SU1564120A1 - Method of dehydration of thin suspensions - Google Patents

Abstract

The invention relates to dewatering methods and can be used in the dewatering and thickening of structured suspensions, as well as in the treatment of waste water from finely dispersed mechanical impurities. The aim of the invention is to increase the rate of dehydration of thin suspensions. To this end, in the method of dewatering thin suspensions, which involves feeding the initial suspension to the zones of precipitation electrodes, dewatering the suspension due to liquid flowing through porous electrochemically active membranes to the areas of auxiliary electrodes, the output of the condensed product and the clarified liquid, the suspension is treated with electro-osmotic dehydration and treated with liquid glass during flow 15-75 g / t solid phase. 2 tab.

Description

The invention relates to dewatering methods and can be used in the dehydration and thickening of structured suspensions, as well as in wastewater treatment from finely dispersed mechanical impurities,

The purpose of the invention is to increase the rate of dehydration of thin suspensions.

Example. Liquid glass was added to a suspension of thin manganese pshams with a solid content of 4.0% at a flow rate of 70 g / t of solid phase and agitation in agitation for 2 minutes. The suspension treated with liquid glass was fed through a charging nozzle to the zones of collecting electrodes of the electroosmotic apparatus. The clarified liquid was removed through the drain pipe, and the condensed product was discharged through the sand pipe.

The result was a clarified liquid without mechanical impurities and a condensed product with a solids content of 22.3%.

In tab. Table 1 shows the results of comparative tests of the known and proposed methods of electroosmotic dehydration of thin manganese slimes of the Bogdanov concentrator.

From the data table. 1 shows that as a result of pretreatment of manganese sludge with liquid glass at a flow rate of 15.0-75 g / t of the solid phase, the rate of electric dehydration increases by 1.5-2.0%, and the specific load on the initial feed increases by 2.5-3.0%.

During the processing of the initial suspension with liquid glass, the electro-Vietname electric potential increases.

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This leads to an increase in the electroosmosis coefficient of the liquid phase and, consequently, the speed of electrical disinfusion.

In tab. Figure 2 shows the values of the electroosmosis coefficient and the rate of dehydration at different flow rates of liquid glass.

From the data table. As can be seen in Figure 2, the growth of liquid glass going to the treatment of the suspension before electrical delagging, equal to 15.0-75 g / t, is optimal. At this flow, the maximum coefficient of electroosmosis is 3.55-3.6-107 m / A and the dehydration rate of 2.64 is 68.10 105 m3 / s. An increase in the consumption of living glass above 75 g / t of solid f.lea leads to a decrease in the coefficient of electroosmosis and the rate of dehydration.

Claims (1)

Invention Formula A method of dewatering thin suspensions, which includes processing the initial suspension in an electroosmotic apparatus using porous electrochemically active membranes, characterized in that, in order to increase the speed of the process, the initial thin suspension is mixed with liquid glass in an amount of 15.0-75.0 g / t before processing solid phase. Table 1 Famous Offered 20-22 96.5-U-3 3.22 20-22 98.3-1C 33.31 Table 2 Coefficient electroosmosis, -10 t, m / A-s 3.08 3.15 3.55 3.56 3.60 3.60 3.00 1.25 0.32 0.08 Speed dehydration V105, m3 / s 2.29 2.34 2.64 2.65 2.68 2.68 2.24 0.93 0.24 0.06