SU1733390A1 - Sewage treatment unit - Google Patents

Abstract

This invention relates to a technique for treating waste water from heavy metal ions of emulsified impurities, suspended solids and other impurities and can be used to clarify recycled water and effluent. The purpose of the invention is to increase the cleaning efficiency and productivity of the installation. The wastewater treatment plant contains an electrode chamber with soluble electrodes, distribution chambers, perforated in the side section at different heights, interconnected with the flotation chamber and inclined and vertical partitions forming sludge collectors, thin-layer sedimentation tanks, a flocculation chamber and a sewage distributor. In the upper part of the distribution chamber, a flotation sludge collector is installed, which is withdrawn to the upper part of the sludge trap and equipped with a flexible corrugated discharge hose of the flotshale and gas. Filtration chambers with a floating filtering load and filtrate collectors are installed to the side walls of the photocell, between which a collection of sludge is placed. 2 tab., 4 Il. THX

Description

The invention relates to the purification of wastewaters of enterprises of the mechanical engineering industry and state agro-industrial industry from heavy metal ions of emulsified impurities, suspended solids and other impurities, and can also be used in the chemical industry to clarify recycled water and effluent.

A known installation for the treatment of waste water from heavy metal ions, which consists of an electrode chamber, a flocculation chamber, a flotation chamber of inclined partitions, a filtration chamber.

The disadvantage of this installation design is low productivity, which is associated with reduced cleaning efficiency, since destruction of flotation sludge and contaminants occurs.

gas bubbles as the treated waste liquid moves through the gas-containing layer.

The aim of the invention is to increase the cleaning efficiency and productivity of the installation.

The goal is achieved by the fact that in a flotokamer consisting of a sewage distributor, thin lagoons, a flocculation chamber, a sludge collector, inclined distribution chambers connected to the sludge collector installed in its upper part are provided with flexible discharge hoses for sludge and gas, and among themselves and the walls of the flotation chamber, the distribution chambers are connected by vertical and inclined partitions,

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moreover, the inclined partitions with the side walls of the flotocameras form sludge-collecting agents, and with the bottom - thin-layer septic tanks and a flocculating chamber. in the upper part of which there is a waste water distributor, which connects the distribution chambers with the help of vertical partitions. This makes it possible to increase the productivity of the installation by increasing the efficiency of clarification.

At the same time, the perforations in the side wall of the distribution chambers are unevenly located along its height: in the initial part they are located at a height of 0.7-0.9 from its total height, and at its end - by 0.1-0.3, with thin-layer modules They are equipped in the upper part with sludge-removal pipes connected to the sludge outlet to the collector. This makes it possible to increase the productivity of the plant by continuously removing the sludge.

Figure 1 presents the installation, General view; figure 2 - section aa in figure 1; on fig.Z - section B-B in figure 1; Fig. 4 shows the placement of perforation holes in the side wall of the distribution chamber.

The installation consists of a housing 1 with an electrode chamber 2, into which electrodes 3 are mounted, connected to an inclined distribution chamber 4, passing through the flotation chamber 8. The distribution chamber 4, through inclined partitions 14, is connected to the flotation chamber 8, forming mono-stores 16, thin-layer settling tanks modules 5 and chamber 6 of flocculation, in the upper part of which a wastewater dispenser 7 is installed connecting the distribution chambers 4 by means of vertical partitions 15. In the upper part of the distribution chamber 4 there is The flotation sludge collector 21 to which the sludge discharge pipes 30 are connected. Placed in the upper part of the sludge module 5. The sludge collector 21 comes out in the upper part of the sludge collector 11 and is provided with a corrugated hose 22 with lifting and lowering units 23 and a holding cable 24. The side wall of the distribution chamber 4 is perforated with holes 13.

The flotation chamber 8 is connected to the filtration chamber 9. in which a floating load 19 is placed. Through the perforation 25 of the side wall, then through the filtrate collection pipe 20 with filtrate collectors 10, between which the sludge collector 11 is placed.

In the upper part of the flotocamera 8 there are slime-retaining partitions.

17 and water distribution partitions 18.

On the housing 1 there are nozzles for supplying effluent 12. discharge of sludge 26, supply of wash water 27, filtrate 28, discharge of flotation sludge 29.

The installation works as follows.

