SU1692609A1 - Settling tank for cleaning oil-containing water - Google Patents

Abstract

The invention relates to a technique for treating oil-containing wastewater and can be used in the oil and petrochemical industry, as well as in other branches of the national economy, the wastewater of which is contaminated by oil and oil products. The purpose of the invention is to increase the cleaning efficiency. The sump includes a tank with a layer of contact mass of oil, a pipeline with water supply pipes, a pipeline for draining purified water, a device for draining oil immersed in an oil layer and equipped with stream-forming nozzles cylindrical perforated chambers, the bottoms of which are made in the form of a surface of revolution obtained by rotating a semi-circle around the axis of the chamber passing through the beginning of the semicircle. Perforated chambers are provided with separation sleeves coaxially mounted inside them. The upper third of the lateral surface of the chambers is made with windows. Inverted annular trays along the peripheral edge are connected to the inner wall of the chambers to form dividing partitions between suction and extrusion zones in the chambers, and the outlet openings of the separation sleeves are located at the level of the tops of the bottoms of the bottoms and are equipped with sockets that follow the shape of the projections. 2 Il. (L with

Description

The invention relates to a technique for treating oil-containing waste water and can be used in oil, oil refining and other branches of the national economy, the waste waters of which are polluted with oil and oil products.

The purpose of the invention is to increase the cleaning efficiency.

FIG. 1 shows a sump, a longitudinal section in FIG. 2 shows section A-A in FIG. one.

The sump includes a tank 1, in the upper part of which is placed a layer of contact mass of oil 2, and cylindrical perforated chambers are immersed in it

3, the upper third of the side surface of which has windows 4, and the rest of it is perforated. The chambers 3 are connected to the pipeline 5 by means of water-conducting pipes 6, which are placed coaxially with the chambers 3. The pipeline 7 for discharging the purified water is placed in the lower part of the tank 1. The container 1 is equipped with a device for the removal of excess oil, which consists of a pipe 8 and an interfacial level regulator 9. Inside the chambers 3 and co-axially with them, jet-forming nozzles 10 are installed, connected to the water supply system by means of nozzles 6. Bottom 10 opposite to nozzles 10

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chambers 3 are made as a surface of rotation obtained by rotating the circumference field around the axis of chambers 3, which passes through the beginning of the semicircle, i.e. the diameter of the semicircle is equal to the radius of the chamber 3 The protrusion of the surface of the bottoms 11 is directed against the flow of liquid from the masadki 10 Inside the chambers 3 and coaxially with them are installed separating sleeves 12, the upper part of which is made in the form of inverted ring trays, peripheral edges of which are at a distance of 1/3 of height connected to the inner wall of chambers 3, separating the suction zones and giving off lazy liquids, i.e. performs the role of a dividing wall. The sleeves 12 in the lower part are provided with sockets located at the level of the top of the projections of the bottoms and repeating the shape of the projections of the bottoms 11.

The sump works as follows.

The tank 1 is filled with water and a calculated amount of oil, and then the source water is fed into the pipeline 5. Water through the nozzles 6 and nozzles 10 in the form of jets enters the cavity of the separating sleeves 12. The jet-forming nozzles 10 and the upper part of the sleeves 12 form an injector that enhances the suction effect of the liquid contact mass from the layer 2 through the upper third surface of the chambers 3 and involving the sleeves in the cavities 12. 8, the process of moving the mixture of the source water and the liquid contact mass through the sleeves 12 is the hard contact of these phases in the turbulent mode in a cylindrical cavity isolated from the circulation currents. Due to the fact that the bottoms 11 are made in the form of a streamlined rotational surface, providing the most efficient and uniform distribution of the jets from the nozzles 10 over the bottoms 11, the jets emanating from the sleeves 12 are reflected from the bottoms 11 in the form of annular cylindrical jets, which when the upper part of the sleeves 12 is reached, in the form of inverted annular trays, they are also reflected back in the form of annular streams. Thus, circulating currents are formed between the bottoms 11 and the upper part of the sleeve 12, some of which are displaced from the chambers 3 through the openings in the lower part as water flows from the nozzles 10. The oil involved in chambers 3 is mixed with the source water. repeatedly circulates in the cavity of chambers 3 and in the form of streams enters through the hole in the lower part of chamber 3 into the layer of oil 2 In the circulation process, the source water is both / faded by oil, entering into hard v with it

