RU2312069C2 - Installation for floatation purification of the water - Google Patents

Abstract

FIELD: oil-producing industry; petrochemical industry; other industries; production of the devices for floatation purification of the industrial waste waters containing the oil products, grease and other impurities.

SUBSTANCE: the invention is pertaining to the devices for floatation purification of the industrial waste waters and may be used for purification of the industrial waste waters containing the oil products, greases and other pollutions, and also for treatment of the water for the different needs. The installation for floatation purification of the water contains the flotation chamber (16), the saturator (6), the pump aggregate (1), which pressure pipeline is made in the upper part of the saturator (6), the jet ejector (2) and the suction pipeline (4) with the inverted valve (15). The jet ejector (2) is installed on the inlet of the pump aggregate (1) on the axis of its symmetry. The pressure pipe line (8) of the jet ejector (2) is mounted on the lower part of the saturator (6). The saturator (6) is connected by this pipeline also with the flotation chamber (16). The vacuum chamber (10)of the jet ejector (2) is supplied with the fitting pipes of feeding of the free air (13) and the chemical reactant (14). The mounting of the jet ejector (2) on the inlet of the pump aggregate (1) is exercised by means of the adapter connector (3),to which the suction pipeline (4) is tangentially connected. The diffuser (12) of the jet ejectors (2) is made cylindrical with formation of the annular clearance between the diffuser (12) and the wall of the adapter-connector (3). The ratio of the cross-section area of the annular clearance to the area of the cross-section of the suction pipeline (4) is taken as 3:2. The technical result of the invention is the increased speed of the reaction of dissolution of the chemical reactants in the flow of the interacting components, the speedup of the process of the flocculation in the purified liquid.

EFFECT: the invention ensures the increased speed of the reaction of dissolution of the chemical reactants in the flow of the interacting components, the speedup of the process of the flocculation in the purified liquid.

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Description

The invention relates to devices for flotation water treatment and can be used in purification schemes for industrial wastewater containing oil products, fats and other contaminants, as well as water treatment for various needs.

A device for flotation wastewater treatment (certificate of the Russian Federation for utility model No. 22663, IPC C02F 1/24, published on 04/20/2002), containing a flotation chamber, pump, fluid inlet and outlet pipes, an ejector with a diffuser included in the bypass line nozzle and fittings for supplying both chemicals and evacuator evacuation, while the nozzle for supplying chemicals is installed directly in the ejector, and the nozzle for evacuating the ejector is in communication with the atmosphere; the ejector nozzle is connected to the discharge line of the wastewater, and the diffuser of the ejector is connected to the suction line of the wastewater.

However, in this device there is insufficient speed of the process of flocculation, which leads to the need to increase the size of the saturator and flotation chamber. In addition, it is difficult to start the pump unit in conditions when the receiving tank is located below the level of the pump.

The closest to the proposed device for flotation water purification in technical essence and the achieved result is a compression flotation unit (AS USSR No. 789399, IPC C02F 1/24, published on 12/23/1980), including a saturator connected by pipelines to flotation chamber, ejector and pump; wherein the pipeline connecting the saturator to the ejector is connected to the pipeline connecting the saturator to the flotation chamber, and the ejector is connected to the suction pipe of the pump.

However, the installation of an ejector on the suction line of the pump leads to an insufficient degree of mixing of the water-air medium coming from the ejector with the original waste water; however, the introduction of chemicals is not provided, which does not provide the required degree of water purification.

The purpose of the invention is to accelerate the process of flocculation of contaminants and high-quality mixing of several media in the process of preparing the cleaned liquid for flotation.

