DE3521109A1 - Method and apparatus for the galvanomagnetic removal of ions from a liquid - Google Patents

Abstract

The invention relates to the removal of ions from a liquid, especially the desalination of seawater and the like. It is proposed that, in a separation cell (1) through which the liquid is flowing, an electric field (8) is maintained in the flow direction by means of electrodes (5, 6), and at the same time to have a magnetic field (B) acting perpendicular to the electric field (8) and the flow direction. As a result, the ions (9, 10) contained in the liquid are deflected perpendicularly to the electric field (8) and to the direction of the magnetic field (B), these deflections together with the effective Coulomb forces jointly resulting in a concentration shift of the ions. It is therefore possible to separate at the output side from the separation cell, via two outlet ports (3, 4), two part streams differently enriched in ions. By means of cascade-like connection in series of a plurality of separation cells, any degree of purification required can be achieved. <IMAGE>

Description

Method and device for galvanomagnetic removal of ions from a liquid The present invention relates to a method for galvanomagnetic Depletion of ions in a liquid, in particular also for the desalination of Water, according to the preamble of claim 1. and a device for implementation of the procedure. To remove ions from a liquid, for example for Desalination of sea water, many different processes are known.

In addition to distillation and reverse osmosis, there are also processes on the principle of electroosmosis and some other concepts.

It is also known, for example from GB-A-2 123 399, liquids to clean with the help of magnetic resonance, with electrodes of different polarity are arranged in the liquid container. Furthermore, there is knowledge about the occurrence the Hall effect in electrolyte solutions, as described, for example, in reports of the Bunsen Society for Physical Chemistry "Volume 78, Number 4, 1974, page 325 - 331 under the title About the Hall effect on some electrolyte solutions and Membranes ", which explains the influence of electric and magnetic fields have on electrolyte solutions.

The object of the present invention is to provide a method for depletion of ions in a liquid to indicate the influence of electrical and uses magnetic fields on electrolyte solutions and makes them technically applicable. Furthermore, a device for carrying out the method is to be specified To the A method according to claim 1 is proposed as a solution to this problem the drawing will be explained in more detail, the liquid containing the ions if possible while maintaining the conditions for laminar flow through a separation cell conducted, in which a constant electrical field in the direction of flow by means of electrodes This makes positive and negative in the electric field Ions accelerated in different directions, making them different overall have high speeds.

At the same time it is perpendicular to the direction of flow and to the plane of the Separating cell maintain a constant magnetic field within the separating cell, which Lorentz forces exerted on the ions, which are based on Lenz's rule let determine. Electric and magnetic fields work together with the flow velocity the total of ions for positively and negatively charged particles in the same direction a concentration shift which is perpendicular to the electric field and to the Magnetic field runs. At the end of the separation cell, therefore, the liquid flow in a partial stream enriched with ions and a partial stream depleted with ions split up will.

In a further embodiment of the invention, it is proposed in claim 2, that in the separating cell an inhomogeneous electric field with a greatest density The presence is maintained in the area of the enriched partial flow an inhomogeneous field intensifies and increases the effect described above thus the separation factor of the separation cell.

In a further embodiment of the invention, it is proposed in claim 3, that several separation cells are cascaded one behind the other, like this in principle from the various systems for isotope enrichment, in particular uranium enrichment, is known. Through this becomes a far-reaching one It causes removal of all ions from the liquid, even if the individual separating cell only has a low level of efficiency. E.g. in seawater desalination discarding the enriched fraction without affecting the input concentration.

In a special embodiment of the invention, it is proposed in claim 4, the magnetic field by permanent magnets, electromagnets or by superconductors Create magnets. Depending on the size of the plant and the desired magnetic Field strength, which in turn has an influence on the separation factor, can be suitable Magnets to be selected.

