, it can be advantageous to do the same in the two adsorption zones Use adsorbents in different grain sizes, such as coarse-grained ones Adsorbent for the equilibrium zone and fine-grained adsorbent for the adsorption zone into which the mass transfer zone falls.

When using different adsorbents in the two adsorption zones two different separation tasks can be carried out in a single adsorber.

In particular, it is possible to have separate adsorber stations that were previously required to avoid pre-cleaning or to integrate into the actual adsorption system.

In an advantageous development of the invention it is provided a line in the area of the open connection between the two adsorption zones to flow into. This additional line enables both the adsorption operation as well as a large number of favorable process management for the regeneration of the loaded adsorber, which will be discussed below, and leads to a very flexible one Adsorber.

The adsorption zones can have different flow cross-sections for the gases to be cleaned or dismantled. In the case of a gas mixture that flows through both adsorption zones in series, this is advantageous, for example, when large proportions of the gas mixture are adsorbed. In such a case, the Amount of gas flowing through the adsorbent in the area of the mass transition zone considerably, so that the flow rate within the adsorber also decreases.

It is therefore often beneficial to use the second adsorber zone with a flow to equip with a smaller cross-section, because this saves adsorbent is possible.

In a favorable constructive embodiment of the invention there is the adsorber vessel consists of a cylindrical pressure vessel with arched ends Trays are provided, with the lower end of the adsorber in the transition area A support grate is arranged from the arched bottom in the cylindrical part, on which the inner container rests on it. The support grid that covers the entire cross-section of the adsorber container includes, is in the area of the outer, generally annular adsorption zone with a gas-permeable perforation that retains the adsorbent provided, while it closes the area of the inner adsorption zone at the bottom. This results in a gas-side connection between the outer adsorption zone and the The area of the arched floor underneath the supporting grid. The arched bottom contains a connection piece for a gas supply or gas discharge line. In the area the inner adsorption zone continues to be a conduit through the support grid and the lower arched bottom, whereby a gas supply or gas discharge line is provided to this adsorption zone.

In a favorable development of the adsorber according to the invention is the upper curved floor or another upper closure of the adsorber by a detachable connection, for example by means of a flange connection, with the vertical, in particular connected to the cylindrical container.

The adsorber according to the invention can be advantageous for a whole Use a number of different procedures. This not only results in constructive, but in many cases also solutions that are particularly advantageous in terms of process technology.

In a first inventive application, the adsorbers are used in the purification of two gas streams that are essentially the same to be recovered Component or various components of one by mixing these components gas mixture to be generated, but containing different impurities. The two adsorption zones become parallel during an adsorption phase operated so that the two gas streams each flow through an adsorption zone and a mixing of the two gas streams only after the respective cleaning in the adsorption bed he follows. When using conventional adsorbers, on the other hand, there would be a mixing the impure gas streams required, causing a mutual dilution of the impurities and thus a relatively high expenditure for a sufficient separation result has, or there would be two separate adsorption systems for the separate cleaning of the both gas flows are necessary. In such a process, the regeneration can be more loaded Adsorber can be done in any way, for example according to the pressure swing process or the temperature change method. The adsorption zones can be both parallel as well as in series if necessary be connected in series. In general, however, the parallel connection is used for such a separation task of the adsorption zones also during regeneration.

In a second inventive application, the adsorbers are used in the purification of air, for example in the separation of water vapor and Carbon dioxide from air prior to cryogenic air separation. It is essential that that the air during an adsorption phase in series through the two adsorption zones is performed and during a regeneration phase a hot purge gas the two adsorption zones flows through and regenerates in parallel. Such a procedure is in particular advantageous in connection with a thermal pulse regeneration. With the thermopulse regeneration a hot purge gas is passed through a loaded adsorber that in the adsorbent bed forms a relatively narrow temperature front, which is pushed through the adsorber. The regeneration times of this process are typically on the order of about 1 hour while common thermal regeneration methods need a considerably longer time for the desorption, for example 4 to 12 Hours. A disadvantage of the thermal pulse regeneration was previously seen in the fact that Satisfactory regeneration results only with short bed heights of the adsorbent were achieved, while on the other hand short dump heights poor loading values result during adsorption. The use of adsorbers according to the invention is permitted it to eliminate both disadvantages, since during series operation of the adsorption zone an adsorption phase has a sufficiently long bed height and on the other hand only relatively short bulk heights, namely only about half of the total Dump height are to be regenerated separately. Another inventive one Application of the adsorber provides the use in adsorption processes with thermal Regeneration before and leads to the saving of regeneration gas or

