SA96160551B1 - A method for separating substances from a gaseous medium by dry adsorption method - Google Patents

Abstract

Abstract: The present invention relates to processing, by a dry adsorption process, a gas resulting from a hot electrolytic process to produce aluminum comprising at least two stages. The particulate aluminum oxide (adsorption material) is passed through the stages of the adsorption process in the opposite direction to that of the gas. Thus, the gas is partially treated with the spent adsorption material in a first dry adsorption stage, and then the particulate adsorption material is separated from the gas from the first adsorption stage in the same direction as the process. Then, part of the separated particulate adsorption material is removed from the adsorption process to recycle the fluorine-containing adsorbents to the electrolytic process. Then the remaining part of the separated adsorption material is recycled in the first adsorption stage in order to carry out the adsorption of the fluorine-containing materials in an ideal manner and release sulfur dioxide from aluminum oxide in this stage. At the same time, the gas is transferred to a second dry adsorption stage. In this second stage, the gas is treated with reactive particulate aluminum oxide that has not been used in the first place, in order to very efficiently adsorb any gaseous fluoride present in the gaseous medium, while also adsorbing at the same time the main part of the sulfur dioxide dioxide present in the gaseous medium. Finally, this particulate aluminum oxide is separated from the gas stream of the second adsorption stage in the same direction as the process, before the gas is discharged into the outside atmosphere. Then, the separated aluminum oxide is transported. The first adsorption stage, optionally after passing the desorption stage to remove adsorbed sulfur dioxide to reduce aluminum dioxide discharges. The separation of sulfur dioxide in the second adsorption stage is improved by recycling, to where the second adsorption stage is, and aluminum oxide is subjected to a maggot treatment.

Description

. No: 7 Method for the separation of substances from a gaseous medium by dry adsorption Full description BACKGROUND The invention relates to a method for the separation of impurities; by adsorption and for recovery purposes; ie separation of fluorine-containing gases; And dust containing fluorine from the gas: (gas medium) rising from the aluminum production process. The gas rising from the process is brought into contact with an adsorbent in the form of particulate aluminum oxide; It is the oxide that can be recycled as raw material to the process. (iS) of the invention relates to a multi-stage process in reverse that performs an efficient gas-cleaning combination with fluorine-containing materials of Alle concentration above the adsorption material. In an environmentally beneficial form of invention; At the same time, sulfur dioxide is removed from the rising gas (the rising gas medium). In a process for the electrolytic production of aluminum, Jie aluminum, the Hall-Héroult process, in which aluminum is produced by reducing aluminum oxide in a molten electrolyte in the form of a fluorine-containing metal. from which aluminum oxide is supplied; The process gases are loaded with 1 _ fluorine-containing materials; Jia hydrogen fluoride; Fluorine-containing dust, and due to the fact that these materials are highly and excessively damaging to the environment; It must be separated before the process gases are discharged to the surrounding outside air; Although at the same time; The fluorine-containing melt is essential for the electrolytic process. a

: a

The process of recovering fluorine-containing compounds from gases generated in dee production

aluminum suffers the inconvenience and inconvenience that it normally would

also loading the process gas with other materials; Such as sulfur dioxide ¢ which is exhaled

Primarily from oxidation of the electrodes but to some extent also from impurities present in the material

0 raw. If these materials are recycled to the process along the adsorption material, these

The material will be emitted into the process gases; And therefore; They are concentrated in a circle that appears prominent in the process

Electrolytics and gas processing. If these materials are concentrated in the process; In most cases, these materials have an adverse effect on the outcome of the process or conflict with the process in some ways

other; Thus, this affects the economics of the process in reverse. And therefore; It must be removed

| This material is an adsorbent before this material (adsorption material) is recycled into the process. The amount of sulfur dioxide from the process must be reduced. z

It is well known that dry adsorption processes are used to clean up the gases generated in

| aluminum production process; In this AY aluminum oxide may be used as an adsorbent. The production process of 1 aluminum anodized 1 aluminum ALO is supplied as raw material; And it has a high and large ability to adsorption of hydrogen fluoride

hydrogen fluoride (in particular; high chemisorption capacity) 0 and aluminum oxide powder

aluminum oxide of commercial quality and particle size within the range of 0.01 to

0.11 + mm shall have a porous structure and an active surface area of 0 to 000 m"/g; such that it

© _ It can adsorb huge amounts of hydrogen fluoride before the aluminum oxide is saturated + and in any case; The absorption capacity actually diminishes

