BE1030731B1 - Electrodialysis system for removing salt ions from water - Google Patents

Abstract

Electrodialysis system (1) for removing salt ions from water, characterized in that the electrodialysis system (1) is provided with at least one anode (2), at least one cathode (3) and at least one electrodialysis cell (4), which is provided with an anion selective membrane (5) and a cation selective membrane (6), wherein at least one electrodialysis cell (4) is arranged between the anode (2) and the cathode (3) and wherein the electrodialysis system (1) is provided with at least one porous carbon electrode (7) between the anode (2) and the electrodialysis cell (4) and at least one porous carbon electrode (7) between the cathode (3) and the electrodialysis cell (4).

Description

Electrodialysis system for removing salt ions from water. 3 The present invention relates to an electrodialysis system for removing salt ions from water.

Various systems are already known for removing salt ions and dissolved substances from water.

Typically, reverse csmosis is used to purify water. This is also called reverse osmosis and is often preceded by a number of steps. For example, classic filtration is first required to retain solids. Another disadvantage is that a filtration step must take place to adsorb chlorine and other volatile substances.

Reverse osmosis is a process in which water is demineralized by applying pressure to a membrane.

A pump pushes the water through the membrane in the opposite direction of flow from that of osmosis. However, this process consumes a lot of energy. Another well-known technique is distillation.

However, these known techniques have several disadvantages: “The process is very slow. Many systems can only produce a maximum of 15 liters of water per day

- BE2022/5604 are therefore only used for drinking water and not for the home or for showering. * Reverse osmosis is a very wasteful and relatively expensive technique. For every liter of water produced from reverse osmosis, 3 to 5 liters are thrown away . ® The vitality of the water decreases sharply during the entire process. « Almost all minerals are removed, 19th Systems must be thoroughly cleaned annually and fitted with new filters 1 to 2 times a year.

The present invention aims to provide a solution to at least the 13 advantages and other disadvantages.

To this end, the invention concerns an electrodialysis system for removing salt ions from water, wherein the electrodialysis system is provided with at least one anode, at least one cathode and at least one electrodialysis cell, which is provided with an anion-selective membrane and a cation-selective membrane, wherein the at least one electrodialysis cell is arranged between the anode and the cathode and wherein the electrodialysis system is provided with at least one porous carbon electrode between the anode and the electrodialysis cell and at least one porous sole material electrode between the cathode and the electrodialysis cell.

An advantage of this electrodialysis system is that substances, including salts, can be extracted from water. In this way, drinkable water can be produced from brackish water. This is particularly advantageous in third world countries where less reusable water is available.

The electrodialysis system can remove 70% — 90% of the total dissolved substances from the water to be purified,

Another advantage is that not all minerals are removed from the water. 1G

An additional advantage is that no additional chemicals are required or added.

Another additional advantage is that the electrodialysis system forms a barrier: Eliminates bacteria, viruses, and other microbes,

In contrast to the known reverse osmosis systems and distillation machines, the energy consumption depends on the salt content that one wishes to remove from the water to be purified.

However, the electrodialysis system is cheaper, more sustainable and requires less energy to extract salt ions from water, making the electrodialysis system ecologically more advantageous.

Preferably, a filter is installed in the supply pipe for filtering undissolved particles from the water to be purified.

A

An advantage of this is that the electrodialysis system is less likely to clog and become damaged,

This increases the lifespan of the device.

With the aim of better demonstrating the features of the invention, some preferred embodiments of an electrodialysis system according to the invention are described below, as an example without any limiting character, with reference to the accompanying drawings, in which: Figure 1 schematically shows an electrodialysis system according to the invention. represents invention; figures 2 and 3 and 4 show alternative embodiments of figure 1,

Figure 1 schematically shows an electrodialysis system 1 for removing salt ions from water. The electrodialysis system 1 is here provided with at least one anode 2 and at least one cathode 3. In addition, the electrodialysis system 1 is provided with at least one electrodialysis cell 4. This electrodialysis cell 4 contains an anion selective membrane 5 and a cation selective membrane 6. The aforementioned electrodialysis cell à is arranged between the anode 2 and the cathode 3.

Also, the electrodialysis system 1 is provided with at least one porous carbon electrode 7 between the anode 2 and the electrodialysis cell 4 and at least one porous carbon electrode 7 between the cathode 3 and the electrodialysis cell 4,

= BE2022/5604

The porous carbon electrodes 7 are preferably attached to the associated anode 2 or cathode 3.

The electrodialysis system 1 contains a supply line 8 for supplying the water to be purified to the electrodialysis cell 4 and a discharge line 3 for discharging the purified water from the electrodialysis system 1.

The electrodialysis system 1 contains an energy supply 10 that applies an electric field between the anode 2 and the cathode 3.

In the example shown in figure 1, the cation selective membrane 6 is arranged on the side of the anode 2, while the anion selective membrane 5 is arranged on the side of the cathode 3. The anion selective membrane 5 will only remove anions ll from the allow water to be purified to pass through. The cation selective membrane 6, on the other hand, will only allow cations 12 from the water to be purified to pass through.

Under the influence of the electric field, anions 11 in the water to be purified will migrate towards the cathode 3 and cations 12 towards the anode 2.