of regenerative energy. For this it is essential that the to be cleaned Gas flow during an adsorption phase first through the outer and then through the internal adsorption phase is carried out. The inner zone of the adsorber according to the invention that is, when the hot flushing gas is passed over, it is regenerated under more favorable conditions than the outer zone, because there is no temperature drop in the outer areas of this layer occurs. Conventional adsorbers, on the other hand, show a decrease in temperature in their edge areas and thus a deteriorated regeneration effect due to the release of heat is caused to the environment and only by expensive insulation of the adsorber can be limited. In the outlet area of an adsorber, towards the end of a Adsorption phase is the mass transition zone, which is possibly still an unloaded one Zone adjoins, falls, must for extensive regeneration of the loaded adsorber must be taken care of, since residual loads here are particularly unfavorable affect the product purity that can be achieved in a subsequent adsorption phase. The regeneration of those loaded to equilibrium during an adsorption phase Zone, on the other hand, has less stringent requirements. In this area are therefore lower temperatures can also be tolerated. When using the adsorber according to the invention is an adaptation to the special requirements of regeneration in the individual Zones possible in a simple way.

In such an application of the adsorbers according to the invention, it is furthermore favorable, the regeneration gas at least in the inner adsorption zone in the Countercurrent to the direction of flow of the gas to be cleaned during one To lead adsorption phase. This ensures that adsorbed components not be transported to the outlet end of the adsorption zone, so that this Zone largely kept free of adsorbable components during the entire process will. The equilibrium zone arranged in the outer adsorption zone can thereby regenerated either in series with or in parallel with the inner zone, which is im the first case of counter-current regeneration and in the second case of direct-current regeneration is equivalent to.

Another inventive application of the adsorber is also related on adsorption processes with thermal regeneration, namely in the event that separated several, differently strongly adsorbable components from a gas stream should be, for example, on drying and carbon dioxide separation Gases. In such a separation process, adsorbent material is formed in the bed essentially two consecutive loading zones, the more strongly adsorbable Component in the entry area of the gas flow into the adsorbent bed and the more weakly adsorbable component is adsorbed in the adjoining area will.

Through suitable dimensioning and / or through the choice of special adsorbents it can be achieved that the loading zones largely at the end of an adsorption phase lie within certain ranges of the adsorbent, so that optionally separate regeneration measures can be initiated for the individual zones it is known, for example, for drying and separating carbon dioxide from gases separate adsorber stations or adsorbers with two in one container on top of each other arranged beds of adsorp- resources to be provided. the The part loaded with carbon dioxide is regenerated in many cases Passing over a hot, circulated gas, while the loaded with water Area is regenerated without recirculation. Such a procedure is simplified when using the adsorber according to the invention, when doing the gas flow during an adsorption phase is passed in series through both adsorption zones and wa, arend a regeneration phase, hot purging gas is passed through the two adsorption zones, the regeneration gas withdrawn from an adsorption zone being circulated and the regeneration gas withdrawn from the other adsorption zone is discharged. The inner and outer adsorption zones are dimensioned so that one of the components to be separated are preferably completely adsorbed in one of the zones will. Compared to a common procedure with two separate adsorber stations This creates a complete adsorber station for the separation of one component saved, and compared to a system in which the adsorber is two stacked, with support grids, filling spouts etc.

have provided adsorption zones, there is not only the advantage a considerably simpler design, but also the advantage that the flow cross-sections are freely selectable for both separation tasks independently of one another.

