RU200864U1 - Biological wastewater treatment device - Google Patents

Abstract

The proposed technical solution refers to continuous devices for the treatment of industrial, household and agricultural wastewater and can be used in local treatment systems of chemical, food and related industries, urban wastewater treatment plants, in agriculture. The technical result of the proposed utility model is increasing the productivity of the apparatus. The technical result is achieved by the fact that the biological wastewater treatment device, consisting of a reservoir with inlet and outlet pipes of the source and purified water, an electrode system installed in the lower part of the reservoir and consisting of vertical anodes and cathodes, each pair of which has the form cylinders and fixed on the side surfaces of the ring separating them, made of a dielectric material, while the height of each cylinder is determined as a proportion: where h1, h2 are the height of adjacent cylindrical anodes, m; ra1, ra2 are the radii of adjacent th cylindrical anodes, m; δ is the annular gap between the adjacent anode and cathode, m; and the height of the ring above and below is greater than the height of the anode and cathode by the value Δh equal to the annular gap: Δh = δ.

Description

The proposed technical solution refers to continuous devices for the treatment of industrial, household and agricultural wastewater and can be used in local treatment systems of chemical, food and related industries, urban wastewater treatment plants, in agriculture.

The known design of a cylindrical electroflotation apparatus with a horizontally located bottom and a mesh cathode, close in area to the bottom of the apparatus, and a vertical movable rod anode, installed asymmetrically with the apparatus above the mesh cathode. The movable anode allows you to change the distance between the electrodes and thereby regulate the current density (Current state and prospects for the use of electrolytic flotation of substances. Part 2 / AA Mamakov. - Chisinau: "Shtiintsa", 1975. - S. 68-69).

The reasons that impede the achievement of a given technical result include the extreme uneven distribution of electrolytic gas bubbles over the section of the apparatus, which leads to the need to increase the residence time of the treated liquid. The use of a grid cathode leads to the deposition of large flocks of coagulated particles on it, especially at the periphery, where electrolysis with the release of electrolytic gas bubbles is the smallest. This requires a periodic shutdown of the apparatus and flushing of the cathode grid, which increases the downtime in repair and, accordingly, reduces the productivity of the apparatus.

A device for biological wastewater treatment is known, consisting of a reservoir with inlet and outlet pipes of source and purified water, an electrode system installed in the lower part of the reservoir, consisting of an anode and a cathode, made in the form of a mesh of metal wire fixed on the side walls of vertically mounted plates , while the diameter of the wire of the anode mesh is 2-5 times greater than the diameter of the wire of the cathode mesh, and a grating is installed above the anode, on which a nozzle for attaching microorganisms is located (Patent for a useful model of the Russian Federation No. 86945, publ. 20.09.2009).

The reasons that impede the achievement of the specified technical result include the uneven supply of electrolysis gases to the liquid and the unequal current of the plates with the cylindrical shape of the reservoir, which leads to uneven processing of the liquid with electrolysis gases and a decrease in the productivity of the apparatus.

The closest technical solution in terms of the totality of features to the claimed device and taken as a prototype is a biological wastewater treatment device, consisting of a reservoir with inlet and outlet pipes of source and purified water, an electrode system installed in the lower part of the reservoir and consisting of vertical anodes and cathodes , each pair of which has the shape of cylinders and is fixed on the side surfaces of the ring separating them, made of a dielectric material, while the height of each cylinder is determined as a proportion:

where h ₁ , h ₂ - respectively, the height of adjacent cylindrical anodes having radii r _a1 , r _a2 , m;

δ - annular gap between adjacent anode and cathode, m (Patent for a useful model of the Russian Federation No. 129500, publ. 27.06.2013).

The reasons that impede the achievement of the specified technical result include current leakage from above and below between the anodes and cathodes, provoking dissolution of the anodes and, as a consequence, reducing their service life, increasing the downtime in repair and, accordingly, reducing the productivity of the apparatus.

The technical result of the proposed utility model is to increase the productivity of the apparatus.

The set technical result is achieved by the fact that a biological wastewater treatment device, consisting of a reservoir with inlet and outlet pipes of source and purified water, an electrode system installed in the lower part of the reservoir and consisting of vertical anodes and cathodes, each pair of which has the shape of cylinders and is fixed on the side surfaces of the ring separating them, made of dielectric material, while the height of each cylinder is determined as a proportion:

where h ₁ , h ₂ - the height of adjacent cylindrical anodes, m;

r _a1 , r _a2 — radii of adjacent cylindrical anodes, m;

δ — annular gap between adjacent anode and cathode, m;

moreover, the height of the ring from above and from below is greater than the height of the anode and cathode by the value Δh, equal to the annular gap:

Δh = δ. (2)

A separating ring made of a dielectric material with a height above and below the height of the adjacent anode and cathode by size δ, that is, it corresponds to formula (2), prevents current leakage from the cathode to the anode, and, accordingly, the dissolution of the anode ends, increases its service life , reduces downtime for repairs and, accordingly, increases the productivity of the device.

When Δh is less than δ, the electrical resistance decreases and the current from the end of the anode to the cathode increases, and, accordingly, additional dissolution of the anode. This reduces the life of the main operation of the electrode system, increases the repair time of the system, including by replacing and cleaning the electrodes from deposits associated with electrolysis products and dissolution of anode platinum, which reduces the productivity of the apparatus.

FIG. 1 shows a general view of the device, FIG. 2 - view A in FIG. 1.

