NL8500017A - Electrodialysing e.g. to desalinate salt soln. - using cells contg. ion-selective permeable membranes supplies energy from cells contg. bipolar membranes between acid and alkaline solns. - Google Patents

Abstract

Method carries out electrodialysis in one or more cells each contg. at least one ion-selective membrane using energy supplied by applying an electric potential across the cell. Energy is generated by reverse dialysis in one or more cells each contg. at least one ion-selective membrane, this energy being supplied to the cell(s). The energy cell(s) may be supplied with acid and alkali, e.g. HCl and NaOH, to opposite sides of a bi-polar membrane whereby H2O is formed by combination of the respective H+ and OH- ions. The cell(s) may be used to de-salinate water.

Description

* * '"» H AL / EW / 1 Bergman

Method for electrodialysis and electrodialysis device

The invention relates to a method for electrodialysis, in which energy is generated by means of a dialytic process in at least one energy cell provided with at least one ionically permeable membrane, and in which the generated energy is taken off.

This method is known from EP 0 013 113. In this known method electrical energy is removed from the energy cell via electrodes.

The invention provides a method which is simplified as far as the energy supply is concerned, in that energy is generated by means of a reverse dialytic process in at least one energy cell provided with at least one ionically permeable membrane which is converted into the consumption cell for a dialytic process. used up.

Preferably the reverse dialytic process and dialytic process are linked together in endless series.

Since in this preferred method no more electron currents are present, but ion currents are present, iodialysis is then referred to.

The invention also relates to and provides an electrodialysis device which is specially suitable for carrying out the method according to the invention.

Further features and advantages are described with reference to a drawing, in which: figure 1 shows a diagram of an electro-dialyzing method according to the invention; figure 2 shows a diagram of a preferred method for | electrodialysing according to the invention; figure 3 shows a diagram of another preferred method 30 according to the invention.

figure 4 shows an electrodialysis device according to the invention.

In a method for electrodialysis according to the invention (figure 1), an electrodialysis device 35 1 comprising consumption cells 2, energy cells 3, electrodes 4 85 0 0 0 17 -2- <* · w resp. 5, and an electrical coupling part 15 - a consumption cell 2 and energy cell 3 are bounded by dotted lines -, at the arrow 6 acid, for example HCl in water, at the arrow 7 base, for example NaOH in water and at the arrow 8, water for -5 namely NaCl in water, fed. In an known manner, an energy cell 2 is provided with a bipolar membrane 9, which transmits only H + ions from the HCl side and only OH-ions from the NaOH side, so that H2O is formed at the bipolar membrane and an electrical voltage difference 10 between the acidic resp. basic compartment 10 resp. 11 is generated. If two energy cells 3 are placed one behind the other, an electrical connection between the energy cells is ensured by means of a salt water-fed intermediate compartment 14, since a Na + -selective permeable membrane 16 and a Cl "" -selectively permeable membrane 17 Na + - and Cl Maintain flows into the intermediate compartment 14, whereby the water discharged from the intermediate compartment 14 is saltier than the supplied saline water. At the arrows 12 and 13, respectively, the dilute acid or the dilute base is discharged.

A consumption cell 2 has a saline water-fed middle compartment 18 and, in series connection with an energy cell 3 or another consumption cell 2, also forms intermediate compartments 14 which, in the same manner as described, form an electrical connection, and the drained water of which is saltier than the supplied salty water. The middle compartment 18 is fed with saline water and communicates with the intermediate compartments 14 via a Na + selective permeable membrane 16 and a C1 - selective permeable membrane 30, whereby the Na + -, respectively. C1-ions from the middle compartment 18 are led and the water is desalinated. Therefore, fresh water is obtained at arrow 19 and salt water at arrow 20 is drained away than the salty water.

The electrodes 4, 5 are via end compartments 21 and 21, respectively, fed with salt water. 22 conducting with the electrolysis device 1 and via the electrical coupling part 15 comprising an electric lead, a resistor 24 and an electric device 25 mutually coupled. Depending on operating conditions - strength of acid and base, 8500017 -3 - brine content of the water, flow rates - either over the resistor 24, a positive voltage with respect to the electrode 4, can be taken off, or for more desalination of the water apply a negative voltage with respect to the electrode 4 by means of the electrical device 25.

Preferably, in the method according to the invention, both the consumption cells 2 and the energy cells 3 are chosen as small as possible in the direction of the electric current in order to minimize the electrical resistance.

Preferably, the voltage differences over one I.

consumption cell 2 kept small for keeping electrical leakage currents small via supply and discharge lines of liquid.

In existing electoral dialysis methods, the leakage currents limit the number of series-connectable energy cells 3. Since an energy cell 3 supplies an electrical voltage sufficiently large for the operation of a number of consumption cells 2 in the order of magnitude of 5, it is preferred that | 20 groups of one reverse dialytic process and of a number of dialytic processes of the order of five in series are connected in series. Therefore, at;

preferred energy cells and consumption cells alternate in J

series connected in a certain numerical ratio.

