DE3238280A1 - Process for desalting solutions - Google Patents

Abstract

A process for desalting solutions with use of an electrodialysis cell (25) is described. The solutions are first introduced into a chamber (28) of the cell (25), said chamber being delimited by two cation exchanger membranes (5, 6) and filled with ion exchanger material, and the solutions are then passed to another chamber (31) likewise filled with ion exchanger material, which is delimited by two anion exchanger membranes (14, 15). Next to each of the first two chambers (28, 31), other chambers (29, 33) are provided, which are delimited on the sides away from the first chambers (28, 31) by membranes (9, 16) differing with respect to selective permeability from the membranes of the first chambers (28, 31) and which are filled with liquids, which prevent the formation of sparingly soluble products. <IMAGE>

Description

Method of desalination of solutions ## ;.

The invention relates to a method for desalination of solutions, in which the solutions are passed through electrodialysis cells which are permselective Membranes are divided into chambers, of which those bounded by the membranes Chambers contain ion exchange material, and the at least one anode and at least have a cathode.

For the desalination of solutions, ion exchange processes are predominantly used today used. With this process, for example, softened, partially desalinated or fully demineralized water can be obtained as it is, for. B. in the food industry, for steam generation, in nuclear engineering, in many branches of raw materials processing Industry and chemistry are required in large quantities and in varying degrees of quality will.

Ion exchangers are divided into cation exchangers and anion exchangers. Depending on the task, there are weakly or strongly acidic cation exchangers and weakly or strong basic anion exchangers. The ion exchangers exist essentially of exchange material, such as, for example, resins.

They take up ions from the solutions given to them and give instead, an equivalent amount of counterions charged in the same direction. When the receptivity the exchanger material is exhausted, it must be regenerated.

Another way to desalinate solutions is through electrodialysis given, in which cells are used, in which permselective membranes are used are. Electrodialysis differs from the ion exchange process described above mainly because no regeneration is required because the separation of the Ions are made steadily by the electric field alone. The ion exchangers must however, using regeneration chemicals, e.g. B. hydrochloric acid and caustic soda, be regenerated as soon as their exchange capacity is exhausted.

A method with an electrodialysis cell as described at the beginning is apparent from, for example, US Pat. No. 3,084,113. In the simplest case is the electrodialysis cell used in this known method through a cation exchange membrane and an anion exchange membrane divided into three chambers. To carry out of the process is the middle chamber filled with ion exchange material a saline solution is supplied. The electrodialysis causes the cations transported through the cation exchange membrane into the cathode compartment, and the anions migrate through the anion exchange membrane into the anode compartment. In this way, the salt content in the middle chamber will decrease.

To avoid the electrical resistance of the middle chamber increases too much with increasing desalination of the solution, the chamber contains that Ion exchange material.

The electrodialytically separated ions reach this known Process from the middle chamber into the electrode spaces, so that there are undesirable Redox reactions take place. In particular, sparingly soluble precipitation products can be used develop, through which the permeability of the membranes is hindered will.

Furthermore, cathodic metal deposition would take place after a short time make it necessary to remove the metal from the cathode compartment, the method would have to be interrupted. An anodic evolution of poisonous gases, such as Chlorine gas would result in an inadmissible pollution of the environment.

By an alternating one also known from US Pat. No. 3,084,113 Multiple arrangement of cation and anion exchange membranes in a cell can these disadvantages cannot be circumvented. In addition, in this case, in the chambers in which the ions accumulate, the risk of precipitation of poorly soluble ones Chemical compounds are made up of what makes the membrane permeable to ions would affect.

The invention is based on the object of an electrodialysis process to specify the desalination of solutions in which undesired redox reactions to the Electrodes are avoided and in which the permeability of the membranes is impaired Precipitation products cannot arise.

