RU2531379C1 - Flotation filter plant - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to motor transport washing machines. Proposed plant comprises intake filter, suction pipe, check valve, pump unit, ejector connected with bypass pipe at pump unit inlet, flotation chamber with filter and filter bed ply. Protective screen is arranged at ejector inlet to prevent clogging of ejector nozzle. Note here that said ejector has two unions, one to feed reagent solution connected to metering pump and another one to atmospheric air inflow. Note here that both unions have check valves. Note also that ejector is connected with two-stage saturator, second stage of which including pressure gage and discharge line connected with common pipeline. Note that said stage is connected via check valve with distribution manifold via nozzles arranged at flotation chamber bottom. The latter includes scraper mechanism, flute and overflow tube connected with filter top section. Filter has adsorbing filter bed retained by support and pressure frames. Every said nozzle consists of case with screw aligned with nozzle case bottom. Case top part union has cylindrical fluid feed hole. The latter communicates with diffuser axially symmetric with case and union. Screw is inserted into case to make cylindrical chamber above said screw and aligned with diffuser and communicated therewith. Note here that screw has central throttling bore while screw outer surface represents a single-start helical groove made inside said casing. Note also that helical groove outlet communicated with outlet conical chamber whereto plate sprayer is jointed. Said baffle consists of, at least, two parallel plates arranged perpendicular to said casing. First plate has central hole with diameter equal to that larger hole of outlet conical chamber. Second solid plate is secured to the first one by at least three fasteners. The latter comprises screw, nut and spacer washer to be fitted between plates for clearance adjustment.

EFFECT: higher efficiency of cleaning.

7 cl, 5 dwg

Description

The invention relates to wastewater treatment plants used at various facilities, in particular at washing stations of vehicles.

The closest technical solution to the claimed object is a flotation filtration unit according to the patent of the Russian Federation No. 2357926, F02C 7/24, containing a suction filter, a suction pipe, a check valve, a pump unit, an ejector connected to a bypass pipe and installed at the inlet of the pump unit, a chamber flotation with a filter and a filter loading layer, and a protective mesh is installed at the inlet of the ejector, which serves to prevent clogging of the ejector nozzle, while the ejector has two nozzles, one of which serves to enter and the reagent solution is connected by a tube to the metering pump, and the other serves to suck in atmospheric air, while check valves are built in both nozzles, while the ejector is connected to a two-stage saturator, the second stage of which contains a pressure gauge and an output line connected to a single pipeline, the second stage of the saturator through a check valve is connected to the distribution manifold through nozzles located in the lower part of the flotation chamber containing a scraper mechanism, a tray and an overflow pipe connected with the upper part of the filter having a layer of absorbent filter loading, which is held by the supporting and clamping frames (prototype).

A disadvantage of the known treatment plant is that it does not provide a high degree of wastewater treatment.

The technical result is to increase the efficiency of wastewater treatment to an extent that allows its multiple use.

This is achieved by the fact that in a flotation-filtration unit containing a suction filter, a suction pipe, a check valve, a pump unit, an ejector connected to a bypass pipe and installed at the inlet of the pump unit, a flotation chamber with a filter and a layer of filter loading, and at the inlet the ejector is equipped with a protective grid, which serves to prevent clogging of the ejector nozzle, while the ejector has two nozzles, one of which serves to enter the reagent solution and is connected by a tube to the metering pump, and the other it serves to suck in atmospheric air, while check valves are built-in in both nozzles, while the ejector is connected to a two-stage saturator, the second stage of which contains a pressure gauge and an output line connected to a single pipeline, while the second stage of the saturator is connected through a non-return valve to the distribution manifold through nozzles located in the lower part of the flotation chamber containing a scraper mechanism, a tray and an overflow tube connected to the upper part of the filter having a layer of an adsorbing filter loading nozzle, which is held by the supporting and clamping frames, each of the nozzles of the distribution manifold consists of a nozzle body with a screw coaxially located in the lower part of the nozzle body, and a nozzle located in the upper part of the body with a cylindrical fluid inlet connected to the diffuser, an axisymmetric body and the fitting, the screw is pressed into the housing with the formation of a cylindrical chamber located above the screw, coaxial to the diffuser, and connected to it in series, and the screw is made with the central throttle aperture, and the outer surface of the screw is at least a one-way screw groove and is located inside the housing, and the output of the screw groove is connected to the outlet conical chamber, to the end of which a plate atomizer is attached, which consists of perpendicular to the axis of the screw and parallel to each other at least two plates, one of which, the first plate, has a Central hole, the diameter of which is equal to the diameter of the larger of the holes of the outlet conical chamber, and the second plate and it is solid and fastened to the first by means of at least three fastening elements including a bolt, a nut and prostanovochnuyu calibrated washer placed between the plates and the regulating unit performs a function of controlling the gap.