This allows a long circuit to be formed.

Preferably, energy cells 26 and consumables are used. cells 27 in an endless series placed one behind the other (figure 2). In this preferred embodiment of the method according to the invention, the electrodes of Figure 1:30 which are subject to corrosion can be omitted and a method for electrodialysis, in particular for desalination of water, is obtained. The electrodialysis device 28 according to the invention is provided with reservoirs 29, 30 and 31 for NaOH dissolved in water, for HCl dissolved in water, respectively. for salt water.

As indicated by the arrows 32, 33 resp. 34, the NaOH solution and the HCl solution are supplied to energy and consumption cells 26 and 6 connected in an endless series. 27 corresponding to the energy and consumption 8500017 -4 cells 3 resp. 4 from figure 1, but are of such a shape that they can be placed in an endless series, for instance a cylinder.

The dilute HCl acid is discharged as indicated by arrow 35 and the diluted NaOH base is discharged as indicated by arrow 36. The saltier water than the supplied saline water is discharged as indicated by arrows 37 and main arrow 38. Fresh water is obtained and discharged at arrow 39.

In another preferred embodiment of the method according to the invention (figure 3), an HCl solution, resp. a NaOH solution kept at constant concentration by means of controllable pumps 42 resp. 43 containing 44 reservoirs fed with concentrated HCl and NaOH. 45 are linked. The mixing chambers 40 and 41 are coupled on both the inlet side - via pumps 46 and 45, respectively. 47 - as the output side with an energy cell provided with energy cell 48 of the electrodialysis device 28, of which one consumable cell with consumable 49 is fed with saline water at arrow 50 with the aid of a pump 51. At arrow 52 saline water is fed to the energy part 48 is supplied and at arrows 53, 54 resp. 55, salt water is discharged, salt water is discharged, resp. fresh water obtained. The mixing chambers 40, 41 are furthermore via pumps 56 resp. 57 coupled with an energy cell powered energy device for obtaining electrical energy from the less concentrated acid and the less concentrated base. Salty water is supplied at arrows 60, 61, respectively. salt water drained. An electrical voltage is taken at terminals 58.

It is noted that with the method schematically shown in Figure 3, both electrical energy and fresh water in an area with scarcity of both - for example the desert - can be obtained from concentrated acid and base 35 and saline water, but also, for example, from a concentrated and a less concentrated salt solution with which an electrodialysis voltage can also be obtained. It is further noted that the flow rates of the pumps 42, 43, 46, 47 and 51 are accurately coupled together to obtain 8500017

»V

-5- a certain amount of fresh water per unit time and an associated amount of electrical power.

In an electrodialysis device 62 according to the invention (figure 4), saline water is introduced at the top via a top closure through openings 80 into energy cells 64 and consumption cells 65. Acid, for example HCl, contained in the outer compartment 67 is kept concentrated via a side connection 66 by means of concentrated acid. A base, for example NaOH, is kept in concentration in the inner compartment 69 via a central connection 68 by means of concentrated base. The energy and consumption cells 64 resp. 65 operate in the same manner as described above, and are provided with bipolar and ion selectively permeable membranes 70, 71, respectively. 72, for example, for the formation of H 2 O, for example the passage of the C 1 ions, respectively. Na + ions. The circular partitions 79 are impermeable to the liquids and ions present. Via openings 73, 74 resp. the fresh water and salt water than the supplied saline water in a fresh water reservoir 75 provided with a drain 76, respectively. into a salt water reservoir 77 provided with a drain 78.

By means of the discharge velocities of the fresh and salt water via the discharges 76 resp. 78 and by means of the acid and base concentration in the outside and. within the room, the desalination rate of the saline water and thus the amount of fresh water produced is controlled with a certain maximum saline concentration. j

It should also be noted that in the above-described embodiments of the invention energy cells can also be used, which energy cells operate without acid and base and bipolar membrane, but for instance with a highly concentrated and a less concentrated salt solution and anion and cation-selectively permeable membranes, as a result of which a decreasing concentration difference between the salt solutions 35 and an electric voltage is created. The highly concentrated salt solution is obtained, for example, via a salt solution from the electrodialysis device according to the invention, thickened with solar heat.

