RU2547503C1 - Water treatment device - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: water treatment device comprises a hydrocyclone with feeding and drain branch pipes, a filtering element installed in the inner part of the hydrocyclone, its lower end is dead and a corrosion-resistant flanged drain branch pipe is threaded to the upper end and is flange-mounted to the outlet branch pipe of the hydrocyclone, inlet, outlet and washing pipelines with relevant branch pipes and gate valves allowing for periodical change of operating mode: filtration of water suspension by the hydrocyclone and the filtering element, washing of the filtering element and treatment waste collector by return flow of the water suspension to the discharge system, the treatment waste collector with a quick-detachable cover and a tap. The filtering element consists of the cylindrical and conical parts conjugated in the plane of co-location of the hydrocyclone's cylindrical and conical parts. The sides of the filtering element's conical part are parallel to the sides of the hycrocyclone's conical part. The outlet hole of the feeding branch pipe in the hydrocyclone is made as a segment with the arc length l ≈ 3.1r, where r stands for the radius of the inlet hole of the feeding branch pipe in the hydrocyclone and is set at the angle of φ = arctg0.32(0.12÷0.4) to the perpendicular of the hydrocyclone axis.

EFFECT: increased reliability and high quality of water treatment process.

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Description

The invention relates to devices for separation of inhomogeneous liquid media in the field of centrifugal forces, in particular to hydrocyclones. The device can be used in metallurgical, petrochemical, construction, food and other industries, including agriculture and urban water supply.

A water purification device is known that contains a horizontally mounted airtight container filled with filter material, upper and lower distribution systems for supplying an aqueous suspension to the network and for removing pollution products. The installation can operate in two modes: filtering the aqueous suspension and washing with reverse current of the filter element. Flushing is carried out by switching a two-position distributor, the casing of which is hydraulically connected by nozzles to the upper and lower water distribution systems for supplying an aqueous suspension from the water source and drainage of purified water, as well as a network for removing pollution products. At the inlet and outlet of the hydraulic network, cyclones are sequentially installed, in the cavities of which self-cleaning strainers are mounted, the bottom parts of the cyclone bodies are connected to collections of pollution products [RF Patent 2272790, IPC C02F 1/52, B01D 36/00, B04C 9/00].

The technical disadvantage of such a device: the complexity of the design, high metal consumption and cost, insufficient reliability of the technological process of water treatment, low quality of the resulting product.

The closest and adopted as a prototype is a water purification device containing a hydrocyclone, inlet and outlet pipelines with valves, a waste collection chamber for cleaning, and a pipe filter located in the inner part of the hydrocyclone. The lower end of the pipe filter is plugged, and a corrosion-resistant pipe with a flange is mounted on the upper end of the pipe, which is bolted to the outlet pipe of the hydrocyclone and the irrigation system by means of a bolt connection. The inlet and outlet pipelines to the valves are interconnected by a pipeline with a valve, which allows you to periodically change the operating mode: filtering the aqueous suspension with a hydrocyclone and a pipe filter; washing the pipe filter and the collection chamber for cleaning waste by reverse current of the aqueous suspension into the discharge system [RF Patent 2411719, IPC A01G 25/09].

The technical drawback of such a device is the insufficient quality and reliability of the water treatment process.

These disadvantages of the analogue and prototype are due to the structural imperfection of hydrocyclones - the shape and spatial position of the supply pipe, the shape of the fine filter element.

In the present invention solves the problem of increasing reliability and achieving high quality technological process of water treatment.

When implementing the proposed device receive the following technical result: the intensification of the technological process of water treatment.

The technical result is achieved by the fact that in the water purification device, including a hydrocyclone with supply and drain pipes, a filter element located in the inner part of the hydrocyclone, the lower end of which is plugged, and a corrosion-resistant drain pipe with a flange mounted on the upper side, flanged to the outlet nozzle of the hydrocyclone, the inlet, outlet and flushing pipelines with the corresponding nozzles and valves, allowing to periodically change the operating mode: filtering the aqueous suspension g drotsiklonom and the filter element; washing the filter element and the waste collection container with a reverse current of the aqueous suspension into the discharge system, the treatment waste collection unit with a quick-release cover and a pipeline valve, according to the invention, the filter element is made of cylindrical and conical parts mated in the plane of alignment of the cylindrical and conical parts of the hydrocyclone, the sides of the conical part the filter element is parallel to the sides of the conical part of the hydrocyclone, while the outlet of the supply pipe of the hydrocyclone is made in the shape of the segment with the arc length l≈3,1r, where r is the radius of the inlet of the hydrocyclone supply pipe, and at an angle of inclination of the axis to the vertical relative to the cover plane φ = arctg0.32 (0.12 ÷ 0.4).

