DE407179C - Method and device for separating gas or vapor mixtures, e.g. Air, by adsorption or chemical bonding - Google Patents

Description

Method and device for breaking down gas or steam mixtures, z. B. air, by adsorption or chemical bonding.

The present invention relates to the decomposition of gas or Steam mixtures, e.g. B.

Air, through chemical bonding or primarily adsorption. Below the latter application is described first. However, it should be emphasized in advance that this description almost word for word also for the decomposition by chemical bonding applies if one uses the term in the place of adsorption or adsorbent (coal, etc.) and designation »Absorptioncc or» chemical bond »or» chemically absorbing, chemically binding, chemically active "mass".

It is known that porous coal and others are porous or finely divided Substances such as clay, magnesine and magnesium carbonate (see volume 1866 of the journal for practical chemistry, Volume 98, page 458off., Reichard; about coal and others Piston, "Liquid Air", 1920, p. 233; also patent 169514 from Dewar), the various Adsorb components of gas or vapor mixtures to different degrees, namely in general, the more abundant the higher the partial pressure and the higher the boiling point possess these constituents and therefore the easier they condense. It seems to give exceptions to this, in that in a certain way prepared zeolites the Volume allegedly twice as much hydrogen as carbonic acid and about sixteen times absorb as much as nitrogen (but there are also chemical effects due to the iron content of the zeolite). Even for such exceptions the present invention applies.

It also follows from these phenomena that an adsorbed gas (or Steam) by a transferred other one of other adsorbability if necessary is displaced, and that the amount adsorbed and therefore the performance of the adsorbent generally increases when working at reduced temperatures. (S. especially Baerwald in the "Annals of Physics (and Chemistry)", Vol. 23 (1907, p. 99 and Ioo, table 4 or panel V; also patent 169514 by Dewar.) Because this brings you closer to the Principle of the liquefaction temperature of the gas or vapor. It is about Oxygen, nitrogen, carbon monoxide and the like, gases which are difficult to condense, are needed one with "lowered" working temperatures does not immediately go to the lowest temperatures to think how they z. B. in the liquefaction of air and its rectification be applied. Rather, temperature reductions are already suitable, which in contrast by means of ordinary refrigeration machines and thus much more economically attainable are. You can of course use coolants such as ethane and other hydrocarbons, as well as mixtures of the same, which are indeed below the cooling water temperature Liquefy pressure, but much lower than ammonia, carbonic acid and the like boil. Of course, the most extensive work is done at low working temperatures Use of countercurrent cold exchange, which has a major impact on costs.

As already mentioned, there are various types of adsorbent and with their help, gases or vapors of the most varied kinds can be extracted from mixtures deposit, e.g. B. Hydrocarbons, their halogenation products, nitrous gases, sulphurous acid, hydrochloric acid gas, ammonia, hydrogen sulphide, chlorine, cyan, hydrocyanic acid gas, rare gases in the air. The degassing of the adsorbent can be done indirectly or direct heating or by reducing the pressure (possibly creating a vacuum) or, almost synonymous with this, by transferring indifferent gases, especially from superheated steam.

In order to describe the invention briefly and clearly by means of an example can, in the following, be highly porous as an adsorbent, in a known manner possible easy flammability and deprived coal accepted - as well as with the later described decomposition by chemical bonding - as a mere example to decomposing mixture of atmospheric air, for its oxygen z. B. porous coal has a stronger adsorption capacity than nitrogen. (See also the German patent specification 193410 by Weileböck »Amazing adsorption power of moist tree bark for oxygen. ') The carbonic acid content of the air and Water vapor, argon and rare gases are neglected. The working temperatures be such that superheated steam is used to degas the coal leaves.

In order to carry out the decomposition, consider an apparatus from following construction and mode of operation, as similarly already in the patent specification 238569 (p. 2, bottom left) of the inventor for the production of nitrogen-hydrogen mixtures described: The container containing the coal has a closed ring shape and is divided into successive chambers by radial partitions, which two Form groups, one of which (the binding group) depends on the one to be processed Air, the other (the degassing group) in the same direction (direction of rotation) of the degassing water vapor and the degassing product flow through, and both in such a way that both initial chambers and both end chambers are periodically also advance in the direction of the gas duct (air duct and steam duct) leaves, so that the inclusion of a chamber in the arcuate path of the air or the water vapor always at the end of this path, the switch-off always at the beginning the same takes place and thus always the last switched on chamber of the relevant Gas (or steam) flows through last. From the chamber that just happened served as the beginning chamber of the binding group and which is now the end chamber the degassing group to drive off the adsorbed oxygen from it, if the latter is assumed z. B. by superheated steam, during the Nitrogen as the more difficult to adsorb constituent of the mixture from the end chamber the binding group flows off as a non-adsorbed residue. Perform this way a decomposition of the air.