In a method, this task is as described at the beginning Type solved according to the invention, - that the solutions first by one of two cation exchange membranes delimited and filled with ion exchange material Chamber of a first electrodialysis cell are passed through, - that from this Chamber of the first electrodialysis cell escaping solutions then through one of two anion exchange membranes delimited and filled with ion exchange material Chamber of a second electrodialysis cell are passed through, - that in the first Electrodialysis cell outside the chamber filled with ion exchange material at a distance from the same on the side facing the cathode, an additional one Anion exchange membrane is arranged - that in the second electrodialysis cell outside the chamber filled with ion exchange material at a distance the same a cation exchange membrane is additionally arranged on the side facing the anode - That the two electrodes are outside the chambers delimited by the membranes are arranged, - and that in the chambers containing the electrodes and in the each of a cation exchange membrane and an anion exchange membrane limited chambers the formation of sparingly soluble compounds preventing liquids be introduced.

In this process, the solutions to be desalinated become the chambers of the Abandoned electrodialysis cells, which are bounded by membranes of the same type. Due to the additional arrangement of a different type of membrane between each the chamber filled with ion exchange material and the opposite polarized chamber This method ensures that the electrode is separated in the chamber Ions cannot reach this electrode. Undesired redox reactions are avoided in this way for sure. In addition, since both the electrodes containing chambers as well as the chambers delimited by different membranes Containing liquids that do not give rise to any precipitation products are flawless Permeability of the membranes guaranteed. The invention thus provides an electrodialysis process specified, which ensures continuous and trouble-free operation. if the solutions to be desalinated the two filled chambers of the two electrodialysis cells then desalinated water emerges from the chamber of the second cell that can be used directly for the respective purpose.

Through the use of suitable permselective membranes and the use of suitable liquids in the chambers of the electrodes and in those of dissimilar ones Membrane-confined chambers, this process is universal for desalination of all possible solutions. Accordingly, both neutral as well as acidic or alkaline solutions.

The mass transfer at the phase boundary of the permselective membranes is more intense when the thickness of the diffusion boundary layer is enforced Convection in connection with turbulence is reduced. That goes with Achieve a corresponding flow rate of the solutions when used as an ion exchange material loose beds of resin granulate are used in the corresponding chambers. This reduces the polarization on the membrane surfaces, so that higher Current densities are applicable and the consumption of electrical energy is still low remain.

An increase in the temperature of the whole acts in the same way Systems (liquids, ion exchange material, membranes), both by Joule Heating as well as by additional heat supply can be brought about. Because a warming by 10 C an increase in the specific electrical conductivity of about 3% As a result, the method can be operated by heating to, for example 600 C significantly improve. The easier solubility of Salts have a beneficial effect at higher temperatures.

The heat balance of the liquids can be adjusted with the help of counterflow heat exchangers adjust optimally.

In a preferred embodiment, the two are electrodialysis cells combined in a common cell, also in this embodiment only one anode and one cathode are required. In this case, between A chamber delimited by permselective membranes is provided for the two cell parts be in the desalinated water or a low-salt liquid as well as ion exchange material available.

In a further embodiment of the method, it is also possible to arrange several units in parallel next to each other in an electrodialysis cell, each corresponding to the first or the second electrodialysis cell.

The method according to the invention is illustrated in exemplary embodiments with reference to the drawings explained.

In the following description, for the sake of simplicity, instead of the The word "electrodialysis cell" always uses the word "cell".

They show: FIG. 1 a cell with two cation exchange membranes and an anion exchange membrane.

FIG. 2 shows a multiple arrangement of the membranes of the cell according to FIG. 1 3 shows a cell with two anion exchange membranes and one cation exchange membrane.

4 shows a multiple arrangement of the membranes of the cell according to FIG. 3. 5 a cell combined from the cells according to FIGS. 1 and 3.

6 shows a combined cell that is modified from FIG. 5.

FIGS. 7 and 8 supplemented embodiments of the cells according to FIG. 1 and 3.

For the separation of cations, a first cell 1 is chosen, such as it is shown schematically in FIG. 1. In the two outer chambers of this Cell are z. B. lead grid as anode 2 and cathode 3, which are in sulfuric acid dive. The chamber 7 delimited by two cation exchange membranes 5 and 6 is filled with ion exchange material 8. Between the chamber 7 and the cathode 3 is - at a distance from both - an anion exchange membrane 9 is arranged. The chamber 7 a solution to be desalinated is applied (arrow 10). The cations migrate in bounded by the cation exchange membrane 6 and the anion exchange membrane 9 Chamber 11. In this chamber there is a solution, e.g. B. dilute sulfuric acid, whose pH is adjusted so that no hydroxide precipitation occurs. To the electric Reduce resistance in the chamber 11, it can also with ion exchange material be filled.