It is widely known that the filtration of an aqueous suspension in hydrocyclone-type apparatuses occurs due to centrifugal forces that exceed tens and hundreds of times the force of gravity, under the action of which heavy mechanical impurities move from the axis of the hydrocyclone to its walls along a spiral path downward and through the sand pipe apparatus. The lighter phase moves in an internal spiral flow directed upward and is discharged from the hydrocyclone through a drain pipe. The installation in the working zone of the hydrocyclone of a fine filter element in the form of a pipe actually leads to a breakdown in the conical part of the apparatus of the spatial untwisting spiral and vortex, i.e. to the violation of the hydrodynamics of internal and external flows, and this accordingly negatively affects the degree of separation of the aqueous suspension.

In the domestic and foreign industry, for the separation of inhomogeneous liquid media, namely aqueous-organic, in the field of centrifugal forces, hydrocyclones with feed pipes of various geometric shapes are known. Due to this technical solution, a balance of the input and peripheral velocities in the cylindrical part of the apparatus is achieved, which contributes to the shockless fluid inlet and, accordingly, has a positive effect on the hydrodynamic structure of the flow and the cyclone performance [Ternovsky I.G. Hydrocyclone / I.G. Terno, A.M. Kutepov. - M .: "Science", 1994. - 350 p.].

For the separation of aqueous-organic media, the feeding nozzles of hydrocyclones perform round, oval, square, rectangular and triangular sections. In this case, the best performance of the cyclone is achieved by supplying fluid through the supply nozzles with rectangular holes, in which the larger side is parallel to the axis of the apparatus, and elliptical in shape. The qualitative separation is also influenced by the direction of the liquid along the spatial spinning spiral, the stability of the vortex and the reduced turbulence of the flow in the working zone of the apparatus, which is achieved by arranging the supply pipe at an angle φ to the perpendicular to the axis of the hydrocyclone.

When separating aqueous-organic liquids, the angle φ is arctg (h / πD) or arctg (d / πD), where h and d are the height and diameter of the inlet of the supply pipe, respectively, of rectangular and elliptical shapes, mm; D is the diameter of the cylindrical part of the hydrocyclone, mm [Shestov, R.N. Hydrocyclones / R.N. Hydrocyclones. - L .: Publishing house "Engineering", 1967. - 78 p.].

According to the recommendations D = d / (0.12 ÷ 0.4) [Design of wastewater treatment plants. Reference manual to SNiP 2.04.03-85 “Sewerage. External networks and facilities. ” - Developed by VNII VODGEO Gosstroy of the USSR. - M .: "Stroyizdat", 1990. - 65 p.].

The technical disadvantage of the known solutions is as follows:

1. The manufacture of a supply pipe with different sections of the inlet leads to a complication and cost of the apparatus design, as well as an increase in the complexity of mounting the cyclone on the work site, in particular, in the field on drip irrigation or fine irrigation systems, the installation of such an apparatus is extremely difficult. This is due to the fact that when connecting the cyclone to the supply pipe, in which the cross-sectional shape is only round, it is necessary to additionally have transitional flanges with different cross-sectional shapes on both sides. The production of non-standard flanges is possible only in the factory, while special devices, equipment adjustment are required, and this entails additional labor, time, finance, and so on; in the field or in remote rural areas - it is almost impossible.

2. The geometric shape of the sections of the inlet openings of the supply pipe and its angle of inclination relative to the perpendicular axis of the hydrocyclone, affecting the ordering of the pulp flows and the reduction of their turbulence in the working area of the apparatus, in most cases were tested on the separation of aqueous-organic media, in particular: fat - water, kerosene - water, paraffin inclusions - water, etc. It is known that the type of an aqueous-organic liquid, like any other separation object, possesses physicochemical and mechanical properties inherent only to it (density, viscosity, particle size dispersion, etc.) For drip irrigation and fine irrigation systems, only water with inclusions of mechanical composition - an aqueous suspension, conventionally with constant density, viscosity, etc. Thus, the known solutions for the geometry of the shapes of the supply nozzles and their spatial position relative to the perpendicular to the cyclone axis do not give a clear idea and recommendations on the design of the apparatus for separating water - mechanical impurities, in particular, for drip irrigation and fine irrigation systems.

For a rational choice of the geometry of the shape of the feeding branch of the hydrocyclone, experiments were carried out to separate the aqueous suspension with mechanical impurities. We tested (Table 1) the rectangular and elliptical drain pipes already noted above, as well as the proposed pipe in the form of a segment with an arc length l≈3,1r.

