SU976619A1 - Electrolytic cell - Google Patents

Description

2 "Electrolyzer by clause, plummer, which is due to the fact that the electrode from the bundles of wire is embedded in the nozzle at 0, 7 its height along the flow.

Zo Electrolyzer for POT, about tl ich and Yu y and with the fact that the cross section of the conductor e electrode bundles in 2-5 times the gap (Shaet section of elements

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The invention relates to electrochemical apparatus used for the treatment of wastewater from mechanical impurities and oil products.

A known cell consisting of a housing, nozzles in the form of a grain, and electrodes G1

However, the magnitude of the current density on the surface of the conductive nozzle grains, which is 1/3 of the total volume of the nozzle, is of little importance due to the high resistance at the contact points of the grain-grain, the grain of the electrode plate. In addition, the grained layer of the nozzle supports the grid, which is often clogged and creates additional resistance to fluid flow, which also impairs the degree of purification of contaminated fluid

Regeneration of the nozzle in such an electrolyzer is costly, since it must be carried out by an intensive flow.

The aim of the invention is to increase the degree of purification of contaminated fluid and the reliability of the operation of the electrolyzer.

The goal is achieved by the fact that, in an electric roller), which includes a nozzle body and electrodes, the nozzle is made as elements of an elastic non-conductive material fixed with upper ends on a non-conductive holder mounted in the upper part of the body one of the electrodes is made in the form of wire beams, which are evenly distributed over the cross section of the housing of the nozzle, and the second electrode is connected to the housing and is installed movable along the axis of the housing in the nozzle “An electra from wire bundles can be buried in the nozzle on its

2

the heights in the course of the flow, and the wire cross section in the pumahs of the electrode 2-5 times higher than the cross section of the elements

 about

The drawing shows the proposed

electrolyzer general view

The cell includes a housing 1 with a nozzle 2 supplying the source liquid j a nozzle 3 discharging cleaned Idkos I5 a nozzle k supplying liquids for regenerating the nozzle, a nozzle S for removing soils, bushing 6 " 7s holder 8 of non-conductive material, nozzle elements 9 movable sealing electrode 10 "

The electrolyzer is operated as follows: Before starting, the sealing electrode 10 digs in the nozzle 9 and connects the current. Contaminated liquid is supplied through the nozzle 2. The cleaning of the liquid takes place in the nozzle E as due to the interaction of the liquid with the nozzle and due to electrochemical processes. The purified liquid is removed through the nozzle 3,

During regeneration, the current source is opychayte electrode compaction 10 vyd1, chgayat from the porous medium nozzle 9 o The washed liquid is fed into the hydroformed enlarged nozzle through the 4-pipe 4. and the polluted liquid is withdrawn through the nozzle 5

They test a model of an electrolyzer with a nozzle containing a cylindrical (iron body (NW 200 mm), FU). A losing layer of nylon fibers (d 1 m., .., 800 mm height), inside which is placed an electrode made of chelated wire (NW 3 mi) “Strain1; e on the electrodes support 60 Bj filtration speed 30 n / h. Purification is made of artificial water containing clay and organic matter. Concentration of agitated substances in the filtrate at a different depth of immersion of the electrode into the porous medium is given in tab., 1 ..

The greatest degree of purification is achieved when the electrodes from the ZOO-BOO mmo are buried. When the depth is less than 300 mm, the area of contact of the electrodes with the liquid is small and it forms little metal hydroxides necessary for cleaning. With a depth of more than 700 mm, the thickness of the nozzle layer below the electrodes decreases, and contamination of the filtrate is possible.

The effect of the cross section of the wire of the electrode beams on the degree of cleaning is given in Table 2: The device was tested with an electrode immersion depth of 500 mm,

The wire cross section is 2-5 times larger than the cross section of the Nozzle Elements is optimal because it creates

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em is the most favorable ratio of pores formed by the elements of the nozzle and wire bundles of the electrode,

5 The performance characteristics of the proposed and known designs are given in the display board. In this case, the proposed design of the electrode is made of wire with a diameter of 2 mm, and

10, a model of a known electrolyzer is a glass cylinder in which layers of coal particles and glass balls 5 mm in diameter 1 mm were placed on the grid-electrode with cells O, 5O, 5 mm.

Thus, the proposed design of an electrolytic cell with a nozzle allows to increase the heat capacity of the nozzle by 40-50, and the absence of a mesh supporting electrode nozzle increases the reliability of the electrolyzer. Moreover, the use of an electrode in the electrolyzer reduces the cost of regenerating the nozzle ,

I Table 1

table 2

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Claims (3)

1. ELECTROLYZER for cleaning contaminated liquids, comprising a housing, a nozzle and electrodes, characterized in that, in order to increase the degree of cleaning and reliability in operation, the nozzle is made in the form of elements of a non-conductive material, fixed with their upper ends to a conductive holder installed in the upper part of the housing, one of the electrodes is made in the form of bundles of wire that are evenly distributed over the cross section of the housing in the nozzle, and the second electrode is connected to the housing and mounted movable along the axis of the housing in asadke. ω phial with m o 0) with 2 ,. The electrolytic cell according to claim 1, wherein the electrode of the wire bundles is buried in the stack at O, 3 ~ O, 7 of its height along the flow. 3 "The electrolyzer no nJ, with the fact that the cross section of the wire and the electrode beams is 2-5 times larger than the cross section of the collisions.