In claim 5, a method is proposed which is in particular Suitable for smaller systems, where it is not a question of large throughputs but of minimization of the technical effort. To this end, it is suggested only one or a few To connect separating cells one behind the other, but these from the ion-containing liquid to pass through several times, with the depleted liquid from the respective Work cycle buffered and in the next work cycle to the inlet of the system is returned.

A device for carrying out the method according to the invention is described in claim 6. This arrangement enables simultaneous maintenance an electric field in the direction of flow and a magnetic field perpendicular to the direction of flow, creating the desired shift in concentration. achieved becomes and at the end of the separation cell two differently enriched with ions Let the partial flows of the liquid separate In a special design of the invention is proposed in claim 7 that an electrode near the liquid inlet is arranged and extends in a grid-like manner over the entire cell cross-section, while the second electrode is near the liquid outlet for depleted liquid is arranged and extends in a grid shape only approximately over this outlet cross-section. This allows an inhomogeneous electric field to be maintained in the cell, which is shaped particularly favorably for a good separation factor.

In a further embodiment of the invention, it is proposed in claim 8, that the electrodes are isolated from the liquid. This allows apply high field strengths without causing an electrode reaction with possible gas development, d. H. electrolysis, comes.

Correspondingly, it is proposed in claim 9 that the electrodes should be designed for application of high voltage, at least for 100 volts ,. but preferably even for voltages of up to several kilovolts.

According to claim 10 are also means. to equalize the Flow in or in front of the separation cell provided to turbulence and thereby a Avoid reducing the separation factor.

For use on liquids in which ions are very different Ion mobility are included, is specifically proposed according to claim 10, to polarize the electric and magnetic field just so that the more mobile ion species is deflected towards the enriched liquid outlet. This measure improved the separation process and is, for example, for liquids such as hydrochloric acid (HCl) and the like suitable.

For a better understanding, let the theory on which the invention is based explained in more detail with reference to the drawing.

An exemplary embodiment of the invention is shown schematically in the drawing shown, namely Figure 1 shows a separating cell according to the invention in a section in the X-Y plane according to the associated coordinate system and FIG. 2, a section through the separating cell in the X-Z plane.

The separating cell 1 consists of a preferably rectangular flow channel with electrically non-conductive walls. It has an inlet 2 and two in the Outlets 3, 4 lying next to one another in the X-Y plane. Near inlet 2, one is preferred Arranged grid-shaped electrode 5, which extends in the Y-Z plane. Further is near the one outlet 3, a likewise preferably grid-shaped electrode 6 arranged, which extends in the Y-Z plane over the outlet cross section of the outlet 3 extends. The electrodes 5, 6 can be connected to a DC voltage source 7. This creates an electric field E, the course of which is indicated by the field lines 8 is maintainable within the separation cell 1. The coordinate system assigned to FIG. 1 illustrates the direction of the individual parts and fields. The direction of flow the liquid is indicated by arrows If there are ions in the liquid 9, 10 are located, these are depending on the sign of their charge by the electrical Field accelerated or decelerated. The positive ions receive the speed ev +, the negative ions the velocity v-.

As illustrated in FIG. 2, in addition to the electric field E in the separation cell 1 also maintain a magnetic field B, which is in the Z direction runs, d. H.

perpendicular to the direction of flow and to the plane of the separating cell 1. Preferably the separating cell 1, as shown in Figure 2, lies between the pole pieces 11, 12 of a magnet, which is a permanent magnet, an electromagnet or a superconducting magnet. There can also be several Separating cells interconnected as a cascade within the pole shoes of a magnet to be ordered.