Sewage water through the nozzle 12 is supplied to the electrode chamber 2, in which, under the action of direct current, the electrodes 3 generate a gas phase and a coagulant. Direct current-destroyed contaminants coagulate, float and enter the distribution chamber 4 passing through the flotation chamber 8 with an inclination in the direction of the flotation sludge collector 21 placed in the sludge collector 11. At the same time, part of the flotation sludge releases an upper part distribution chambers 4, where, due to the near-wall effect, the speed of the fluid is dramatically reduced. Moreover, large gas bubbles that do not participate in the flotation process are much faster transported to the foam layer, do not destroy coagulated impurities and improve the movement of the sludge towards the collecting manifold 21, in which it gradually accumulates and compresses, and the corrugated hose 22 with lifting units 23 and lowering and holding the cable 24, allows to fix the time of compaction and discharge of the sludge into the sludge trap 11. The process of removing the sludge is performed periodically by lowering the corrugated hose 22 under the pipe water level of the flotocamera 8, providing automatic flushing of the flotation tank and distribution chamber. This prevents accumulation of contaminants and increases flotation efficiency and plant capacity (see Table 1). Placing the flotation sludge collector 21 in the upper part of the sludge collector 11 also prevents it from precipitating with precipitating substances when the flotation sludge is destroyed, which also increases the cleaning efficiency due to more favorable sludge and gas discharge conditions.

The perforation 13 is placed in the side wall of the distribution chamber 4 so that in the initial part of the hole is at a height of 0.7-0.9 of the total height, and in its end at a height of 0.1-0.3. These hole placement sizes are optimal and allow for increased flotation efficiency and plant capacity (see Table 2 of the distribution chamber test).

Partially clarified wastewater in the distribution chamber 4, in which there are no large gas bubbles and coagulated impurities, enters the thin-layer settling modules 5 formed by the inclined baffles 14 and the bottom of the flotation chamber 8. The velocity of the fluid flow decreases and part of the sludge gradually accumulates in the settling unit . However, by placing the slop module 5 with a slope in the longitudinal direction, which coincides with the slope of the distribution chamber 4, the flotshaft is continuously transported towards the flotation slurry pipes 30 connected to the collector 21. This ensures efficient removal of the sludge and flushing of the settling modules, which also improves installation performance , in comparison with the known solutions (see Table 1). The remaining fine particles of coagulated impurities, as well as finely dispersed gas bubbles enter the flocculation chamber 6, in which the rate decreases and the precipitated deposit from the lower part of the distribution chamber 4 forms a suspended layer. This makes it possible to intensify the process of clarification and increase the size of spliced aggregates. The coagulated fine particles of impurities and flotation units through the wastewater distributor 7, formed by connecting vertical partitions 15 and distribution chambers 4. enter the flotation chamber 8. At the same time, the distributor device 7 allows to evenly distribute the wastewater over the cross section of the flow chamber, and the sludge collector 16. formed by inclined partitions side wall, effectively remove the coagulated impurities that will gradually accumulate in the installation and periodically pumped through the discharge pipe 26 sludge and into the sludge collector 11. The flotation impurities enter the upper part of the flotation chamber 8 and are retained by the sludge-retaining partitions 17, which also serve as guides for the scraper sludge removal devices to the sludge collector 11. The clarified waste water, which contains a small amount of impurities, the water distribution partition 18 and the perforation of the side wall of the flotation chamber 25 enters the filtration chamber 9, in which it is filtered through the floating filter charge 19 and through the filtrate collection pipe 20 enters into bortniki 10 filtrate

equipped with branch pipes 28 of the filtrate of the circulating water supply system.

Periodically, flushing of the floating filtering load 19 is performed with a reverse flow of water from the circulating system through the nozzle 27. At the same time, suspended substances from the load with the washing water flow through the perforations 25 of the side wall of the flotation chamber 8, which

The case works as a sump with a sludge accumulator 16 located in the initial part. This also improves the plant performance by reducing the time for settling -flokamera 8,

works as a settling tank with two sludge tanks 16.

The clarified water through perforations in the opposite side of the side enters the filtration in another filtration chamber.

Example. Chromium-containing sewage was treated with a content, mg / dm3: chromium (total) 35, iron (total) 18. 18 chlorides, 178 sulfates, pH 7.2.

The proposed installation makes it possible to simplify the process of removing the sludge, evenly distribute the waste water in the flotation chamber, increase the reliability of individual elements and significantly improve the performance of the installation. At the same time, the structural change of position j of the distribution chambers in the flotation chamber is possible. chemical properties of the fluid.

Installation is easy to manufacture, not

requires scarce materials, is easy to maintain, and allows for various cleaning techniques.

Claims (1)

Invention Formula A sewage treatment plant containing a flotation chamber with an electrode chamber, a filter, a perforated cylindrical distributor and shelving pans, characterized in that, in order to improve the cleaning efficiency and plant performance, it is equipped with a sludge trap connected to the flotation chamber using flotation sludge collectors, installed in its upper part and having flexible discharge hoses, distribution chambers are located in the flotation cell and provided with inclined partitions, forming sludge collectors with the side walls of the flotation cell, and with its bottom — a flocculation chamber, having in the upper part vertical distribution partitions connecting the distribution chambers, installed with a slope upstream, with the perforations in the side wall of the distribution chambers located at a height of 0.7-0.9 at the inlet of the stream, and 0.1-0.3 at the outlet of the stream of the wall height. Table 1 table 2 - five FI.1 28 Aa 29 11 tt i at fig