A za

: "0 z when {ai} the active active surface is completely adsorbed by hydrogen fluoride molecules; that is, when the aluminum oxide is saturated with hydrogen fluoride, and it is usual; aluminum oxide is mixed particulate matter efficiently and turbulently with the gases emitted from the aluminum production process in a fluid bed reactor or in some other contact reactor, then the hydrogen fluoride is adsorbed onto the aluminum oxide afterwards ¢ The aluminum oxide now containing the fluorides adsorbed downstream is separated from the contact reactor with the help of one or more cola spall filters then; the aluminum oxide production process is supplied to 1 Aluminum oxide “sniffing” fluorides are recovered. However, sulfur dioxide is also adsorbed in these processes to a certain extent (as a general rule, in a ratio of 10 to 1). Thus, the sulfur dioxide gas associated with aluminum oxide is returned once again to the aluminum production process. It is the gas that is released into the rising process gases in the furnace. In practice z actual practice; 1 Sulfur dioxide is not removed from the gases; but instead; Unwanted recycling and concentration in a system that includes an aluminum furnace and gas cleaning equipment is furthermore; An increase in the content of sulfur dioxide is obtained in el sel over buildings and facilities. If he desires to reduce the environmentally hazardous discharge of sulfur dioxide resulting from the aluminum production process | ©; The sulfur dioxide must be separated from the fuel gases with the help of wet separation devices and units that are arranged in an orderly manner in the direction of the process from the ey operations.

z Dry adsorption of the previous art. any way; Such devices from the wet separation devices used to separate sulfur dioxide from gases represent an expensive Sa (dda) given that the quantities of gas included or ol ginal are large and have considerations and because the concentration of sulfur dioxide is Lea sulfur dioxide is low; compared to that, for example, with the quantities of those

0 The gases emitted from a power plant that operates on fossil fuels 'caused by burning fossils.' For this reason, aluminum factories or units in the world are still discharging sulfur dioxide into the surrounding air. One of the objectives of the present invention is to provide a method, with the help of dry adsorption of isl aluminum oxide, to essentially separate all fluorine-containing 0 gallons of gall for recovery purposes, and also efficiently to Separation of sulfur dioxide, for reasons Ay, from the gas rising from the aluminum production process. Another objective of the invention is to provide a process, which is the process by which sulfur dioxide is removed and also to To some extent the removal of other undesirable impurities from above the adsorption material before it is recycled to the aluminum production process, 1 by which recycling and accumulation of these materials in the system is avoided.However, another object of the invention is to It provides a process, which is compared to the dry gas cleaning processes of the prior art; They lead to preserved or improved separation results and improved recovery of Lad for fluorine-containing materials; This is despite the achievement of maintaining or improving the environmental friendliness of the process (low emission); Compared to the aforementioned pre-art© processes. Mr. Dr

: Q0Z - General description of the invention according to the invention; These goals are achieved by the adsorption process consisting of at least two dry z adsorption stages; In which the upwelling gas generated in the aluminum process is mixed and loaded with at least fluorine-containing materials, which may be a gaseous medium 0 or particulate particles; This is done with fine-grained aluminum oxide and brought it into contact with this oxide. Thus, by this process, at least fluorine-containing materials are separated from the rising gas. The adsorption stages are placed in one or more contact reactors in which the gas is treated by mixing it and bringing it into contact with fine-grained aluminum oxide. 0 in the adsorption process according to the invention; The gas is treated in a first dry adsorption stage with particulate aluminum oxide, at least partially depleted; So that the main sAD adsorption of the gaseous fluorides present in the gas takes place above the adsorption material. The aluminum oxide is separated with the fluorine-containing materials from the gas from the first adsorption a yo z in the same direction of travel the operation; and then; Part of the aluminum oxide 0 separated with fluorine-containing adsorbed is removed from the adsorption process and then the remaining part of the aluminum oxide is recycled in the first adsorption stage; While at the same time the gas is transferred to a second dry adsorption stage which is placed in the same direction as the first adsorption stage; The gas is now of a reduced content mainly of fluorine-containing substances; Then vy. It is then treated in the second dry adsorption stage with reactive aluminum oxide a sie sf.