To speed up the process or to remove large volumes of salt at solutions according to FIG. 2, several arrangements according to FIG. 1 in one common cell 12 are arranged. Even with this multiple arrangement only one anode 2 and one cathode 3 are required.

A second cell 13 is used for the separation of anions, which is shown schematically in FIG. 3. This cell contains two anion exchange membranes 14 and 15 and a cation exchange membrane 16. In the two outer chambers the cell 13 are z. B. an anode 17 and a cathode 18 made of expanded steel metal, which are immersed in caustic soda. In the of the anion exchange membranes 14 and 15 Limited chamber 19 is ion exchange material 20. The from the anion exchange membrane 14 and the cation exchange membrane 16 limited chamber 21 can be used to reduce of the electrical resistance must also be filled with ion exchange material. In the chamber 13 there is also, for example, a weak liquor such. B. diluted caustic soda to avoid the formation of poorly soluble compounds.

If several arrangements of the cell 13 according to the illustration 4 operated in parallel in a common cell 22 are again only Electrodes (anode 17 and cathode 18) required in the end chambers.

The solution emerging from the chamber 7 of the cell 1 can accordingly the arrow 23 of the chamber 19 of the cell 13 are given, from which then accordingly the arrow 24 a desalinated solution emerges.

The operation with two separate cells 1 and 13 can thereby be simplified that a cell 25 is used according to FIG. 5, in which the membranes of these two cells are combined: The cell 25 according to FIG. 5 consists of seven Chambers, each separated by permselective membranes, with the designation of the membranes of Figs. 1 and 3 is retained. The two outer chambers contain an anode 26 which, for. B. immersed in sulfuric acid, and a cathode 27, which z. B. is in sodium hydroxide solution. The solution to be desalinated is that of the two adjacent cation exchange membranes 5 and 6 delimit chamber 28 abandoned, and the cations, e.g. B. Na +, Ca2 + Mg + etc., migrate to the right adjacent chamber 29, from which they are withdrawn in a partial flow of water can.

The deboned water exits the chamber 28, as indicated by the arrow line 30 indicated, into which of the two adjacent anion exchange membranes 14 and 15 limited chamber 31, which it leaves desalinated (arrow 32). The anions pass through the anion exchange membrane 14 into the adjacent one on the left Chamber 33, from which they, like the cations, are withdrawn by a partial water flow can be. As already described for the cells according to FIGS. 1 and 3, in the chambers 28 and 31 arranged ion exchange material. Also in chambers 29 and 33 such material can be attached.

The solutions enriched with cations and anions may be in of the cell 25, of course, do not mix, because otherwise precipitation products would arise, through which the membrane permeability would be impaired. Therefore is between the chambers 29 and 33, in which the cations or anions accumulate, a Chamber 34 is provided with demineralized water or another, low-salt liquid, that of an anion exchange membrane 9 and a cation exchange membrane 16 is limited, and their electrical resistance by a filling with ion exchange material is kept low.

Special measures can be taken with electrodialytic desalination aqueous solutions may be required if acidic or alkaline solutions are present or if wastewater is to be desalinated, its salt content and pH value are often within further limits can fluctuate. From alkaline solutions are z. B.

essentially removing cations. Therefore the cations require a higher partial flow than the anions. To solve this problem, two Cells as shown in FIG. 1 and FIG. 3, corresponding to FIG. 6 to one Double cell 35 can be combined with one another. Here, too, are for the membranes the same reference numerals as in FIGS. 1 and 3 are used. In contrast to the execution form According to FIG. 5, two electrode arrangements are required here, with the anodes 36 and 37 and the cathodes 38 and 39, which have rectifiers 40 and 41 are supplied with power. This allows the currents with which the cations or anions are electrodialytically separated from a solution, set separately. The solution to be desalinated is given to the chamber 42 and from there to the chamber 43 passed, both of which are filled again with ion exchange material.

The double cell 35 shown in FIG. 6 can again be selected from a large number consist of single cells, as is the case for the cells according to FIGS. 1 and 3 in FIGS 4 is shown.