Figure 1 shows a General view of the flotation-filtration unit, figure 2 - adsorbent adsorbent filter loading filter, made in the form of hollow balls, on the spherical surface of which a helical groove is cut, figure 3 - adsorbent adsorbing filter loading filter, made in in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, in FIG. 4 is a section BB-3 of FIG. 3, where a helical groove is cut, having in cross section perpendicular to the helical line a profile such as a “Berl saddle” or a saddle “In Aloxe "3 - scheme nozzle distribution manifold.

The flotation-filtration installation (Fig. 1) contains an intake filter 1, a suction pipe 2, a check valve 8 connected through a tee 41 to a valve 9 to start the pump unit 3. An ejector 4 connected to the bypass pipe 5 and installed at the inlet of the pump unit 3 mounted on the base 14. For the initial start-up of the pump unit 3, a valve 9 is provided. At the entrance to the ejector 4, a protective mesh is installed, which serves to prevent clogging of the ejector nozzle. The ejector 4 has 2 fittings 11 and 12. The fitting 11 serves to inject the reagent solution and is connected by a pipe 42 to the metering pump 6. The metering pump 6 is connected by a pipe to the canister 13. The fitting 12 serves to suck in atmospheric air and has an adjusting screw 7. B both fittings have check valves integrated.

The mixture of wastewater with a reagent solution and air is carried out in the pump 3, after which the mixture enters through a pipeline 10 into a two-stage saturator 15, 16, where, under a pressure of 0.50 ÷ 5.5 MPa, air is dissolved in water and mixed with the reagent. The second stage of the saturator 16 contains a pressure gauge 17 and an output line 18 connected to a single pipe 38. In addition, the second stage of the saturator 16 is designed to supply purified water through a pipe 19, through a check valve 40, which then enters the distribution manifold 21 through nozzles 20, located at the bottom of the flotation chamber 22.

Each of the nozzles 20 (Fig. 5) of the distribution manifold 21 comprises a housing 47 with a screw 53 coaxially located in the lower part of the housing and a fitting 48 located in the upper part of the housing with a cylindrical fluid inlet 49 connected to the diffuser 50 and an axisymmetric housing 47 and fitting 48. For sealing the housing 47 with the fitting 48, a gasket 51 is provided. The screw 53 is pressed into the housing to form a cylindrical chamber 52 located above the screw 53, coaxially with the diffuser 50, which is connected to it by a follower but. The screw 53 is made with a Central throttle hole 55, and the outer surface of the screw 53 is at least a single-pass screw groove 54 with right or left thread and is located inside the housing 47, and the output of the screw groove 54 is connected to the output conical chamber 56, to the end which is attached plate sprayer. The auger 53 of the nozzle is made of solid materials: tungsten carbide, ruby, sapphire.

The plate spray consists of at least two plates perpendicular to the axis of the screw 53 and parallel to each other, one of which, the first plate 57, has a central hole, the diameter of which is equal to the diameter of the larger of the openings of the outlet conical chamber 56, and the second plate 58 is made continuous and attached to the first by means of at least three fasteners 60, including a screw, a nut, and a calibrated washer 59 installed between the plates 57 and 58 and acting as a control link, up ulation gap.

The foam is removed by a scraper mechanism (sludge remover) 25 and discharged into the tray 26 and then through the pipe 43 enters the sludge tank (not shown) for settling. For normal operation with a scraper mechanism, an overflow tube 39 connected to the top of the filter 29 is used.

In the filter 29, water enters the lower part, passes through a layer of an absorbent filter charge 30, and the purified water is discharged through an overflow pocket 33 and a pipe 45, while the load of the filter 29 is held by the supporting 31 and pressure 32 frames. Wash water is discharged through a tap 34 into the reservoir. As an adsorbent, active carbons of the brands BAU, AR-A, SKT-3, etc. are used.