- da | >

It is used primarily in the form of granules; Through which any fluorine-containing materials remaining in the gas are then adsorbed after the first dry adsorption stage, in order for other gases such as sulfur dioxide to be adsorbed; after that; The particulate and granular aluminum oxide is removed from the adsorbent gas stream M of the second dry adsorption stage and in the same direction as the process; This is before the gas is discharged into the surrounding atmospheric air; or to undergo complementary treatment in 3 directions of the process; Then at least part of the separated aluminum oxide from the rising gas stream is transported in the direction of the process flow from a contact reactor included in the second dry adsorption stage to another contact reactor included in the first dry adsorption stage. particulate matter through the phases of aluminum oxide, as is evident from the foregoing; The aluminum oxide undergoes antireflux adsorption to the gas. First, aluminum oxide is supplied

It has never been used as a contact reactor and is the reactor that is included in the second dry adsorption stage; Where the aluminum oxide is mixed and brought into contact with 1 _ gas. and from the contact reactor that is included in the second adsorption stage; The now partially spent aluminum oxide is transferred to the contact reactor which is included in the first adsorption stage. And when the contact reactor that is included in the first adsorption stage is supplied with aluminum oxide; The aluminum oxide coming from the second stage of adsorption is mixed and brought into contact with the Als gas in this first stage of adsorption. After being passed through the contact reactor which is included in the first adsorption stage; Dry powdery aluminum oxide is separated; and be for

- Co z on A ginal fluorine now essentially saturated with at least aluminum oxide and removed from the process; Thus, fluorine-containing materials are recycled; Recycling the remaining part of the aluminum oxide to the aluminum fluorine production process, where the first adsorption stage is. Aluminum oxide The recycling movement is activated for two reasons. The first of them is that he may want to control and control the adsorption of the gaseous 0 coming from the process in the first adsorption stage and make it perfect. that he may wish to obtain and achieve the target pronunciation of such material 0 ; These are materials that have been adsorbed on aluminum oxide, sulfur oxide; By which, therefore, any primary recycling of these materials to aluminum oxide sulfur is then prevented in terms of the electrolytic process. If sulfur 0 is recycled to phosphorus pentoxide (phosphorus Or phosphorus (dioxide) in the electrolytic process; this may have an adverse effect on the yield of the product of this process. Jie these gases id of attraction Jef fluoride _possible; in part; that the adsorption material is recycled in the first adsorption stage at least; vo to make sure what material is recycled to where the electrolytic process along The adsorption material transferred to the electrolytic furnace, thus, the unwanted materials phosphorus pentoxide and the phosphorous dioxide Jie in it are prevented from being recycled and concentrated in the system, including the furnace Electrolytic analysis and gas equipment. All these gases are adsorbed and molecularly bound to the active surface with a dalle © granule.

: 0 Oxide in a dry adsorption process. And on Af case; Given that hydrogen fluoride has a high affinity for the oxide, higher than its affinity for sulfur dioxide; So the sulfur dioxide that has been adsorbed will actually be pronounced, while hydrogen fluoride 0 takes the place of sulfur dioxide on top of the surface Lo sill 0 active. in excellent contact conditions between the process gas and the adsorbent; The adsorption process, Ja | voltage, in the direction of achieving equilibrium, is based on a very high portion of hydrogen fluoride adsorbed on the surface of the oxide; Wis there is Gh sulfur dioxide adsorbed if there is an increase in the surface area of the active adsorption material relative to the amount of hydrogen fluoride present in the process. According to the fact 0 that the adsorption material is recycled in the first adsorption stage; The process reaches this state of equilibrium. As a result; Unwanted material can be monitored and reduced to a minimum; So that the minimum amount of these materials is then recycled to the electrolytic analysis furnace, along with the adsorption material. And in one of the embodiments of the invention concerned with the use when it is desired to avoid unwanted substances oe such as sulfur dioxide; which has been adsorbed on sale adsorption; It is recycled to where the electrolytic furnace; However; These materials may be allowed to be discharged into the external atmospheric air, and the adsorption material (aluminum oxide) is transferred from the second adsorption stage directly to the first adsorption stage, where it is recycled during the emission of sulfur dioxide + and is directed The ejection process in the direction of achieving the condition: _equilibrium Sulfur dioxide is emitted from the electrolytic lee and accompanies the process gas to where the first adsorption stage is.In any case, a second adsorption is controlled