Since the cations in electrodialysis are under the influence of the electric Field to the cathode and the anions migrate to the anode, it can be advantageous to shorten these movements by asymmetrically abandoning the solutions. Appropriate Cells 44 and 45 are shown schematically in FIGS. 7 and 8. You have in In addition to the membranes, a diaphragm 46 or 47 in addition to the respective chambers.

Another measure to avoid solutions-with fluctuating salinity and To desalt the pil value consists in that one cell 25 according to FIG. 5 cells 1 and 13 according to FIG. 1 and FIG. 3 and their electrodialysis currents accordingly automatically adjusts to the pH value and the salt concentration. That way will a large part of the cations or anions are pre-separated, and the cell 25 accordingly Fig. 5 takes over the function of a fine cleaning. Of course you can but also change the order of the cells.

The procedure can be used in all cases, whether with separate cells 1 and 13 or common cells 25 and 35 is used, even at elevated temperatures be performed. For this purpose, the Joule heat of the, which then cannot be dissipated System are exploited. However, it is also possible to obtain heat from by heating to be supplied outside, the type of heating being arbitrary. For the optimal setting the heat balance of the liquids can also be countercurrent heat exchangers known per se insert.

For the filling of the chambers with ion exchange material it is advisable loose fillings of resin granulate are used. By flowing around the resin particles This creates turbulence within the liquid, including on the membrane surfaces.

This allows in particular the thickness of the diffusion boundary layer on the membranes advantageously reduce The method according to the invention is in The foregoing has been described for the desalting of solutions in which both cations as well as anions are to be separated. For those skilled in the art, the term "desalting" includes also the treatment of bases and alkalis, from which either only cations or only Anions are to be removed. The method should also be used for these applications of the invention apply, in which case only one of cells 1 or 13 or only one of the cells 12 or 22 are required.

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Claims (7)

Claims fE g method for desalination of solutions, in which the solutions are passed through electrodialysis cells, which are permselective Membranes are divided into chambers, of which those bounded by the membranes Chambers contain ion exchange material, and the at least one anode and at least have a cathode, characterized in that - that the solutions initially through one of two cation exchange membranes (5,6) bounded and with ion exchange material (8) filled chamber. (7) a first electrodialysis cell (1) are passed through, - That the exiting from this chamber (7) of the first electrodialysis cell (1) Solutions then pass through one of two anion exchange membranes (14, limited and. with ion exchange material (20) filled chamber (19) of a second electrodialysis cell (13) are passed through - that in the first electrodialysis cell (1) outside the chamber (7) filled with ion exchange material (8) with waste was standing to the same, on the side facing the cathode (3), there is also an anion exchange membrane (9) is arranged - that in the second electrodialysis cell (13) outside the with ion exchange material (20) filled chamber (19) at a distance from the same on the side facing the anode (17) additionally a cation exchange membrane (16) is arranged - that the two electrodes (2,3) outside of the through the Diaphragms delimited chambers are arranged, - and that in which the electrodes (2,3) containing chambers and in each of a cation exchange membrane (16) and an anion exchange membrane (9) bounded chambers the emergence of liquids preventing poorly soluble compounds are introduced. 2. The method according to claim 1, characterized in that the membrane assemblies the first electrodialysis cell (1) and the second electrodialysis cell (13) in one common electridialysis cell (25,35) are combined. 3. The method according to claim 1 or 2, characterized in that in the common electrodialysis cell (25) uses an anode (26) and a cathode (27) be, and that in between the individual anion exchange membrane (9) and the individual cation exchange membrane (16) adjacent to it (34) demineralized water or another low-salt liquid as well as ion exchange material to be ordered. 4 The method according to claim 1 or 2, characterized in that in the common electrodialysis cell (35) has two pairs of electrodes (36,37,28,39) which are supplied separately with power via separate rectifiers (40, 41). 5. The method according to any one of claims 1 to 4, characterized in that that loose granules are used as ion exchange material. 6. The method according to any one of claims l to 5, characterized in that that the desalination is carried out at an elevated temperature. 7. The method according to any one of claims 1 to 6, characterized that in the chambers filled with ion exchange material, which are to be desalinated Solutions are applied in the vicinity of one of these chambers delimiting membrane a diaphragm (46, 47) is also arranged.