8500017

Claims (9)

Method for electrodialysis in at least one consumption cell (2, 27, 65) provided with at least one ionically selective permeable membrane (16, 17, 71, 72) by adding energy, characterized in that by means of an Inverted dialytic process energy is generated in at least one energy cell (3, 26, 64) provided with at least one ion-selective permeable membrane (9, 70), which is consumed in the consumption cell (2, 27, 65) for a dialytic process. T0 2. Method according to claim 1, characterized in that energy is generated in the energy cell (3, 26, 64) by means of an acid-base reaction using a bipolar membrane (9, 70), where H2O is formed from H + and OH ions of the acid resp. of the base. Method for electrodialysis in at least one consumption cell (2, 27, 65) provided with at least one ionically selective permeable membrane (16, 17, 71, 72) by adding energy, characterized in that by means of an reverse dialytic process energy is generated in at least one energy cell (3, 26, 64) provided with at least one ion-selective permeable membrane (9, 70), which is consumed in the consumption cell (2, 27, 65) for a reverse dialytic process . Method according to claim 1, characterized in that energy is generated in the energy cell (3, 26, 64) by means of an acid-base reaction using a bipolar membrane (9, 70), wherein H 2 O is formed from H + and OH ions of the acid resp. of the base. Method according to claim 1 or 2, characterized in that water is desalinated in the dialytic process in the consumption cell. Method according to claim 1 or 2, characterized in that water is desalinated in the dialytic process in the consumption cell. Method according to claim 1, 2 or 3, characterized in that the dialytic process and the reverse dialytic process are coupled in series. Method according to claim 4, characterized in that the dialytic process and the reverse dialytic process are linked together in an endless series. Method according to claim 1, 2 or 3, characterized in that the dialytic process and the reverse dialytic process are coupled in series. Method according to claim 4, characterized in that the dialytic process and the reverse dialytic process are linked together in an endless series. 6. Electrodialysis device (1, 28, 62) for carrying out the method according to any one of the preceding claims, comprising at least one consumption cell (2, 27) provided with an ion-selective permeable membrane (16, 17, 71, 72) , 65), characterized by at least one energy cell (3,26,30,64) provided with an ion-selectively permeable membrane (9, 70). 6. A method according to claim 4 or 5, characterized in that groups of one reverse dialytic process and a number of dialytic processes in the order of magnitude of 5 are successively coupled in series. Electrodialysis device according to claim 6, characterized in that the energy cell (3, 26, 64) is provided with a 85 0 0 0 1 7 ~ ££ WJ ~ ri Si-rib _3 brine content of the water, flow rates - can be either a voltage which is positive with respect to the electrode 4 is decreased across the resistor 24, or a voltage negative with respect to the electrode 4 is applied to desalinate the water more by means of the electrical device 25. ; Preferably, in the method according to the invention, both the consumption cells 2 and the energy cells 3 are chosen as small as possible in the direction of the electric current in order to minimize the electrical resistance. In existing electrodialysis methods, the leakage currents limit the number of electrodialysis cells 2 which can be connected in series. Preferably, the voltage differences across the circuit are kept small in order to keep electrical leakage currents small via supply and discharge lines of liquid. Therefore, preferably energy cells and consumption cells are alternately connected in series in a certain numerical ratio. This allows a long circuit to be formed. Preferably, energy cells 26 and consumption cells 27 are placed one behind the other in an endless series (figure 2). In this preferred embodiment of the method according to the invention, the electrodes of Figure 1 which are subject to corrosion can be omitted and a method for electrodialysis, in particular for desalination of water, is obtained. The electrodialysis device 28 according to the invention is provided with reservoirs 29, 30 and 31 for NaOH dissolved in water, for HCl dissolved in water, respectively. for salt water. As indicated by arrows 32, 33 and. 34, the NaOH solution and the HCl solution are fed to energy and consumption cells 26j resp. In an endless series. 27 corresponding to the energy and consumption j i i 8500017 «· AW-f7 / f ^, -ηύ / bipolar membrane (9, 70). Electrodialysis device (1, 28, 62) for carrying out the method according to any one of the preceding claims, comprising at least one consumption cell (2 provided with an ion-selective permeable membrane (16, 17, 71, 72) , 27, 65), characterized by at least one energy cell (3, 26, 64) provided with an ionically selective permeable membrane (9, 70). Electrodialysis device according to claim 6 or 7, characterized in that the consumption cell (2, 21, 65) is provided with at least one ion-selective permeable membrane (16, 17, 5 71, 72) for desalinating water. Electrodialysis device according to claim 7, characterized in that the energy cell (3, 26, 64) is provided with an 8 * MO 17-7 bipolar membrane (9, 70). Electrodialysis device according to claim 7 or 8, characterized in that the consumption cell (2, 21, 65) is provided with at least one ion-selective permeable membrane (16, 17, 5 71, 72) for desalinating water. Electrodialysis device according to claim 7,8 or 9, characterized in that groups of one energy cell and a number of consumption cells of the order of 5 are connected in series in series. Electrodialysis device according to claim 10, characterized in that the series of energy cells (26, 64) and consumption cells (2, 27, 65) is endless. Electrodialysis device according to claim 10 or 11, characterized in that the energy cells and consumption cells 15 (2, 21, 65) are each connected in groups of one energy cell and a number of consumption cells in the order of order of 5. e «« · j i i! i 8500017 4 c * -sB * Electrodialysis device according to claim 8, characterized in that the series of energy cells (26, 64) and consumption cells (2, 27, 65) is endless. • · · · 85 0 0 0 1 7