However, this decomposition is imperfect because it is in the degassing chambers not only more easily adsorbable component (oxygen), but also heavier adsorbable (nitrogen) is adsorbed. There is also some in the pores and spaces the coal pieces contain. This creates two effects: I. The expelled Adsorption product consists not only of oxygen but also of nitrogen and is therefore defiled by such; 2. those from the end chamber of the binding group The amount of nitrogen flowing out is compared to that contained in the air as a whole Amount less - which can be important for gases other than air, and that the amount of nitrogen which is also adsorbed in the degassing chambers and is included and driven out of them.

According to the present invention, the decomposition by the two very perfected the following measures.

A) Before degassing, the initial binding chamber is switched off For some time oxygen (auxiliary oxygen) in the pure, namely from the ones to be removed Components (nitrogen) of the gas mixture released state passed. Through this the adsorbed and the mechanically contaminating portion of the less adsorbable Nitrogen displaced and replaced by the more easily adsorbable oxygen ()) Maximum enrichment process ee or "maximum process" for short), so that in the following Degassing of pure oxygen results.

B) The chamber (briefly "Maximum chamber") leaving gas initially has air composition, but becomes gradually becoming more and more oxygenated, and you even wait for it to come out completely pure Oxygen exists before degassing begins. This exhaust gas is now left do not escape into the air, but you either pass it a) together with the raw gas to be broken down (air) in the initial chamber of the binding group or b) in one or more chambers upstream of the same backward (antechamber).

Each of these latter measures a and b has the consequence that the in adsorbed in the initial chamber and contained in the exhaust gas of the maximum process Nitrogen, but especially the oxygen in the latter exhaust gas, is not lost. With a sufficient number of chambers and thorough gasification of the oxygen from the The degassing chamber or chambers is therefore practically all of the oxygen in the air in the pure state during the degassing process and practically all of the nitrogen more or less pure than unadsorbed air residue from the last binding chamber. (Of course the total decomposition effect depends to a large extent on the number and The size of the chambers, the applied gas pressure and the applied reduced working temperature from.) Measure a means, compared to measure b, the destruction of what has already been achieved Decomposition effect, because the oxygen content of the exhaust gas is very high on average the l! Maximum chamber due to the remixing that takes place in measure a Air is considerably devalued, whereas with measure b this mixing is only with a lower oxygen fraction or with exhaust gas () secondary, Exhaust gas) of the exhaust gas in question ("primary" exhaust gas) takes place. measure b therefore deserves preference.

If the degassing is effected by heating the adsorbent, the same can be achieved simply by going through the degassing chambers heated oxygen (1-eizsauerstoiX) circulates, which outside the chamber part of it is continuously withdrawn as a useful product.

When evacuating the degassing chambers, however, it is advisable to use the same e.g. by means of 3 embedded in their adsorbent material and through which heating means flow Pipes to be heated in order to cool down which counteracts the gradual release of gas the adsorption mass during the gasification of the oxygen condensed on it impede. If one is satisfied with keeping the temperature of the mass approximately constant received, this comes at reduced working temperatures of the simplicity of To the benefit of the apparatus by using the heating means that go against dismantling, cooled air or the nitrogen flowing off can serve, so not two different strong cooling or even special heating are necessary.

If the degassing is carried out incompletely, so much If oxygen remains adsorbed in the degassed alasse, this oxygen residue becomes when the degassed degassing start chamber is switched on as the binding end chamber displaces the nitrogen flowing through it, which has a very high partial pressure and carried on with it, thus reducing its purity for a time.

According to the theory, it is for increasing and maintaining the adsorptive capacity of the coal is not unfavorable, considering the air to be laid previously freed from water vapor and carbon dioxide, which is due to the liquefaction of the air and decomposition can be done in a known manner.