Another inventive application of the adsorber relates to adsorption processes, in which in addition to one withdrawn from the adsorber during an adsorption phase non-adsorbed product stream and a residual gas resulting from the regeneration yet another, second product gas stream is obtained during the regeneration. This second product gas stream can, for example, be a pure or highly enriched one adsorbable Contain component that in addition to or instead of the non-adsorbable constituents of the gas flow is to be obtained as product gas. Common procedures of this type provide a pressure swing adsorption process in which the gas flow to be broken down is passed through two adsorption beds connected in series, which after completion an adsorption phase are regenerated separately, with one adsorber the residual gas and the second product gas from the other adsorber (e.g. DE-OS 26 04 305).

Such a separation process can be carried out using adsorbers according to the invention Perform in an adsorber when the gas mixture to be broken down is during an adsorption phase is passed in series through the two adsorption zones and an adsorption phase is ended after the adsorption zone through which the gas mixture first flows to is loaded to equilibrium with adsorbable components, but before the adsorption front reaches the outlet end of the second adsorption zone, and which is up to equilibrium loaded adsorption zone then with one enriched in the adsorbed component Gas flow with displacement of cavity gas containing non-adsorbable components is saturated, and then the saturated adsorption zone in countercurrent to The direction of flow of the gas mixture is relaxed during an adsorption phase, the resulting expansion gas at least partially as a second product gas is won.

It is still beneficial in this procedure if during the countercurrent relaxation in the saturated adsorption zone is a cocurrent relaxation the other adsorption zone takes place. With a steadily progressive relaxation in the two that way adsorption zones operated in parallel that is largely avoided that contaminated gas from the second adsorption zone passes into the first adsorption zone, which is loaded to equilibrium, and closes here leads to contamination of the secondary product.

Another possible application of the adsorber according to the invention is given, for example, in the case of gas cleaning, in which a progressive in operation Damage to the adsorbent through chemical reaction or through non-desorbable Components enters. Such cleaning processes previously required separate pre-adsorbers, whose adsorbents are completely renewed after a certain period of time got to. Such a pre-adsorber can be used using the adsorbers according to the invention can be integrated in the auptadsorber, which means that a pressure vessel is not required. the The filling of the pre-adsorber can be changed separately. The adsorber tank is for this purpose for example with a flanged, detachable upper arched base or with other suitable design features.

Even if always in the above-mentioned adsorption processes only the use of an adsorber was mentioned, it is understood by the person skilled in the art It goes without saying that for continuous operation there are several, in operation cyclically interchangeable adsorbers are provided.

At least one adsorber is in an adsorption phase, while at least one other adsorber is being regenerated.

Further details of the invention are given below with reference to the in Illustrated embodiments shown in the figures.

The figures show: FIG. 1 a section through an adsorber according to the invention Figures 2 to 5 different modes of operation of an adsorber according to the invention during an adsorption phase, Figures 6 to 9 different modes of operation of an inventive Adsorbers during a regeneration.

In the section shown schematically in Figure 1 through an inventive Adsorber, an outer cylindrical pressure vessel 1 is provided at its ends arched bottoms 2 and 3 are welded on. The upper arched bottom 2 is with a Pipe socket 3 provided, to which a connection line 4 can be connected. Of the below the arched bottom 3 can be connected to a further gas line via a connecting piece 5. A line 6 is also passed through the lower base 3.