developmental contact, in which droplets of oil present in water are absorbed by the oil absorbed from tank 1. It has been established that

the upper third of the heights of the nozzles 10 and the liquid outlet in the lower part of the chambers 3, which is 2/3 of their height. The water enriched with oil, after circulation through holes in the lower part of chamber 3, flows into the layer of oil 2, where the process of contact purification of water from oil is carried out. The presence of the split sleeves 12 changes the pattern of fluid movement inside the perforated chambers 3, the jet section

5 mixtures of the initial water with a contact mass inside the sleeves 12 from the circulation currents outside the sleeves 12. As the settling process proceeds continuously in layer 2, water droplets are deposited in the oil layer 3, 5 as a result

In the upper part of layer 2, dehydrated oil accumulates, which is sucked into chambers 3.

The oil contained in the water is absorbed by the contact mass 2, and the purified water

5 enters the layer of oil 2 in the buffer zone, in which dynamic settling takes place. Large particles of oil, entrained by the flow of the diodes, float and merge with the contact mass, and water drains the consumer through pipe 7. After re-accumulation, oil from layer 2 is withdrawn through pipe 8, and the height of layer 2 is maintained by the interfacial level controller S.

After the outflow from the sleeves, the mixture moves for 5 s in the mode of circulation currents, but does not come into contact with the jets from the jet-forming nozzles, i.e. negative interaction of circulation currents and jets from the nozzles is excluded. In tribute

This significantly increases the lifetime of circulating currents.

This is facilitated by the fact that kinetic energy losses are reduced as a result of jet movement through the liners, 5 which means that circulation currents receive more energy and have a greater survivability.

The application of the proposed technical solution will make it possible to increase the efficiency of cleaning oily water by eliminating drawbacks in the design of chambers.

Due to the fact that the upper third of the lateral surface of the chambers has windows, it improves

5 conditions for the arrival of the contact mass from the perforated chambers and the energy consumption of the jets for injection, c, o leads to an increase in the range of the jets,

The complete separation of the suction and extrusion zones of the fluid in the chambers eliminates the negative interaction of the streams, and also improves the circulation conditions of the fluid inside the chambers, since the cavity in which the fluid circulates occurs is disconnected from the intake fluid flow, which increases circulating fluidity. currents.

Making the outlet openings of the split sleeves in the form of sockets, repeating the shape of the protrusions, and placing them in close proximity to the bottoms of the perforated chambers, completely eliminates the launching of the jets and separates the jets of water from the circulation currents, resulting in more favorable circulation conditions. fluids inside the chambers, which also increases the survivability of circulating currents.

Claims (1)

Claims of the invention: A settling tank for cleaning oily water, including a tank with a layer of contact mass of oil, a pipeline with water supply pipes, a pipeline for draining purified water, a device for oil diversion immersed in an oil layer and equipped with a cylindrical forming nozzles for the chamber, the bottoms of which are made in the form of a rotation surface obtained by rotating the semicircle around the axis of the chamber passing through the beginning of the semicircle and the ends of the bottoms are directed against flow tubes from the nozzles, and separating sleeves located inside the chambers, the upper part of which is made in the form of an inverted annular tray, characterized in that increase the cleaning efficiency, the upper third of the lateral surface of the chambers is made with windows, and the remainder of the lateral surface is perforated, the annular trays of separating sleeves are connected to the inner wall of the chambers with peripheral edges, and the separating sleeves in the lower part are fitted with sockets that repeat the shape of the bottom ledges, and located at the top of the protrusions. 1 ig.2