SU1286234A1 - Electrodialyzer - Google Patents

Abstract

The invention relates to the field of demineralization of water, allows to increase the depth of desalination and provides work on solutions with low salinity. The electrodialyzer contains two coaxially arranged cylindrical electrodes, spirally interposed non-selective membranes, forming concentration and desalination chambers, devices for inlet and outlet solutions, each of the membranes provided with vertical strips of non-conductive material along the entire membrane height. The length of each strip of non-conductive membrane material does not exceed the length of one coil. 1 hp ff, 3 ill., 1 tab.

Description

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The invention relates to the demineralization of water and can be used in electrodialyzers with ion-selective membranes intended for the production of deeply desalinated water.

The purpose of the invention is to create an electrodialyzer design that allows to increase the allowable depth of desalination and ensures work on solutions with low salinity.

FIG. 1 shows an electrodialyzer (section in FIG. 2); in fig. 2 - a spatial image of the electrodialyzer; on fig.Z - membrane.

The electrodialyzer contains two coaxially arranged cylindrical electrodes — the inner 1 and outer 2, between which the ion-selective membranes 3 and 4 are arranged in a spiral, forming desalination and concentration chambers. The walls of the chambers are formed by sections made of membrane material alternating with vertical strips 5 made of IZ material, the resistivity of which is not less than the solution resistance of the desired desalting depth, for example, of polyethylene. The length of sections made of membrane material does not exceed the length of one turn. The width of the dividing strips 5 is not less than the width of the membrane sections. If the strips 5 are made of polyethylene, then they can be connected to the membrane sections by heating to.

The input device for the solutions consists of supply manifolds b and 7, desalination chamber 8 and concentration 9. Discharge manifolds 10 and 11, respectively, desalination and concentration chambers, constitute an output device. Fittings 12 and 13 are used to power the anode chamber, shtutsera 14 and 15 - to power the cathode chamber, shtutsera 16-19 - to power the collectors.

The chambers are sealed at the ends with sealing gaskets 20 and 21 and with caps 22 and 23.

Electrodialyzer works as follows.

The feed solution supplied to the inlet manifold 6 through the nozzle 16 enters the desalting chamber 8 and moves to the periphery. The ions of the salts contained in the solution under the action of the electric field are migrated through the ion-selective membranes 3 and 4 into the concentration chamber 9. The desalinated water is discharged through the collector 10 and the fitting 18. The concentration chamber 9 is rinsed with a solution coming through the mixer 17 and the collector 7. The brine is discharged by means of the collector 1 and the spout 19.

High fluid flow rates, mass flow intensification by macrovortexes and design features (spiral

the form) allows the desalting process to be carried out at elevated current densities compared with backfilled electrodialyzer. The energy expended goes into performing useful work — the transfer of salt-forming ions from the desalting chamber to the concentration chamber, thus increasing the desalting depth compared to the known spiral electrodialyzer.

The results of tests on the demineralization of NaCl solution (500 mg / l), carried out in electrodialyzers with the same area of membranes and intermembrane distance, are presented in the table.

Thus, the use of this dialyzer allows to increase the depth of desalination, to ensure the possibility of the operation of the spiral electrodialyzer with solutions of low salinity and reduces the weight and size parameters, energy consumption and increases productivity compared with flat frame devices with backfilling.

Claims (2)

1. Electrodialyzer containing two coaxially arranged cylindrical electrodes, spirally spaced ion-selective membranes between them, forming concentration and desalting chambers, devices for inlet and outlet of solutions, characterized in that, in order to increase the desalination depth and enable work with low salinity solutions , each of the membranes is provided with vertical strips of non-conducting material over the entire height of the membrane. 2. The electrodialysis apparatus according to claim I, characterized in that. the length of each strip of non-conductive membrane material does not exceed the length of one coil. Phi. 2 7277 7 18 13 21 FIG. J