Inside the vertically arranged cylindrical pressure vessel 1 is a horizontally arranged area in the lower area bordering the lower tube sheet 3 Support grate 7 is provided, which fills the entire cross section of the container 1. Concentric An inner container 8 is arranged vertically on the support grid 7 for the cylindrical jacket 1. The inner container 8 is tightly connected to the supporting grid 7, and the supporting grid 7 forms in the space enclosed by the inner container 8 a tight plate through which only the Line 6 is passed through. Above the confluence of the line 6 is a sieve 9 provided, which prevent the escape of adsorbent into the line 6 target. The support grid 7 is in the area between the inner container 8 and the pressure vessel 1 designed as a gas-permeable grate that prevents adsorbents from falling through media prevented. The inner container 8 of the adsorber is filled with adsorbent 10 and the annular space bounded by the inner container 8 and the cylinder jacket 1 is with Adsorbent 11 filled. Above the bed of adsorbent and the end of the inner container 8, which can be a simple sheet metal cylinder, is a free one Space 12 is provided in which both adsorption zones open.

In Figures 2 to 5, different operating options are during an adsorption phase. According to FIG. 2, raw gas enters via line 6 the adsorber and is through the lower arched floor 3 and the support grid 7 and passed through the sieve 9 into the lower region of the inner adsorption zone. The gas flows upwards through the adsorber and is deflected in the area of space 12 and flows through the annular space between the inner container 8 and the pressure vessel 1 of the adsorber in the opposite direction. The cleaned or decomposed gas emerges Via the support grid 7 from the adsorbent bed 11 and is via line 5 withdrawn from the area of the lower curved base 3. Line 4 is with this one Mode of operation closed by a valve not shown in the drawing.

In the exemplary embodiment shown in FIG. 3, the direction of flow is the reverse is true during an adsorption phase, i.e. the unpurified gas occurs via line 5, flows through first the outer annular space and then the inner one Adsorption zone before it is finally withdrawn via line 6.

Figure 4 shows a flow guide in the adsorption, the recovery of two product streams allowed. Gas to be cleaned is fed into the joint via line 4 Space 12 above the adsorbent beds. directs and flows in parallel through the inner and outer adsorption zones. Over the lines 5 and 6, two product streams are withdrawn separately. If in such a case different in the inner container 8 and between the inner container 8 and the pressure vessel 1 Adsorbents are contained, can be different product streams over Pull off lines 5 and 6.

FIG. 5 shows an operating mode in which two different raw gas flows be cleaned and a single product gas stream is obtained. The raw gas flows are Separated from each other via lines 5 and 6 to the two adsorption zones, the cleaned gases mix in the common space 12 before they pass through Line 4 can be withdrawn.

FIGS. 6 to 9 show different modes of operation during regeneration of the adsorber according to the invention.

According to FIG. 6, regeneration gas first enters the interior via line 6 Adsorption zone and then flows through the annular outer adsorption zone, before it is withdrawn via line 5. Part of the from the bulk adsorbent 10 of the inner container 8 emerging regeneration gas can optionally via line 4 can be deducted.

In the embodiment shown in Figure 7, the regeneration gas straight through the adsorber in the opposite direction, i.e. it overflows Line 5 into the adsorber is first through the outer annulus and then passed through the inner space before it is withdrawn via line 6. In turn a partial flow of the regeneration gas can be withdrawn via line 4.

In the mode of operation shown in FIG. 8, the two adsorption zones regenerated in parallel. Here regeneration gas enters the upper room via line 4 12 of the adsorber and flows through the two adsorption zones in parallel before it is finally withdrawn separately via lines 5 and 6.

In the mode of operation shown in FIG. 9, there is also a parallel one Regeneration of the two adsorption zones takes place, but here is a separate one Supply of regeneration gas provided for the inner zone and the outer zone. It will therefore two possibly different regeneration gas flows via lines 5 and 6 introduced into the adsorber and via line 4 is a common residual gas that consists of the regeneration gas and the desorbed components, deducted.