This goal is achieved by the fact that in the installation for flotation purification of water containing a flotation chamber, a saturator, a pump unit, the pressure pipe of which is connected to the saturator, a jet ejector connected to the pressure pipe of the saturator, and the saturator is connected by the pressure pipe to the flotation chamber, the suction pipe with check valve, according to the invention, the jet ejector installation at the inlet of the pump unit along the axis of symmetry of the latter, the installation of the jet ejector at the inlet of the pump unit This is carried out using an adapter to which the suction pipe is tangentially connected, the diffuser of the jet ejector is made cylindrical with the formation of an annular gap between the diffuser and the wall of the adapter, while the ratio of the area of the annular gap formed by the cylindrical diffuser of the ejector and the wall of the adapter to the cross-sectional area of the suction pipe is accepted like 3: 2, the vacuum chamber of the jet ejector is equipped with two nozzles for supplying atmospheric air and a chemical reagent, pressure pipes Wire pump unit is brought to the top of the carbonator and the pressure line jet ejector withdrawn from the bottom of the saturator.

The drawing shows a diagram of an installation for flotation water treatment.

The installation comprises a flotation chamber 16, a pump unit 1, the pressure pipe of which 5 is connected to a saturator 6 in the upper part of the latter, a jet ejector 2 with a vacuum chamber 10 passing into a diffuser 12. The vacuum chamber 10 of the ejector 2 is rigidly connected to a cylindrical adapter 3, which is mounted at the inlet of the pumping unit 1 along the axis of symmetry of the latter, moreover, a tangentially suction pipe 4 with a check valve 15 is connected to the adapter 3 for supplying purified water to the system.

The jet ejector 2 also contains an active nozzle 11 for supplying a working stream to the pump unit 1, a pipe 13 for intake of atmospheric air and a pipe 14 for introducing a chemical agent. The nozzle 11 of the ejector 2 is connected to the pipeline 8 for supplying the air-water mixture flowing from the bottom of the saturator 6. The pipe 9 serves to supply a mixture of various media in the flotation chamber 16.

The saturator 6 has in the upper part a valve 7 for venting excess air.

Installation works as follows.

The mixture stream, consisting of the liquid to be cleaned, atmospheric air and a chemical solution, such as a coagulant, is pumped by a pump unit 1 through a pressure line 5 to the upper part of the saturator 6, and from its lower part the air-water mixture is diverted in two streams: one stream through pipeline 9 is fed into the flotation chamber 16, and another stream through pipeline 8 - to the bypass line to the nozzle 11 of the ejector 2 mounted with an adapter 3 at the inlet of the pump unit 1.

The high-speed pressure jet of water-air mixture flowing out of the confuser of the nozzle 11 of the ejector 2 creates a vacuum in the vacuum chamber 10 of the ejector, due to which atmospheric air and the chemical solution are sucked into the chamber 10 through the nozzles 13 and 14, respectively.

At the moment of impact of the jet of active flow flowing from the nozzle 11 into the diffuser wall 12, a favorable dispersion effect of the flow is achieved, accompanied by the formation of a large number of fine liquid droplets and increased solubility of the aspirated atmospheric air.

The above important circumstances, especially dispersion, provide an increased rate of dissolution of chemical reagents in the flow of interacting components, which leads to the spontaneous nucleation of a large number of contamination coagulation centers, providing a high-speed development of the process of flocculation in the liquid being cleaned.

The effect of accelerated flocculation is also enhanced due to the fact that the working stream of the air-water mixture coming from the saturator 6 through the pipe 8 to the ejector 2 contains hydrolyzed coagulant particles, which are additional centers (nuclei) of the contamination coagulation process.

Strengthening the effect of flocculation is also facilitated by the process of mixing all the components of the flow, carried out first in the diffuser 12 of the ejector 2 (the first stage of mixing), then in the adapter 3 and at the entrance to the receiving chamber of the pump 1 (second stage of mixing).

The final mixing of the components is carried out in the pressure pipe 5 (the third stage of mixing).

At the same time, the effect of mixing four media (purified water, atmospheric air, a chemical agent and the active mixture flow coming from the pressure pipe 8 of the ejector 2) is enhanced in the pump cavity by introducing the liquid to be cleaned (via pipe 4) tangentially relative to the mixed flow of three media (atmospheric air) , chemical reagent and the stream coming from the ejector nozzle), flowing out of the diffuser 12 of the ejector 2. The swirling flow of the liquid being cleaned substantially “slows down” the working mixed flow of three media flowing from diffuser 12 of the ejector 2, as a specially created hydraulic resistance at the entrance to the cavity of the pump 1.