Sulfur dioxide in this first adsorption stage with reduction to a minimum by recycling the adsorption material in this stage. As a result; The sulfur dioxide will be concentrated in the existing cycle between the first adsorption stage and the second adsorption stage, while there is basically no sulfur dioxide that will be recycled between the 0_electrolytic furnace and the first adsorption stage. Upon reaching a stable and stable stage; In the end, Alls are formed in the same equilibrium, which is the case in which the amount of sulfur dioxide: which is discharged into the outside atmosphere is equal to the amount of sulfur dioxide emitted or sublimated to the process gases in the furnace. Electrolytic analysis. 0 0 : brief explanation of the drawings for illustration and example purposes; The invention will now be described in more detail with the help of a preferred embodiment of the invention; With the help of the attached illustration. In Operation "Hall - ‎Hall Héroult" cals ma; Aluminum is produced by reducing 0 aluminum oxide; which is dissolved in a melt of 8-containing metals with the help of electrolysis in an electric reduction furnace (1). The electrolysis is carried out at a temperature of about 1760 °C. The melt is partially fractionated during the course of the process; the volatile components evolve in a gaseous state As a result, the gases emitted from the process contain fluorine compounds, such as hydrogen fluoride (HF) fluoride ©, and fluorine-containing oils, and because they are destructive and harmful, Rill must be

0 Z: Separation of these materials from the gases emitted from the process before they are discharged into the surrounding atmospheric air. any way; These fluorine-containing materials represent, at the same time, a loss of significant value and consideration. Apart from fluorine-containing compounds, there are combustion products; such as sulfur dioxide; coming from the elevators

Carbon anodes are the products that are burned during the process. The sulfur dioxide must be removed from the adsorption material not only to avoid that it will be recycled into the process,

Z but because it is also undesirable; for environmental reasons; To reduce discharges or discharges of sulfur dioxide from the process without setting up huge and expensive manufacturing units to treat huge quantities of gas with a low content of sulfur dioxide.

When the invention is used to treat gas (Y) emitted from process (1) for the production of aluminum, the fluorine-containing materials are separated from the gas in a reverse adsorption process comprising at least two dry adsorption stages (© 4).The gas loaded with fluorine-containing materials is processed in a first dry adsorption stage (oY) which is shown in the figure as a contact reactor (©). In this contact (©) reactor the gas is mixed and brought into contact with a particulate adsorbent

10 The granules are depleted Wa in the form of aluminum oxide, which is transported with the gas stream into the contact reactor (1), where the content of fluorine-containing substances is reduced! fluorine in the process gas. Second adsorption is quenched sulfur dioxide during the treatment procedure in the first dry adsorption stage (of) when the content of fluorine-containing substances is at its highest value; This is because such substances as hydrogen fluoride

Hydrogen fluoride 0: It has a greater affinity for aluminum oxide than it does for sulfur dioxide. It takes place in this first adsorption stage; F1 adsorption

A 2: Sulfur dioxide ulfr dioxide only on the surface of an excess of aluminum oxide ¢ which is the surface that has not been covered, for example, by hydrogen fluoride. It has the adsorption of sulfur dioxide in a sufficiently strong contact with the gas containing hydrogen fluoride; The sulfur dioxide gas will then be released and replaced by hydrogen fluoride, and after treatment is completed in the first stage of adsorption (oY), the particulate aluminum oxide is separated from the penultimate gas, Bis. We now have a very low hydrogen fluoride content that is transferred to the second dry adsorption stage (£) to be treated in. Then the particulate aluminum oxide, which has a high content of fluorine-containing adsorbents, is separated fluorine; such as hydrogen fluoride; This is from the gas along the main part of the 8B fluorine compounds downstream of the process and from the first adsorption stage (¥) with the help of mechanical separation means of prior art (17); such as an cyclone. Some aluminum oxide (YY) is recycled aluminum oxide equal to or corresponding to the amount of 0 _ aluminum oxide that has not been consumed and paid to the second adsorption stage (£) of the adsorption process that is loaded with adsorbent pally containing fluorine. (1) (at position “7”); while the remainder of the aluminum oxide (at position (“FY”) is recycled into the first adsorption stage (7) and via LAS recycling and acceptable given For the difference in the attraction of aluminum oxide to each of hydrogen fluoride ¥ - | and sulfur dioxide, respectively; this ensures that the main part of the gall containing fluorine fluorine present in the gas The process has been adsorbed