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Claims (14)

Claims 1. Adsorber with a filled with adsorbent Adsorber container, characterized in that in the adsorber container with an adsorbent filled inner container is arranged so that two are substantially concentric adsorption zones arranged around one another show that the inner container on a End gas-tight is connected to the outer container that at the other end of the inner container there is an open connection between the two adsorption zones, and that in the area in which the inner container is connected to the adsorber container in a gastight manner, both Adsorption zones each connected to at least one gas supply or gas discharge line are. 2. Adsorber according to claim 1, characterized in that the adsorber container a cylindrical and substantially vertically arranged pressure vessel and the Inner container is a cylindrical container arranged concentrically therein. 3. Adsorber according to claim 1 or 2, characterized in that in the two adsorption zones contain different adsorbents. 4. Adsorber according to one of claims 1 to 3, characterized in that that the area of the adsorber container in which the open connection between the consists of two adsorption zones, with one leading out of the adsorber container Line is connected. 5. Adsorber according to one of claims 1 to 4, with a cylindrical Pressure vessel, characterized in that the pressure vessel at its ends through arched bottoms is closed that at the lower end in the area of the transition from Arched bottom in the cylindrical part a support grate is arranged on which the Inner container is arranged so that the support grate is enclosed by the inner container Adsorption zone from the area of the arched floor below the supporting grid separates and the other adsorption zone through gas-permeable openings with the one below of the supporting grate lying area of the arched floor that connects a line through the area of the curved bottom into the adsorption zone enclosed by the inner container leads and that another line in the area of the curved floor below of the supporting grid leads. 6. Adsorber according to claim 5, characterized in that the upper arched bottom connected to the cylindrical container by a releasable connection is. 7. Adsorber according to one of claims 1 to 6, characterized in that that the two adsorption zones have different cross-sections. 8. Process for the adsorptive purification of two identical gas streams, containing different impurities, using an adsorber according to any one of claims 1 to 7, characterized in that each of the gas flows passed through one of the adsorption zones and the cleaned gas streams together be withdrawn from the area of the open connection between the adsorption zones. 9. Process for the adsorptive purification of air, in particular for separation of water vapor and carbon dioxide from air, using an adsorber according to one of claims 1 to 7, characterized in that the air to be cleaned is passed in series through the two adsorption zones and that for regeneration a loaded adsorber a hot regeneration gas in parallel through the two adsorption zones to be led. 10. Process for the adsorptive purification of a gas stream and regeneration of loaded adsorbent by passing a hot regeneration gas under Use of an adsorber according to one of Claims 1 to 7, characterized in that that the gas flow during an adsorption phase first through the outer and then is passed through the inner adsorption zone. 11. The method according to claim 10, characterized in that the regeneration gas at least in the inner adsorption zone in countercurrent to the direction of flow of the to be cleaned gas stream is performed during an adsorption phase. 12. Process for the adsorptive separation of at least two, different strongly adsorbable impurities from a gas stream with the loaded adsorbent is regenerated by passing a hot purge gas, using a Adsorber according to one of Claims 1 to 7, characterized in that the gas flow is passed in series through both adsorption zones during an adsorption phase and during a regeneration phase hot purging gas in parallel through the two adsorption zones is performed, the regeneration gas withdrawn from an adsorption zone in the circuit and the regeneration gas withdrawn from the other adsorption zone is discharged will. 13. A method for the adsorptive decomposition of a gas mixture in which a first product gas during an adsorption phase and a first product gas during a regeneration phase a second product gas and a residual gas can be obtained using a Adsorber according to one of Claims 1 to 7, characterized in that the gas mixture passed through the two adsorption zones in series during an adsorption phase is that an adsorption phase is ended after the first of the gas mixture flow through adsorption phase up to equilibrium with adsorbable components is loaded, but before the adsorption front, the exit end of the second adsorption zone reaches that the loaded to equilibrium Adsorption zone thereupon with a gas stream enriched in the adsorbed component Displacement of non-adsorbable components containing cavity gas saturated is that then the saturated adsorption zone in countercurrent to the direction of flow the gas mixture is relaxed during an adsorption phase and that this accumulating expansion gas at least partially obtained as a second product gas will. 14. The method according to claim 13, characterized in that during the countercurrent relaxation in the saturated adsorption zone is a cocurrent relaxation the other adsorption zone takes place.