Moreover, in the right part of the adapter 3 there is an active mass transfer between the components of the two streams with the dilution of the three-component medium with the liquid to be purified (the fourth component of the mixed medium) to obtain a uniform state. Such a homogeneous medium then enters the saturator 6 through the pressure pipe 5, where it is additionally supersaturated with air. The last important circumstance is due not only to the saturation of the liquid with air through the ejector in conjunction with the initial concentration of air in the liquid being cleaned, but also to the efficient use of air for its intended purpose in the mass transfer processes occurring in the saturator, thanks to the claimed new design of the latter (see application for invention No. 20031102013 from 04/10/2003, “Device for saturating a liquid with gas”).

At the outlet of the saturator, the working stream is divided into two branches: through pipeline 8 enters the ejector 2, and through pipeline 9 to the flotation chamber 16. In this case, the processing cycle is continuously repeated.

Thus, the placement of an ejector 2 with an adapter 3 at the inlet of the pump unit 1 allows the simultaneous introduction of at least 4 components forming a single stream into the cleaning system, effective mixing of the three components, subsequent dilution of the resulting mixture with the fourth component (the liquid being cleaned) and their preliminary mixing in adapter 3 with final mixing in the pump cavity. At the same time, the increased mixing effect is also associated with the accelerated passage of flocculation processes realized in the liquid being cleaned in the system “ejector with adapter - pump unit”.

The creation of a multifunctional small-sized design in conjunction with the capabilities of a saturator (design according to application for invention No. 20031102013 dated April 10, 2003) allows for the implementation of the whole range of necessary preparatory chemical, hydrodynamic and technological processes in the liquid to be purified, providing an increased degree of wastewater treatment in the flotation chamber; at the same time, a characteristic distinguishing feature of the preparation of the liquid being cleaned is the accelerated and phased process of flocculation with parallel effective (stepwise) mixing of the components of the working medium, which together allows to achieve the objective of the invention.

The analysis of distinctive features by the criterion of "significant differences" showed the following.

1. Installing a jet ejector directly at the inlet of the pump unit increases the rate of fluid injection through the suction pipe, enhancing its suction in the cavity of the pump unit, provides a pressure jet of air-water flowing from the ejector nozzle directly into the pump cavity, contributes to high-quality preliminary mixing of the active stream flowing out of the nozzle, with the incoming liquid being cleaned before entering the pump cavity, since the active stream flowing out of the diffuser immediately arrives into the mixing zone with the sucked-in liquid being cleaned. This important circumstance prevents the separation of the active flow of the air-water mixture to the approach to the pump cavity, creating favorable conditions for the development of the process of subsequent mixing of all the components of the combined stream.

In addition, the installation of a jet ejector at the inlet of the pump unit ensures the latter starts up in the absence of a vacuum tank and ensures its stable operation, since the air-water mixture is introduced through the ejector to start the pump into its suction pipe. This ensures self-priming due to the creation of additional vacuum at the inlet to the pump.

Thus, the placement of the jet ejector at the inlet of the pump unit, as a hallmark of the installation for water purification, is not known from the patent and technical literature, which allows us to consider it new and significant.

2. Using the adapter as a device that directly connects a jet ejector and a pump assembly into a single unit allows constructively creating a chamber for preliminary mixing of the active air-air flow flowing from the ejector nozzle and the liquid to be cleaned, and by tangentially connecting the suction pipe to the adapter, significantly increase the effect of preliminary mixing in the conditions of input and movement of the cleaned liquid in the form of a swirling flow. This effect is associated with providing sufficient time for the interaction of contacting media, leading to the activation of the mass transfer process and an increase in the degree of mixing. This feature is not known from the patent and technical literature, which allows us to consider it new and significant.