Thus, the proposed solution with the outlet of the supply pipe of the hydrocyclone in the form of a segment, the location of the supply pipe to the perpendicular axis of the hydrocyclone at an angle, as well as the shape of the fine filter element and the parameters recommended by the applicant for these positions allow:

1. To establish a balance of the inlet and peripheral velocities of the aqueous suspension in the cylindrical part of the apparatus and to provide shock-free fluid entry into the working area of the apparatus.

2. To reduce turbulence and ensure the maintenance of a stable vortex in the working area of the apparatus, as well as the direction of the aqueous suspension along a spatial untwisting spiral.

3. To increase the degree of symmetry of the radius of the surface of zero axial speeds, providing a decrease in the boundary grains.

4. To increase the washing efficiency of the fine filter element with reverse current of the aqueous suspension and to increase the inter-washing cycle of its operation.

In addition, the proposed technical solution allows to achieve the highest density of treatment waste and the lowest density of discharge.

The water treatment device is illustrated by drawings: FIG. 1 is a general view of a water treatment device; FIG. 2 is a top view of a water treatment device; FIG. 3 - hydrocyclone with a filter element.

The water treatment device includes an inlet pipe with a pipe 1 and a valve 2, a hydrocyclone 3, consisting of a cylindrical 4 and conical 5 parts, as well as a supply 6 and a drain 7 pipes, a fine filter element 8 located in the inner part of the hydrocyclone, a pipe for unloading cleaning waste 9 , a collection of cleaning waste 10 with a flushing pipe 11, a pipe valve 12 and a quick-release cover 13, an outlet pipe with a pipe 14 and a valve 15, a washing pipe 16 with a valve 17, a main or distribution pipe wire 18.

The water treatment device can operate in two modes: filtering the inlet aqueous suspension with a hydrocyclone 1 and a fine filter element 8; washing the fine filter element 8 and the waste collection tank 10 by returning aqueous suspensions to a waste system.

In the mode of filtering the aqueous suspension, the valve 17 is closed, and 2 and 15 are open: the aqueous suspension enters through the inlet pipe 1 through the supply pipe 6 to the cylindrical part 4 of the hydrocyclone 3 tangentially. The flow in the hydrocyclone 3 is twisted, the heavy fractions hitting the walls, along the conical part 5 of the hydrocyclone 3 are lowered down and through the discharge pipe of the waste treatment 9 fall into the collection of treatment waste 10. The aqueous suspension passing through the side surfaces of the fine filter element 8 is cleaned of suspended solids through a drain pipe 7 enters the outlet pipe with a pipe 14 and then into the main or distribution pipe 18.

In the washing mode of the fine filter element 8 and the waste collection tank 10 by the reverse current of the aqueous suspension, the valves 2 and 15 are closed and 17 are open. The aqueous suspension through the washing 16 and the outlet with the pipe 14 pipelines is fed through the drain pipe 7 to the fine filter element 8. The aqueous suspension, passing through the pores of the fine filter element 8, washes and squeezes out contaminants that enter the waste discharge pipe 9 into a collection of cleaning waste 10, and then with the open water tap 12 through the flushing pipe 11 into the discharge system.

The washing of the collection of cleaning waste 10 can also be carried out during the working process by opening the pipeline valve 12 for a short period. With all valves closed, the collection of cleaning waste 10 can be cleaned manually by opening the quick-release cover 13.

Thus, the claimed device provides increased reliability and the intensification of the technological process of water treatment.

Claims (1)

Water treatment device, including a hydrocyclone with supply and drain pipes, a filter element located in the inner part of the hydrocyclone, the lower end of which is plugged, and a corrosion-resistant drain pipe with a flange mounted on the upper end, flanged to the outlet of the hydrocyclone, is mounted at the inlet, outlet and flushing pipelines with appropriate nozzles and valves, allowing to periodically change the operating mode: filtering the aqueous suspension with a hydrocyclone and a filter element; washing the filter element and the waste collection container with the reverse current of the aqueous suspension into the discharge system, the waste collection container with a quick-release cover and a pipeline valve, characterized in that the filter element is made of cylindrical and conical parts mated in the plane of alignment of the cylindrical and conical parts of the hydrocyclone, the sides the conical part of the filter element parallel to the sides of the conical part of the hydrocyclone, while the outlet of the supply pipe of the hydrocyclone is made in the shape of the segment with the arc length l≈3,1r, where r is the radius of the inlet of the supply pipe of the hydrocyclone, and at an angle of inclination φ = arctg0.32 (0.12 ÷ 0.4) to the perpendicular axis of the hydrocyclone.

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