Only the anions 11 are allowed to pass through the anion-selective membrane 5 and only the cations 12 can migrate through the Kcation-selective membrane 5. The cations 12 and anions 11 are then separately collected and retained in the associated porous xole electrode 7. A water flow that

E becomes increasingly poor in ions {it = diluate) and a residual current becomes increasingly rich in ions {the concentrate}. The residual current is trapped at the coreous electrodes 7. Purify the supplied Le water

S is thus stripped of ions,

The electrodialysis system 1 is preferably provided with a residual pipe 14 for draining the residual water

Considering the concentrated salt ions, are preferred

LE both the discharge pipe 9 and the residual pipe 14 are provided with a closable valve for closing off associated

Pipe,

It is also possible that the discharge pipe 9% and the residual pipe 14 are the same pipe. In this case, this pipe is provided with a closure such that it can be closed,

The residual flow of residual water can be removed from the electrodialysis system 1 by exchanging the anode 2 and the cathode 3. The electric field is then reversed. As a result, the cations 12 in the porous electrode 7 will migrate back through the cation-selective membrane 6 in the direction of the anion 2. The anions 11 in the porous electrode 7 will also migrate back through the anion-selective membrane 5 in the direction of the cathode. 3. Both the cations 12 and the anions 11 are then trapped between the cation-selective membrane 6 and the anion-selective membrane 5. In other words, the residual current or residual water has moved from the porous electrodes 7 to the space between the

_ BE2022/5604 ; both selective membranes. From here, the residual flow or water can then be drained or removed via the residual pipe lé.

An advantage of this is that contamination of the selective membranes is avoided to a very large extent.

By reversing the voltage across the electrodes (anode and cathode) and exchanging the electric field, the direction of flow of the diluate and concentrate is also reversed,

In this way, the direction of ion transport is changed, and therefore cok transport of pollutants, which cleans the selective membranes.

In an alternative embodiment, as shown in figure 2, the electrodialysis system 1 is provided with two electrodialysis cells arranged between the porous carbon electrodes 7, in another alternative embodiment, as shown in figure 3, the electrodialysis system 1 is provided with four electrodialysis cells 4 arranged successively between the solid carbon electrodes 7,

In a preferred embodiment, a pump 15 is provided in the supply line 8 for pumping the water to be purified and a filter 16 for filtering undissolved particles from the water to be purified, as shown in Figure 4.

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Preferably the selective anion membranes 5 and/or the selective cation membranes 5 are constructed with a thickness of 50-200 micrometers.

In addition, it is also possible to use selective anion membranes 5 and/or the selective cation membranes 6 that are coated. These coated selective anion membranes 5 and/or the selective cation membranes

G preferably have a thickness of 20 micrometers,

The present invention is by no means limited to the embodiments described by way of example and shown in the figures, but an electrodialysis system according to the invention can be realized in all kinds of shapes and dimensions without departing from the scope of the invention.

Claims (9)

Conclusions. 1.- Electrodialysis system {1} for removing salt ions from water, characterized in that the electrodialysis system (1) is provided with at least one anode {2}, at least one cathode (3) and at least one electrodialysis cell {4}, which is of an anion selective membrane {5} and a cation selective membrane 19 {6}, wherein at least one electrodialysis cell {4} is arranged between the anode {2} and the cathode (3) and wherein the electrodialysis system (1) is provided with at least one porous carbon electrode (7) between the anode {2} and the electrodialysis cell {4} and at least one porous carbon electrode (7) between the cathode {3} and the electrodialysis cell {4}. 2.7 Electrodialysis system according to claim 1, characterized in that the electrodialysis system (1) is provided with 2 or more electrodialysis cells {4} that are arranged between the porous carbon electrodes {7}. Electrodialysis system according to claim 1 or 2, characterized in that the electrodialysis system {1} is provided with 4 or more electrodialysis cells (4) which are arranged successively between the porous carbon electrodes (7). Electrodialysis system according to one of the preceding claims, characterized in that the selective anlon membranes (5) and/or the selective cation membranes (8) have a thickness of 50-200 micrometers. Electrodialysis system according to any one of the preceding claims 1 to 3, characterized in that the selective anion membranes {5} and/or the selective cation membranes (6) are coated, Electrodialysis system according to claim 5, characterized in that the coated selective anion membranes (5) and/or the selective cation membranes (6) have a thickness of 20 micrometers, 7. Electrodialysis system according to one of the preceding claims, characterized in that the electrodialysis system {1} contains a residual line (14) for discharging the residual water containing the concentrated salt ions. Electrodialysis system according to any of the preceding claims, characterized in that the electrodialysis system {1} contains an energy supply (10) that applies an electric field between the anode (Z) and the cathode {3}. 9. Electrodialysis system according to any of the preceding claims, characterized in that the electrodialysis system (1) is provided with a sand supply line {8} for supplying the water to be purified to the electrodialysis cell (4) and a discharge line {3}; for draining the purified water from the electrodialysis system (13. 1G. - Electrodialysis system according to claim 9, characterized in that a filter (16) is arranged in the supply line (8) for filtering undissolved particles from the water to be purified.