If there is no need for deep cleaning, then the purified water after flotation is discharged through a tap 27 and a pipe 44. All the tanks of the installation have drain taps 34, 35, 36, 37, united by a single pipe 38, ending with a pipe 46. Water purified by flotation is supplied through the overflow pipe 24 to the head 23 and then through the tap 28 for deep cleaning into the charge built-in filter 29.

The adsorbent 30 is made in the form of balls, as well as solid or hollow cylinders, grains of an arbitrary surface obtained during its manufacture, as well as short segments of thin-walled tubes or rings of equal size in height and diameter: 8, 12, 25 mm.

In order to increase the degree of purification of the gas stream from the target component by increasing the contact area of the adsorbent with the target component, the adsorbent 30 can be made in the form of hollow balls, on the spherical surface of which a helical groove is cut (figure 2), or in the form of hollow balls, on a spherical surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the “Berl saddle” or “Intalox” saddle type (Fig. 4). The adsorbent 30 can be made in the form of cylindrical rings, on the side surface of which a helical groove is cut (Fig. 3). The adsorbent can be made in the form of cylindrical rings, on the lateral surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the “Berl saddle” or “Intalox” saddle type (Fig. 4). The adsorbent can be made in the form of toroidal rings (not shown in the drawing). The adsorbent can be made in the form of toroidal rings having a profile such as a “Berl saddle” or an “Intalox” saddle (not shown in the drawing).

Flotation filtration unit operates as follows.

The contaminated water after preliminary cleaning in the sump through the intake filter 1 through the suction pipe 2, through the check valve 8 enters the ejector 4 installed at the inlet of the pump unit 3. For the initial start-up of the installation, the pump unit 3 body must be filled with water through the valve 9. The working fluid flow the ejector enters through the bypass pipe 5. At the entrance to the ejector 4 a protective mesh is installed, which serves to prevent clogging of the ejector nozzle. The ejector 4 has 2 fittings 11 and 12. The fitting 11 serves to inject the reagent solution and is connected by a pipe 42 to the metering pump 6. The metering pump 6 is connected by a pipe to the canister 13. The fitting 12 serves to suck in atmospheric air and has an adjusting screw 7. B both fittings have check valves integrated.

In pump 3, the wastewater is mixed with the reagent solution and air, after which the mixture enters through a pipeline 10 into a two-stage saturator 15, 16. Here, under pressure of 0.50-5.5 MPa, air is dissolved in water and mixed with the reagent. From the 2nd stage of the saturator 16, the purified water through the pipe 19 through the check valve 40 enters the distribution manifold 21 through the nozzle 20.

The nozzle 20 (figure 5) of the distribution manifold 21 operates as follows.

The fluid is supplied through a cylindrical hole 49 to the diffuser 50, and from it to the conical chamber 52, from which it is supplied under pressure to the screw outer cavity of the screw 53 and through the throttle hole 55 to the conical chamber 56, and from it to the atomizer. A rotating fluid flow in the external screw cavity of the screw forms a vortex movement, with additional crushing of the liquid droplets due to turbulence of the outlet flow, and a finely dispersed rotating flow leaves the nozzle with a wide rotating spray torch.

In the lower part of flotation chamber 22, pressure is released and dissolved air is released from the water in the form of tiny bubbles, to which pollution particles adhere. The sludge is collected on the surface of the flotation chamber in the form of foam, which is removed by a scraper mechanism (sludge remover) 25 and discharged into the tray 26 and then through the pipe 43 enters the sludge tank (not included in the delivery set) for sedimentation. Sludge can be handed over for processing as a whole (if there is such a possibility), and in separate fractions after sludge and discharge from above of oil products and water from the middle part. Petroleum products should be returned for processing or used as liquid fuel. Water is returned to the sump for treatment. Suspended solids in the sludge tank can be removed and buried at the landfill or used as an additive in road surfaces at asphalt concrete plants.

In the filter 29, water enters the lower part, passes through a layer of absorbent filter charge 30. The purified water is discharged through an overflow pocket 33 and pipe 45, the filter load is held by supporting 31 and pressure 32 frames. Filter loading is selected depending on the technology of wastewater treatment. The standard loading of the filter for wastewater treatment of car washes is polyurethane foam oil sorbent (crumb 10-20 mm). When clogged polyurethane foam chips, the filter 29 is removed from the installation and washed from above with a stream of water. Wash water is discharged through a tap 34 into the reservoir.