In the drawing, a device for execution is schematically of the method shown, with a single degassing chamber 8 instead a whole group of them. The inner, circular arrow means that Direction of the gas flow and at the same time the circuit. The supply line is here a total of eight chambers arranged in a closed ring. 3 is the adsorption initial chamber, into which air is introduced. This also flows through the chambers one after the other 4 to 7, from the last of which the unadsorbed residue (nitrogen) flows off. the end the degassing chamber 8 releases the adsorbed gas component, e.g. B. Oxygen, in that they - possibly with artificial heating of the adsorption mass - evacuated (see drawing) or circulate the oxygen warmed by it (oxygen) leaves. - The starting chamber 3 is, in the backward direction, the chambers in sequence 2 and I upstream. The maximum process takes place in the latter, the maximum chamber instead, by z. B. pure air separation, namely nitrogen-free or very low-nitrogen oxygen (auxiliary oxygen).

The resulting substitution product (nitrogen) as well as the always more increasing unadsorbed remainder of the introduced auxiliary oxygen mixes the air fed into the initial chamber 3 is preferably not readily available at, but you lead the gas, according to the procedure described earlier B, b and, as illustrated in the drawing, initially through chamber 2 (Antechamber). For example, with the next forwarding, chamber 4 or 8 becomes the start or End chamber, I or 2 or 3 to the degassing or maximum or pre-chamber.

One embodiment of the maximal process is that one the auxiliary oxygen by water vapor (or other inert gas or steam) Developed in the degassing chamber or chambers and only required from there measured cooling, but still mixed with such water vapor, etc., immediately leads into the maximum chamber.

Another embodiment is formed in that from the The initial chamber that has just been switched off and made the maximum chamber or else Antechamber by introducing steam etc. or by indirect heating ei drives out new part of the oxygen together with the adsorbed nitrogen and the resulting Exhaust gas in the manner described in the gas flow and switching direction via the any antechamber forwards into the binding chambers (adsorption chambers).

As is carried out here for air, for example, the method According to the invention also serve for other gas mixtures that decompose by adsorption can be. In this case, too, one becomes the most easily adsorbable component as auxiliary gas «to use with him from the enriched with it, in the order first or initial chamber to drive off the constituent or constituents which are more difficult to adsorb. According to the literature, there also seem to be adsorbents, at least some at ordinary temperatures, oxygen adsorb less than nitrogen. When using such adsorbents in the above example, the oxygen and the nitrogen of course switch roles.

-The procedure is similar to perfected rectification. Because even in this first a rectification product of the gaseous (cder liquid) raw mixture produced, whereupon this rectification product the vapor of the higher-boiling component, which is also apparently lost here it has a rectifying effect to a certain useful amount of this component in the pure, dripping liquid state (in the present invention in the adsorbed liquid state). (See German patent I6793I / I7g of the inventor.) For the purest recovery of the most easily adsorbable constituent of Mixing gases or vapors is gradual enrichment through repeated repetition the decomposition by adsorption has been proposed. It is clear, however, that one Such a decomposition is extraordinary compared to the new method described above is cumbersome and leads to an incomparably lower yield (similar to frequent Repetition of primitive fractional distillation versus more regular, more perfect Rectification).

As emphasized at the outset, the invention relates just as well to the Breakdown of gas or vapor mixtures, e.g. B. air, by chemical bond. These Form of application is described below, again assuming z. B. more atmospheric Air as a gas mixture to be decomposed, It is known to extract oxygen from the atmospheric To win air that oxidizable substances such. B. barium oxide or mixture of alkali manganate and alkali metaplumbate, at a suitable, elevated temperature Air that is passed over, possibly compressed, is oxidized and then reduced again the latter by means of indirect or direct heating or by means of Pressure reduction or, with which almost synonymous, by means of transition indifferent Gas, especially superheated steam. Here, several ovens with interchangeable bins wedge can be used in two groups, one of which is always degassed when the others are subjected to the binding process (oxidation process, ventilation In operation, an apparatus of the following construction can still be used and perfect the way of working, as already described in the Pti.teri.tschrift v; 8569 (5. 2, bottom left) by the inventor for the production of nitrogen-hydrogen mixtures described.