“ay: 7 completely in the first adsorption stage (oY) while there is no adsorption mainly for sulfur dioxide. Instead, a substantial amount of sulfur dioxide (1) sulfur dioxide adsorbed on aluminum oxide is then pronounced. As a result, sulfur dioxide will be mainly associated with process gas 6; In order to make it possible to recycle basic fluorine-containing materials into process (1) with a good yield at (7); while avoiding recycling of sulfur dioxide and its concentration in the process. and the arrangement of the second adsorption stage (4) at 0

| Jolin's photo One or more contact reactors (£) are placed downstream from the first adsorption stage (7) and from the first adsorption stage (¥) and the following separator (FY) the gas at the position is transported (Vr) to the contact reactor (o£) where it is mixed and brought into Ala contact with a freshly prepared, unused reactive aluminum oxide. In the contact reactor (o£) any gaseous fluorine is adsorbed”; So is sulfur dioxide

dioxide Sa 0 in a certain amount depends on the extent of adsorption capacity allowed by the newly prepared adsorption material A (aluminum oxide) for the adsorption of the low gravitational gas. After 10 the treatment is carried out in Als pe second dry adsorption o£) the adsorption is separated from the gas “process gas” with the help of a filter (£1) such as a bag filter; then, the gas which has become WIS and completely clean can be discharged with high efficiency of all fluorine-containing materials fluorine to where the surrounding external atmospheric air is at the position (©); while, according to the invention, aluminum oxide loaded with a substantial amount of sulfur dioxide © adsorbed in the second adsorption stage (£) is transported to where First adsorption stage (7). Play sale process suitable for (TY) aluminum oxide first adsorption stage ();

A? 11-7, the amount of basic sulfur dioxide adsorbed on aluminum oxide will be pronounced in the first adsorption stage (©) Laie, which will be in contact with the process gas with a high content of hydrogen fluoride “Xia . The hydrogen fluoride released is in contact with the sulfur dioxide along the length of the process gas to where the second adsorption stage is (?). Because of the pronunciation

0 sulfur dioxide; There is an increase in the effective active surface area of the aluminum oxide, which is available for adsorption of hydrogen fluoride, le <hydrogen fluoride, which leads to achieving highly efficient adsorption of hydrogen fluoride | So much so that a very high degree of adsorption of gaseous fluorine is obtained in the first adsorption stage (AY) 0 and through aluminum oxide (YY) aluminum oxide that was transferred from the first adsorption process (¥) to the reduction process ( 1) All fluorine-containing substances emitted from the reduction process (1) to process gas (¥) are basically recycled to the reduction process (V) again. And on dla Af it Essentially no (ale) ey Sy sulfur dioxide is cycled to where the reduction process is (1) along the length of (MY) aluminum oxide transferred from the first adsorption process (Y) to the reduction process (1). In view of the fact that sulfur dioxide is excreted in the first adsorption stage, the partially cleaned process gas (+) transferred to the second adsorption stage (4) will have an increased content of dioxide sulfur dioxide » which is reduced to some extent in the second stage of adsorption (?). In the case of GALEN an equilibrium is formed with regard to the recycling of concentrated slfr dioxide between the first two stages of adsorption (7) ( and the second (4);

A: The amount of sulfur dioxide that is discharged or discharged over the length of the cleaned process gas (0) and equal to the amount of sulfur dioxide that is supplied with the uncleaned process gas up to (OY): in one of the models of the invention; The sulfur dioxide that is discharged to the surrounding outside air is also reduced with the cleaned process gas () by treating aluminum oxide loaded with sulfur dioxide coming from the second adsorption stage (V). (A) desorption stage In this stage of the desorption stage (oA) all sulfur dioxide that has been desorption is basically ejected by heating it and mixing it with gas Carrier (MY) flows through. Then the yarn will be 0 bearing (AY) leaving the “pronounced” aggregation stage (A) with a high concentration of sulfur dioxide; Basically, it has a high concentration of sulfur dioxide, which has been emitted from aluminum oxide during the pronouncement process. And due to the low attraction of sulfur dioxide, which leads to aluminum oxide, the aluminum oxide has a restricted or completely limited ability to absorb sulfur dioxide. Therefore, it is possible even in a stable state. This low content of gaseous fluorine present in the process gas (V0) and transferred to the second adsorption stage (€) and having an effect on the adsorption of sulfur dioxide during this second stage of adsorption (£) can be neglected; Even in this case a poor separation of sulfur dioxide from the process gas is obtained; : the quality or quality of the adsorbent is >_low and/or if the sulfur dioxide content of the process gas being supplied is low