If there is no need for deep cleaning, then the purified water after flotation is discharged through a tap 27 and a pipe 44. All installation tanks have drain valves 34, 35, 36, 37, united by a single pipe 38, ending with a pipe 46. The electrical and hydraulic circuits of the installation provide it work in automatic mode in accordance with the consumption of circulating water for washing cars or as sewage arrives using the sensors of the minimum and maximum water levels in the tank. Water purified by flotation method enters through an overflow pipe 24 into the head 23 and then through a faucet 28 for deep cleaning into a built-in backfill filter 29.

Reagent treatment is used with increased requirements for wastewater from a car wash or with increased concentrations of wastewater pollution. The type, dose and working concentration of the reagent are taken according to wastewater treatment technology. The proposed device can work with reagent wastewater treatment. Due to the fact that the main part of the dissolved contaminants is anionic surfactants, cationic flocculants, for example polyvinylpyridine, are used as reagents.

The proposed device is designed to use a closed system of water consumption. The characteristic dosage levels of flocculants when used in clarification processes are in the range of 0.05-0.2 g / m ³ depending on the quality of the untreated water.

Claims (7)

1. A flotation-filtration unit containing a suction filter, a suction pipe, a check valve, a pump unit, an ejector connected to a bypass pipe and installed at the inlet of the pump unit, a flotation chamber with a filter and a filter loading layer, and a protective screen is installed at the inlet to the ejector , which serves to prevent clogging of the ejector nozzle, while the ejector has two nozzles, one of which serves to enter the reagent solution and is connected by a tube to the metering pump, and the other serves to suction atm spherical air, at the same time, check valves are built-in in both nozzles, while the ejector is connected to a two-stage saturator, the second stage of which contains a pressure gauge and an output line connected to a single pipeline, while the second stage of the saturator is connected through a non-return valve to the distribution manifold through nozzles located in the lower part of the flotation chamber containing a scraper mechanism, a tray and an overflow tube connected to the upper part of the filter having a layer of absorbent filter loading, which rzhivaetsya supporting and clamping frames, characterized in that each nozzle of the distribution manifold consists of a nozzle body with a screw coaxially located in the lower part of the nozzle body, and a nozzle located in the upper part of the body with a cylindrical fluid inlet connected to a diffuser, an axisymmetric body and fitting, the screw is pressed into the body to form a cylindrical a chamber located above the screw, coaxial to the diffuser, and connected to it in series, moreover, the screw is made with a central throttle hole, and the outer surface of the screw is a at least a one-way helical groove is located inside the housing, and the output of the helical groove is connected to the outlet conical chamber, to the end of which a plate atomizer is attached, which consists of at least two plates perpendicular to the axis of the screw and parallel to each other, one of which, the first plate has a central hole, the diameter of which is equal to the diameter of the larger of the openings of the outlet conical chamber, and the second plate is solid and is attached to the first by at least three ex fasteners, including a screw, nut and spacing calibrated washer installed between the plates and acting as a regulating link that controls the gap. 2. Flotation filtration plant according to claim 1, characterized in that the adsorbent is made in the form of balls, as well as solid or hollow cylinders, grains of an arbitrary surface obtained during its manufacture, as well as short segments of thin-walled tubes or rings of equal size in height and diameter: 8, 12, 25 mm. 3. Flotation filtration plant according to claim 1, characterized in that the adsorbent is made in the form of hollow balls, on a spherical surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the “Berl saddle” or “Intalox” saddle type. 4. Flotation filtration plant according to claim 1, characterized in that the adsorbent is made in the form of cylindrical rings, on the side surface of which a helical groove is cut. 5. Flotation filtration plant according to claim 1, characterized in that the adsorbent is made in the form of cylindrical rings, on the side surface of which a helical groove is cut, having in cross section perpendicular to the helical line a profile of the “Berl saddle” or “Intalox” saddle type. 6. Flotation-filtration plant according to claim 1, characterized in that the adsorbent is made in the form of toroidal rings. 7. Flotation-filtration plant according to claim 1, characterized in that the adsorbent is made in the form of toroidal rings having a profile of the type of "Berl saddle" or saddle "Intalox".

Images