The container containing the active class has a closed ring shape and is divided into successive chambers by radial partitions, which form two groups, one of which (the binding group) depends on the one to be processed Air, the other (the degassing group) in the same direction (direction of rotation) of the eventual, heating, evacuation, or both. exerting degassing auxiliary gas (superheated steam) and the degassing product flows through, both such that both initial chambers and both end chambers are periodically also in the direction of the gas flow (air flow and water vapor flow) advances, so that the inclusion of a chamber in the arcuate path of the air or of the water vapor etc. always at the end of this path, the deactivation always at the beginning the same takes place and thus always the last switched on chamber of the relevant Gas (or steam) flows through last. From the chamber that just happened served as the beginning chamber of the binding group and which is now the end chamber. the degassing group to drive off the adsorbed oxygen from it, if the latter is assumed z. B. by superheated steam, during the Nitrogen from the end chamber of the linking group as a non-adsorbed residue flows off, mixed with an oxygen residue, which is the smaller, the stronger Oxidation tendency possesses the active mass. In this way one takes place Decomposition of air.

This mode of operation results in the most extensive and most economical use the oxidizing tendency of the active substance, the oxidizing power of the air and the degassing Effect, be it of any auxiliary gas or of indirect heating.

However, this decomposition can, if not precisely in the case of the present one Air separation, to the extent that it is imperfect, as well as undesirable components of the Gas mixtures are bound chemically or physically, primarily when they are contained in the gas mixture in very large quantities. The degassing product is then contaminated by such constituents.

It also avoids the described arrangement and its operation not a significant disadvantage, consisting in that the solid or liquid active Earth the interior of the individual chambers (let alone their connecting lines) of course not completely filled, but leaves empty spaces, which are immediately are filled with air and therefore also with nitrogen before degassing, so that the same contaminates the evolved oxygen during degassing. Also is the outflowing The amount of nitrogen contained in the interstices discussed lower, which may be important for gases other than air According to the present Invention, this decomposition is now very vervikkjinnebtm by the following two measures A) Before the degassing, some time in the switched-off binding initiation chamber long Oxygen (auxiliary oxygen) in the pure form, namely from the components to be removed (Nitrogen) of the gas mixture released state passed. Thereby the possibly co-absorbed components of the gas mixture by the most easily absorbable is displaced, as is the nitrogen that also fills the spaces between the loading areas (»maximum enrichment process or in short »5Iaximalprocessf (), so that in the subsequent degassing it is purer Oxygen results.

B) The chamber (in short "Maximum chamber") leaving gas initially has air composition, but becomes gradually becoming more and more oxygenated, and you even wait for it to come out completely pure Oxygen exists before degassing begins. This exhaust gas is now left do not escape into the air, but you either pass it a) together with the raw gas to be broken down (air) in the initial chamber of the binding group or b) in one or more chambers upstream of the same backward (antechamber).

Each of these latter measures a and b has the consequence that the in the initial chamber and then the nitrogen contained in the exhaust gas of the maximum process and above all the oxygen in the latter exhaust gas is not lost. With enough Number of chambers and thorough gasification of the oxygen from the degassing chamber or chambers are therefore practically all the oxygen in the air in the pure state during the degassing process and practically all of the nitrogen is more or less pure obtained as unabsorbed air residue from the last binding chamber.

(Of course, the overall decomposition effect depends to a large extent on the selected active mass, the number and size of the chambers, the applied Gas pressure and the applied working temperature.) Measure a means opposite Measure b a destruction of the already achieved decomposition effect, since the on average very high oxygen content of the exhaust gas of the maximum chamber due to the measure a taking place remixing with air is considerably devalued, whereas in measure b, this mixing only with a lower oxygen fraction or exhaust gas ("Secondary" exhaust gas) of the exhaust gas in question ("primary" exhaust gas) takes place. Measure b therefore deserves the preference.

If the degassing is effected by heating the absorption material, so one can achieve the same simply by going through the degassing chambers strong ; heated oxygen ("heating oxygen") circulates, which outside part of it is continuously removed from the chamber as a useful product. When evacuating the degassing chambers but it is appropriate to use the same z. B. means in their absorbent material to heat embedded pipes through which heating means flow to one of the gradual gas release counteracting cooling of the active material in the A to prevent gasification of the oxygen bound by it. If you are satisfied in order to keep the temperature of the mass approximately constant, this is what happens The simplicity of the apparatus benefits from that of dismantling as a means of marriage opposing heated air or the outflowing nitrogen can serve, so two different levels of heating are not necessary.