The device consists of a cylindrical tank 1 with an inlet pipe 2 of source water and an outlet pipe 3 of purified water, a cover 4 with a pipe 5 for removing electrolysis gases into the ventilation system, a bottom 6 with a pipe 7 for removing sludge, an electrode system installed in the lower part of the tank 1 and consisting of vertically installed anodes 8 and cathodes 9, made in the form of cylinders and fixed in pairs on the rings 10 separating them, made of dielectric material, the height above and below is greater than the height of adjacent anode 8 and cathode 9 by the value Δh = corresponding to expression (2) δ, where Δh is the height difference between the spacer ring 10 and adjacent anode 8 and cathode 9 from above and below, m; δ - annular gap between adjacent anode 8 and cathode 9, m.

The anodes 8 are connected to the positive pole 11 of the direct current source, and the cathodes 9 to its negative pole 12. The reservoir is grounded 13.

The gaps between adjacent anodes 8 and cathodes 9 are the same and equal to δ, and the height of the cylinders h ₁ and h ₂ , the radii r _a1 and r _{a2 of the} anodes 8 and the gap δ between the adjacent anodes 8 and cathodes 9 are determined by the relation (1):

The biological wastewater treatment device operates as follows.

Potential is supplied to the anodes 8 and cathodes 9 from a direct current source. The liquid to be cleaned is fed to the reservoir 1 through the branch pipe 2. In the gap δ between adjacent anodes 8 and cathodes 9, a current flows through the water to be purified as a conductor of the second kind. Oxygen bubbles are released on the surface of the anodes 8, and hydrogen bubbles on the surface of the cathodes 9. Due to the fact that the dividing rings 10, made of a dielectric material, on which the anodes 8 and cathodes 9 are fixed in pairs, while the height of the dividing ring 10 from above and below is greater than the height of the adjacent anode 8 and cathode 9 by the value Δh equal to the value of the annular gap δ, that is, it corresponds to formula (2), then current leakage from the cathode to the anode does not occur, and, accordingly, the ends of the anode do not dissolve. Oxygen bubbles interact with suspended particles of activated sludge and microorganisms in the treated water, which leads to biological oxidation of organic matter in the treated water. In addition, bubbles of hydrogen and oxygen, rising upward, colliding with suspended particles, carry them out during flotation into foam. The spent mixture of electrolysis gases is discharged through the nozzle 5 into the ventilation system, the large particles formed as a result of coagulation go down to the bottom 6 of the tank 1 and are discharged through the nozzle 7 into the sludge collector. Purified water is discharged from reservoir 1 through branch pipe 3.

Example 1 (prototype device design).

According to table 1 of the prototype (Patent for utility model of the Russian Federation No. 129500, publ. 06/27/2013), we have the following values of the parameters of the electroflotator design: the radius of the cylindrical body of the apparatus R = 250 mm; the gap between the adjacent anode and cathode δ = 10 mm; the thickness of the plates of the anode and cathode forming the cylinders, ε = 5 mm; the number of anode ends N = 14; average current density j _a = 94A / m ² ; the maximum permissible current density (when the anodes practically do not dissolve) j _pr = 100A / m ² .

Let us consider the rate of dissolution of the ends of the anode plates in a device taken as a prototype, when the distance between the anode and the cathode is equal to the thickness of the dielectric ring equal to 5 mm. This thickness is 2 times less than the gap between the adjacent anode and cathode, equal to δ = 10 mm. Accordingly, the current density at the ends will be 2 times greater, that is, j _a = 188A / m ² , and exceed the maximum permissible value by 1.88 times. In this case, the upper part - the ends of the anodes dissolve quickly, and the dissolution products enter the solution and onto the walls of the anodes and cathodes, increasing their electrical resistance and reducing the productivity of the liquid to be cleaned.

The total surface area of all ends will be:

The total current at the ends of the anodes will be:

For anode plates made of ferrosilide, the dissolution rate is ω _p = 0.5 kg / (A year) (Basic materials of anode ground electrodes. Comparative analysis and scope / GN Zorina, VV Pershukov, N. M. Katolikova // Sfera. Oil and Gas. - 2017. - No. 5 (61). - P. 70-72).

Then, for a year of operation of the electroflotator, the dissolution of the anodes will be:

Example 2 (claimed device design)

In the proposed design of an electroflotator (with parameters similar to the prototype), the average current density above and below between the anodes and cathodes is less than the maximum allowable and is j _a = 94A / m ² due to the fact that the height of the dielectric ring from above and below is greater than the height of adjacent anode and cathode by size δ, that is, it corresponds to formula (2).

Thus, with the difference in the heights Δh of the rings and the anodes and cathodes fixed on them from above and below, corresponding to condition (2), it is ensured by increasing the service life of the anodes and reducing the downtime for repairs, increasing the productivity of the apparatus.

Claims (7)

A biological wastewater treatment device, consisting of a reservoir with inlet and outlet pipes of source and purified water, an electrode system installed in the lower part of the reservoir and consisting of vertical anodes and cathodes, each pair of which has the shape of cylinders and is fixed on the side surfaces of the ring separating them, made of dielectric material, while the height of each cylinder is determined as a proportion:

where h ₁ , h ₂ - the height of adjacent cylindrical anodes, m; r _a1 , r _a2 — radii of adjacent cylindrical anodes, m; δ — annular gap between adjacent anode and cathode, m; characterized in that the height of the ring above and below is greater than the height of the anode and cathode by the value Δh equal to the annular gap: Δh = δ.

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