To understand the invention, the following theoretical details should be pointed out: An electrical charge e moving at speed v is deflected in a magnetic field B by a force K, for which the following applies: Opposite charges are then deflected in different directions. Due to the additional influence of an electric field E, however, the ions with different signs receive a different speed, so that they are deflected to different degrees. At the same time, of course, the Coulomb attraction between the charges also acts, which results in a resulting force on all ions in a direction perpendicular to the direction of flow, ie in the Y direction. When a liquid containing ions flows through the separation cell, positively and negatively charged ions are therefore deflected to one side in the Y direction. This creates a concentration shift, which can be used at the outlet of the separation cell to separate an ion-enriched and a depleted fraction. The separation factor, ie the concentration ratio between enriched and depleted fraction, depends on the magnetic field strength, the electric field strength, the length of the separation cell on which these field strengths act and on the cross-sectional ratio of the two outlet openings of the separation cell. By influencing these variables, separating cells can be implemented for various applications. The speed of migration of the ions involved and some other effects occurring in electrolytes must be taken into account in the calculations. However, suitable separating cells can be constructed for most applications.

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Claims (11)

Method and device for galvanomagnetic removal of ions from a liquid Patent claims 1. Method for galvanomagnetic separation of ions from a liquid, characterized by the following features: a) The Liquid containing Ione # is produced in compliance with the conditions for laminar Flow passed through a separation cell (1). b) In the separation cell (1) is means. Electrodes (5, 6) attached to a DC voltage source (7) are connected, an electric field (8) in the direction of flow (X) maintained. c) perpendicular (Z) to the direction of flow (X) and to the plane (X, Y) of the Separating cell (1), a magnetic field () is maintained within the separating cell. d) At the end of the separating cell (1), the liquid flow is split up into an ion-enriched (3) and an ion-depleted (4) partial flow corresponding to the direction perpendicular to the magnetic field (B) and to the direction of flow (X) in the Separation cell (1) took place ion concentration shift. 2. The method according to claim 1, characterized in that in the separating cell (1) an inhomogeneous electric field (8) with a greatest density in the region of the enriched partial flow is maintained 3. Procedure according to Claim 1 or 2, characterized in that several separating cells (1) are cascaded are connected in series, each of which is depleted in a separating cell (1) Partial flow is depleted more and more in further separation cells (1), while the enriched part streams discarded or to the inlet of previous separation stages be returned. 4. The method according to claim 1, 2 or 3, characterized in that the magnetic field (B #) by permanent magnets, electromagnets or superconductors Magnet is generated. 5. The method according to any one of the preceding claims, characterized in, that one or more separating cells (1) connected like a cascade with intermediate storage of the depleted amounts of liquid operated in such a discontinuous period that the temporarily stored amounts of liquid in the next working cycle be further depleted. 6. Apparatus for performing the method according to claim 1, characterized by the following features: a) between the pole pieces (11, 12) of a magnet at least one of a liquid .perpendicular .to the direction of the magnetic field (B #) through which flow separating cell (1) is arranged. b) The separation cell (1) forms a flow channel which has a liquid inlet (2) and adjacent to one another a liquid outlet (3) for enriched with ions liquid and a liquid outlet (4) for ion depleted liquid. c) In the separating cell (1) electrodes (5, 6) are arranged in such a way that that when a voltage is applied, an electric field (8) is maintained in the direction of flow is obtainable. 7. Apparatus according to claim 6, characterized in that an electrode (5) is arranged near the liquid inlet (2) and extends in a grid-like manner about extends the entire cell cross-section and that the second electrode (6) near the Liquid outlet (3) is arranged for depleted liquid and is grid-shaped extends approximately over this outlet cross-section. 8. Apparatus according to claim 6 or 7, characterized in that the electrodes (5, 6) are insulated from the liquid. 9. Apparatus according to claim 8, characterized in that the electrodes with a voltage of several kV, but at least of up to 100 Vl are. 10. Device according to one of the preceding claims, characterized in that that means for equalizing the flow in or in front of the separating cell (1) are present are 11. Device according to one of the preceding claims, characterized in that that the magnetic field (B #) and the electric field (E #) are straight so are polarized that with ions contained in the liquid of different mobility the more mobile ions towards the enriched liquid outlet to get distracted