If the degassing is carried out very incompletely, so that much Oxygen in the degassed mass = remains bound, this oxygen residue becomes when the degassed degassing start chamber is switched on as the binding end chamber the flowing through, acting as a vacuum, so to speak, in relation to the oxygen Nitrogen gasified and carried along, so its purity for a while decreased.

If the active mass is solid, then the maximum process described has nor the extremely beneficial effect of this mass becoming inactive, like the same thing z. B. threatens to occur due to excessive heating and thus strong sintering, to counteract. Namely, it causes active mass, which z. B. by the the faulty operation mentioned has severely lost its ability to be oxidized by air, by pure oxygen due to its partial pressure which is five times higher than that of air is still oxidized, both in its entirety, as well as possibly up to the highest oxidation level, which in turn is easier with degassing is subject to reduction than the oxidation stage produced only by air. It is it is even obvious that the subsequent new oxidation (by means of Air) by the previous reduction from the maximally oxidized state and the the resulting molecular porosity of the (if solid) Mass is favored. The maximum process is therefore advantageous in every respect.

In the drawing, a device for execution is schematically of the method shown, with a single degassing chamber 8 instead a group of such.

The inner, circular arrow indicates the direction of the gas flow and at the same time the circuit. The direction here consists of eight to one closed ring arranged chambers. 3 is the initial binding chamber into which Air is introduced. This also flows through one after the other the Chambers 4 to 7, from the last of which the unabsorbed residue (nitrogen) flows off.

The bound gas component is released from the degassing chamber 8, z. B. oxygen, by the fact that they - etl. under artificial heating of the active Mass -evacuated (see drawing) or steam superheated by it or very allows strongly heated oxygen (heating oxygen) to circulate. The initial chamber 3, the two chambers 2 and I are connected upstream in sequence in the reverse direction. In the latter, the maximum chamber, the maximum process takes place by going through she z. B. pure air separation, namely very nitrogen-free or very low-nitrogen Oxygen (auxiliary oxygen) leads. The nitrogen displaced as a result and the mixed with it and mixed in this mixture more and more increasing auxiliary oxygen the air fed into the initial chamber 3 is preferably not readily available at, but you lead the gas, according to the procedure described earlier : 3, b and as illustrated in the drawing, initially through the chamber 2 (Lorliammer). For example, the next time you are forwarded, chamber 4 or 8 will become Beginning or end chamber, I or 2 or 3 for degassing or maximum or. Antechamber.

Here, too, one embodiment of the maximal process consists in that pure oxygen can be replaced by water vapor (or other inert gas or steam) is developed in the degassing chamber or chambers and from there only after the necessary cooling, but still mixed with such water vapor etc., leads directly into the maximum chamber.

Furthermore, a further embodiment is also formed here by that one can get out of the initial chamber that has just been switched off and made the maximum chamber or the antechamber by introducing steam, etc., or by indirect heating drives out some of the oxygen along with the polluting nitrogen and the resulting exhaust gas in the manner described in the gas routing and switching direction passes through the possible antechamber into the binding chamber.

As carried out here for air, for example, the method can According to the invention also serve for other gas mixtures that are chemically bonded can be disassembled from components. In this case, too, one becomes the absorbable Use component as an auxiliary gas in order to remove it from the chemically loaded, in the order of the first or beginning chamber the other, unbound, however, the spaces between the active material and possibly physically filling expel absorbed (i.e. adsorbed) components.

The following statements apply to the first described, based on adsorption, as also for the one just treated, on chemical action based application of the invention.

If the degassing takes place by evacuation or a similar effect, so there is the disadvantage that the active mass automatically cools down, which counteracts degassing.

This disadvantage can be eliminated to a bohemian extent that the active mass is applied in a mixture with substances which are involved in the adsorption or do not take part in the chemical reactions and therefore no adsorptive power or need to have a chemical effect, but act as a heat store, namely during the evacuation period as a result of previously recorded and now again prevent the heat emitted from cooling down rapidly and severely, what they do the more extensively, the greater the quantity they add to the latter mass are.

