SU1003869A1 - Method of controlling electric dialysis unit - Google Patents

Description

(54) METHOD OF CONTROL OF ELECTUDIAL INSTALLATION

one

The invention relates to methods for the electro-chemical treatment of liquids by electrodialysis using non-selective membranes, in particular, to methods for controlling electrodialysis units of the circulating type.

Closest to the present invention is a method of controlling an electrodialing unit of the circulation type by acting on the flow rate of desalinated liquid and supplying voltage to the electrodializer electrodes 1).

At the electrodialysis electrodes, the electrode is kept constant throughout the entire desalination cycle of the liquid portion and is chosen so that the current density by the end of the desalination cycle does not exceed a critical value. As the fluid circulating through the electrodialysis unit (distillate) desalinates, the current density in the electrolyzer decreases, respectively, with an increase in the electrical resistance of the β-dilate. When desalination of a liquid and a decrease in the current density to a predetermined limit is triggered |

the current relay and its contacts switch the automatic valves installed. On a single pipeline, sent a desalinated portion of oil to the consumer. However, the current density in the electrodialyzer c. most of the desalination cycle is less than acceptable. This circumstance causes the idleness to increase the effective area of ion-selective membranes when creating electrodialysis plants, i.e. to increase the size and weight of the electrodializer, to complicate its design.

The purpose of the invention is to stabilize the current density over the course of most of the CCL9 desalination.

This goal is achieved by the fact that according to the method of controlling a circulating-type installation by affecting the flow rate of desalinated liquid and the flow applied to the electrodializer electrodes, the flow rate of the desalinated liquid is performed depending on the limiting concentrations of the single fluid, and strained to the electrodes served in steps.

The drawing shows a functional block diagram of a device that implements a thin method of controlling an electrodialysis unit.

The device contains a control unit 1, made in the form of mutually related dates, 2, and a concentrator 3, automatic valves 4 and 5, a transformer 6, a transmitter 7, a voltage switch 8. The concentrator has a signal output of the upper concentration of the diluate and a signal output of the lower value of the concentration of the diluate. Rectifier 7 is connected to its own output. to electrodes 9 of electrodialization 10, between which are located a turn of dilution chambers 11 and chambers 12 of concentrated private OBOB separated by ion-selective membranes.

A single circuit by electrodialysis circulator consists of a diluate. piping 13, dilution tank 14, pump 15 and pipeline 16 to discharge the desalinated portion of liquid. To the electrodialyzer 10, the source liquid supply pipeline 17 is connected to the concentration chambers 12 and to the flushing of the electrode chambers and the liquid discharge pipeline 18 from these chambers. The method is carried out as follows. A part of the initial fluid enters through the conduit 17 to flush the concentration chambers 12 and electrode chambers, and then is discharged through the conduit 18. Another portion of the initial fluid enters the diatom tank 14, after filling up to the upper level, the pump 15 is turned on and the liquid is lined via the pipeline 13, through the sensor 2, the open automatic valve 5 and the diluate chambers 11 of the electrodialysis apparatus 10. Through the outer terminals of the secondary winding of the transformer 6, the switch 8 and the rectifier 7 to the electrodes 9 are electrodialysated The voltage is applied to the DC voltage, under the influence of KOTOi-jro, the portion of the source liquid circulating through the diluent of chamber 11 is gradually desalinated. And the initial stage of desalination on the electrodes 9 is maintained at a constant value of the voltage, and the density decreases as the desalination of the liquid and at a concentration of diluate corresponding to the setting in the concentration meter 3 of the signal output of the upper concentration value reaches the limiting value of the current density. At this PB signal of sensor 2, the signal output of the concentrator 3 is commanded to the voltage switch 8. The switch 8 connects the rectifier 7 to the intermediate, secondary terminal of the transformer 6. As a result, at the final desalination stage at electrodes -9, the lower value of the constant voltage value holds, and the current density decreases as the freshening of the liquid, not the revenue, reaches the limit values. When the concentration of a portion of the liquid is lowered to a pre-set value by a signal from datka 2 in concentrator 3, a lower concentration signal output is triggered and an automatic valve 4 and 5 are commanded to operate. Valve 5 closes and valve 4 opens and Portion of desalinated liquid is directed through pipe 16 on reset to the consumer. After a portion of the fluid from the diluate tank 14 has been drained, it is filled again with a new portion of the initial fluid, as a result of which, according to the signals from sensor 2 and concentrator 3, automatic valves 4 and 5 and voltage switch 8 take the initial position and repeat in the order described in the next cycle desalination

Claims (1)

Invention Formula . A method of controlling an electroscopic circulating type installation by affecting the flow rate of desalinated liquid and applying voltage to the electrodializer electrodes, characterized in that, in order to stabilize the current density values for a large part of the desalination cycle, the desalination flow of desalinated water has been applied to depending on the limiting values of the diluate concentrate, and the voltage on the electrodes is supplied in steps. Sources of information accepted in BHHMaime during the examination 1. Bulletin of the Sociely of Sea Water Science, 22, N 1, p. 26-31, 1968.