3. The implementation of the ejector diffuser in the form of a cylinder with the formation of an annular gap between the diffuser and the adapter wall provides, firstly, compression of the jet of active stream flowing out of the nozzle, together with atmospheric air and a chemical solution involved in the diffuser, preparing potential conditions for the implementation of the kinetics of subsequent spontaneous expansion and mixing of the three components of the flow after the diffuser is cut off in conjunction with the process of preliminary mixing with the liquid being cleaned ayuschey into the adapter through the suction conduit. Secondly, the presence of a relatively small annular gap between the diffuser and the adapter wall enhances the effect of suction of the liquid being cleaned from the suction pipe by an active stream jet and, combined with the possibility of tangential introduction of the liquid being cleaned in the form of a swirling jet into the ring annulus indicated above, significantly improves the quality of preliminary mixing in right side of the adapter. The above symptom is not known from the patent and technical literature, which allows us to consider it new and significant.

4. The choice of the ratio of the cross-sectional area of the annular gap formed between the diffuser and the wall of the adapter to the cross-sectional area of the suction pipe, as 3: 2, allows a relatively low flow rate of the suction fluid in the cavity of the adapter, which favorably affects the formation of a stable swirl flow in the annular gap between adapter and diffuser; at the same time, the requirement of having a constant cross-sectional area of the suction pipe is observed. Reducing the above ratio (less than 3: 2) creates an unjustified additional hydraulic resistance in the suction pipe. In addition, this contributes to an increase in the axial velocity of the flow from the suction pipe in the annular gap, which leads to uneven fluid velocities in the annular gap and the formation of air cavities due to the separation of the air-water mixture entering the adapter from the diffuser, which disrupts the stable operation of the ejector and pump. An increase in the above ratio (more than 3: 2) leads to a decrease in the radial velocity of the swirling flow in the pre-mixing zone (right side of the adapter) of the air-water mixture and the initial liquid being cleaned. The creation of a structurally annular gap of a certain cross-sectional area with respect to the cross-sectional area of the supply pipe that allows fluid to enter the given annular gap in hydraulics is known, however, in combination with new and significant features (see paragraphs 1, 2, 3), this symptom allows to achieve the purpose of the invention, which makes it significant.

5. Equipping the vacuum chamber of the ejector with nozzles for supplying atmospheric air and a chemical reagent allows not only simultaneously introducing the required passive components into the active stream, but also simultaneously pre-mixing the three media in the diffuser, which positively affects the final stage of the mixing process, compared to sequential introduction of passive components into the active stream, known in the art, requiring additional circulation of fluid in the system to ensure the required quality of mixing. This feature is known in the inkjet technique, however, in combination with new and significant features (see 1, 2, 3, 4), it is possible to achieve the purpose of the invention, which makes it significant.

6. The supply of the pump pressure line to the top of the saturator and the output of the finished medium from the bottom of the saturator ensures the continuity of the flow of the working active medium at the inlet to the ejector nozzle due to the absence of large air bubbles in the bottom of the saturator, while the prepared working medium enters the ejector containing coagulated particles of contaminants that are a catalyst for accelerating the process of flocculation.

The use of the invention allows to obtain additional advantages, namely: to minimize the volume of the flotation chamber and saturator, to ensure the normal operation of the installation at relatively low ambient temperatures, to start the pump unit without the use of a vacuum tank and stable operation in technological mode.

Claims (1)

A flotation water treatment plant comprising a flotation chamber, a saturator, a pump unit, the pressure pipe of which is connected to the upper part of the saturator, a jet ejector, the vacuum chamber of which is equipped with nozzles for supplying atmospheric air and a chemical reagent, the pressure pipe of the jet ejector is removed from the bottom of the saturator, the last connected by this pipeline and to the flotation chamber, the jet ejector is installed at the inlet of the pump unit along the axis of symmetry of the latter, and the suction pipe with non-return valve, characterized in that the installation of the jet ejector at the inlet of the pump unit is carried out using an adapter to which the suction pipe is tangentially connected, the diffuser of the jet ejector is cylindrical with the formation of an annular gap between the diffuser and the wall of the adapter, while the ratio of the cross-sectional area of the annular gap formed the cylindrical diffuser of the ejector and the wall of the adapter, to the cross-sectional area of the suction pipe is taken as 3: 2.