This application of a heat storage material is also particularly important Loyalty and maximum period benefit. This happens automatically during these periods Increase in temperature, which counteracts the progress of adsorption or chemical bonding. Here, too, the additive in question has a temperature equalizing effect, by having to be warmed up by the developed heat and thereby in proportion to it added amount reduces the heating of the active material.

The auxiliary material can consist of a good heat conductor (such as metal filings or shavings or metal balls [metal shot] or metal beads) or from bad Heat conductors (such as spheres or beads made of glass or porcelain).

! The worse the auxiliary material conducts heat, the smaller the size must have its admixed particles. The mixture can be purely mechanical be or a physical one! in the sense that the adsorption or chemical milk acting substance is deposited on the excipient or the latter with the former is intimately interspersed (impregnated).

This auxiliary method is the more advantageous, the more expensive the active mass as raw material or by virtue of its preparation for the main process is.

Another auxiliary method is that you can split the Gas mixture and in the maximum process the gas introduced into the maximum chamber pulsating Subject to pressure changes for the purpose of creating the original gas mixture (in the case of the maximum process) as well as gas-1 mixture, which is to be adsorbed or chemically constituent to be bound is depleted due to a decrease in pressure from the pores and interstices sucking out the active mass, but with the subsequent increase in pressure, gas, which is richer in that named component to push back into the pores.

Claims (10)

PATENT CLAIMS: 1. Process for separating gas or vapor mixtures by binding the same to porous materials, characterized in that after saturation of the binding substances (active mass) initially one of the easiest to bind Part of the corresponding gas (vapor) in the less easy-to-bind parts completely or largely freed state (auxiliary gas) through the porous substances to expel the less firmly bound gas mixture parts (maximum process) and then only the more firmly bound mixture parts in a known manner, for. B. by reducing the pressure or by heating, wins (degassing process). 2. Embodiment of the method according to claim 1, characterized in that that when using a series of binding chambers, each with auxiliary gas treated initial chamber (maximum chamber) escaping gas mixed with the raw gas forwards through the chamber system. 3. Embodiment of the method according to claim 1 and 2, characterized characterized in that one dad exhaust gas from the chamber treated with auxiliary gas (masimal chamber) before it is mixed with the raw gas through one of the chambers just mentioned and the new initial chamber switched chamber (antechamber of the initial chamber) or several such directs. . Embodiment of the method according to claim 1 to 3 in the case of Introduction of inert gas (vapor) into the degassing chamber during the degassing process, characterized in that, immediately after switching over the initial chamber or the antechamber to the maximum chamber, than that in the same for driving out the less firmly bound gas mixture parts serving auxiliary gas readily in the degassing process Degassing product obtained from the degassing chamber without cleaning it thoroughly of the auxiliary gas used for Eatgasung and therefore still with a more or less considerable Stick to it instead of using it in its pure state. 5. Embodiment of the method according to claim 1 to 3, characterized characterized in that, immediately after switching the initial chamber or the Antechamber to the maximum chamber, the one in the same for driving out the less tightly bound Gas mixture parts serving auxiliary gas generated in this chamber itself, namely with The help of degassing that has begun and still produces an impure product. 6. Embodiment of the method according to claim 1, characterized in that that one in the degassing by pressure reduction or similar effect in the to be degassed chamber contained active material by simultaneous heating, for example by passing through heated, easier-to-bind gas mixture part, to a constant one Seeks to maintain temperature. 7. To carry out the method according to claim 2 serving device, characterized in that it consists of a ring of reaction chambers with for everyone matching gas guide and at the same time switching device consists of which Chambers each as a bonding chamber or as a degassing chamber or as one Binding start chamber upstream and opening into it (maximum chamber) can be switched. 8. To carry out the method according to claim 3 serving embodiment the device according to claim 7, characterized in that each chamber also as an intermediate chamber (antechamber) between the maximum chamber and the binding start chamber can be switched. 9. Auxiliary method for the method according to claim I and its claimed From embodiments, characterized in that the active amasse in more or less Intimate mixture with substances is applied, which at the actual binding and Do not participate in degassing process> but in the binding process of heating and during the degassing process, the cooling of the active material is contrary to and therefore have a temperature equalizing effect. 10 Hilfsverfahre.n for the method according to claim 1 and its claimed From: guide forms, characterized in that the gas mixture to be broken down ud, beün maximal process, the gas introduced into the xinialkammer pulsates pressure changes is contemplated.