‎-11-: | 7 to this second stage of adsorption (£) is high. In one embodiment of the invention, the ability to separate sulfur dioxide is raised to the target level by recycling at position (AY) of a portion of the aluminum oxide treated in Pronunciation stage (A) to where the second adsorption stage (o£) as this contributes to increasing the amount of active active adsorption material. So; M. The amount of aluminum oxide treated in the ejection stage (A) will increase steadily with the increase in the amount of aluminum oxide recycled at position (AY) of ! denatured stage (A) to where the second dry adsorption stage (4). In the “cooling” stage (A) sulfur dioxide is pronounced sulfur dioxide due to the effect of heating and flowing through (AV) dala gas where it drags sulfur oxide gas with it to 0 out of the system . If verbal processing in stage (A) was performed correctly. Sis would need to use a small amount of carrier gas (1/); while at the same time obtaining a high concentration of Sulfur dioxide in the carrier gas (AY) leaving the release phase L(A) For reasonable economic reasons of cost, the sulfur dioxide in the carrier gas may be washed or converted into commercial products ; As if it is converted into liquid sulfur dioxide; or to sulfuric acid or to csulfior sulfur by using well-known processes in this field, as long as there are only trace amounts of carrier gas (AY) included which is the reason for which The processing equipment may be of a small volume The slight heating of the aluminum oxide required to pronounce (al) sulfur dioxide Pronunciation phase (A) Pronunciation of the small amount: © Hydrogen fluoride fluoride that has been adsorbed in desorption stage 7

| “0 z z second (6). After the termination of the ¢ (A) phase the aluminum oxide is attached to the first dry adsorption stage (1) as described above. After the adsorption material is passed In the first and second dry adsorption stages (oY) (;) in opposite directions to where the process gas is; all hydrogen fluoride 0 and other fluorine-containing substances are essentially adsorption from the process gas; aluminum oxide is pushed aluminum oxide to the process (1) and supplied with it to produce {aluminum}. The aluminum oxide sulfur dioxide content in aluminum oxide 1 is very low and is mainly limited by the amount that has been adsorbed And it remains during the treatment in the first adsorption stage (L (V)) that there are certain other substances, such as phosphorus, which has been adsorbed ad 0 with the gas coming from the aluminum production process (1) aluminum oxide, which aia is the by-product of the current electrolytic process and has an adverse effect on the process, it must then be removed and disposed of from the process gas and in the final filtration stage (41); removal of al phosphorus in the form of particulate phosphorus pentoxide; Otherwise, it may become concentrated in the system; Including its concentration in electrolytic furnace and gas processing equipment. 1 It was found that the treatment for the removal of sulfur dioxide (A) sulfur dioxide also leads to the removal of a certain amount of phosphorus stu sill; Thus, this leads to a reduction in its accumulation in the system. According to the method of invention; And since the particulate adsorption material (aluminum oxide) passes through the first and second stages of adsorption (oF) (£) of the adsorption process in two opposite directions to where the process gas is, while the gas and the adsorption material are transported jointly with the current © located in the first and second adsorption stages (o£) oF), the adsorption sala is adsorbed efficiently and in the capacity of £ey

| Co basic all hydrogen fluoride separated in the first adsorption stage 90) where it is recycled with the adsorption material along its extension to where the aluminum production process (1); while sulfur dioxide is separated Sulfur dioxide is in the second adsorption stage (6) and is removed from the adsorption material in the “magnification” stage (4). During recycling at position (AT) of the adsorption material starting from the adsorbent stage (A) to where the adsorption stage : second (8) This two-stage process results in recycling with a yield of Alle of fluorine-containing materials Lae fluorine leads to desirability of recycling from the process, whereas sulfur dioxide can be separated by itself and either neutralized with an alkaline disinfectant 0 or recovered as commercially process products. 0 its simplified form by reducing (sale) recycling and reducing the accumulation of sulfur dioxide; However, in its most refined form, it also reduces recycling and Jie build-up of such contaminants as phosphorus, which is present in the aluminum production process; This led to improved efficiency in the electrolytic process for aluminum production; As long as this process 1 _ is somehow or other adversely affected by the increase in the contents of these substances. And given that sulfur p: 16 N 9 can be separated in one of the models of the invention; Mia can improve the environmental friendliness of aluminum production in its whole form. 7

Claims (1)

NAL PROTECTION_ELEMENTS Z | of the gas released from the fluorine process A method for the separation of fluorine-containing substances - 1 1 by means of adsorption on the surface of a solid; Y particulate aluminum production in a dry adsorption process; Where aluminum oxide and aluminum oxide the method includes the following steps: first dry adsorption of aluminum oxide; For the adsorption of the main part of the containing materials (HEY - mentioned aluminum oxide; where aluminum oxide fluorine is passed over fluorine Y in a direction opposite to the direction of the said gas path; particulate A with materials containing fluorine aluminum oxide Separation of aluminum oxide 9 from the aforementioned gas in the direction of the process, from the first adsorption stage, fluorine 0, before this aforementioned gas was transferred to the second adsorption stage, 11 particulate matter, which was separated with the materials aluminum oxide Part of aluminum oxide AY NY that has been adsorbed from the process of adsorption and return of fluorine containing fluorine 1 v | : particulate matter separated with aluminum oxide _ supplying the said part of aluminum oxide 4 aluminum to where the production process Aluminum fluorine fluorine-containing materials ve ida ya separated into aluminum oxide where the aluminum oxide is recycled VY the first adsorption; VA aluminum to the second adsorption stage and the gas treatment at this stage with a reactive 0 z aluminum oxide that has never been used before and in the form of aluminum oxide + 01 z 0 ' 0 z Said reactive yo aluminum oxide particulate granules; where the aluminum oxide YY which has not been used before is passed in a direction opposite to the direction of said gas path; And then YY particulate granules from the gas in the direction of aluminum oxide YY aluminum oxide is separated before the process is discharged or drained ast) from the dry adsorption stage YE gas in the surrounding external atmospheric air; Then at least part of the separated Z Yo oxide is transferred downstream of the process from the second dry aluminum oxide adsorption stage YT CLAN to the dry adsorption stage YY; In which the amount of aluminum oxide is monitored 1 way according to the element of protection - 7 1 z partially depleted and thus controlled in order to obtain aluminum oxide Y fluorine on an ideal adsorption of fluorine-containing materials sulfur is ideal for desorption on aluminum oxide £ in the first adsorption stage. aluminum oxide of aluminum dioxide © Aled method according to Claim 7 in which the aforementioned gas ( Gas - © 1: sulfur dioxide, hydrogen fluoride, containing at least hydrogen fluoride | Y separated in aluminum oxide and in which aluminum oxide is “sulfur dioxide |” The direction of the process and beyond the dry adsorption stage The second one contains dioxide.; Treatment of aluminum oxide with Led adsorbed from the aforementioned gas, and sulfur dioxide © sulfur adsorbed in the aforementioned sulfur dioxide stage with aluminum oxide 1 aluminum sulfur dioxide for aluminum 1 The ols oxide is heated by desorbtion 1 with a carrier gas flowing through it; Thus the principal amount of oxide A is pronounced d Y YY .aluminum oxide adsorbed sulfur dioxide q; Method according to the protection element? ; Where part of the oxide 1 is recycled into desorption As je treated in aluminum oxide Aluminum: ¥ The second adsorption stage in order to enhance the adsorption capacity at this stage. 1 > - method according to the claim; ; In which water vapor or nitrogen gas, nitrogen Y |, flows through aluminum oxide in the boiling stage (pronouncement). Desorption 1 1 - A method (according to claim Cuno) in which said process gas contains at least Y hydrogen fluoride, sulfur dioxide and carbon dioxide; And where the separated aluminum oxide is in it; The direction of the process and beyond the second dry adsorption stage containing sulfur dioxide adsorbed from the aforementioned gas; In it, the aforementioned aluminum oxide 1 is treated with sulfur dioxide adsorbed in the desorption stage, by heating the aluminum oxide A > with a carrier gas flowing from through it; Thus, the basic amount of q sulfur dioxide adsorbed on aluminum oxide is pronounced ee: YY. 1 7 - method according to claim 6; In which part of the desorption oxide that is processed in the aluminum oxide phase Y is recycled to the second dry adsorption stage in order to enhance the adsorption capacity at this stage. (YL A) - Method pursuant to claim 7; Cun in which water vapor or nitrogen gas flows: in the magnification stage aluminum oxide through aluminum oxide nitrogen Y . desorption 1 ] 1 4 - Method in accordance with claim 6; Where water vapor or nitrogen gas 1 flows into it through | oxide of aluminum oxide in the collection stage .desorption (pronunciation) 0 | | a