RU2151627C1 - Water purification plant - Google Patents

Abstract

FIELD: water purification technique; purification of natural water in agriculture; final purification of service and domestic runoff; purification of badly contaminated and oil- containing water. SUBSTANCE: water purification plant includes housing divided into chambers. First chamber is used for suspended layer; branch pipe for tangential supply of water to be purified is fitted between bottom and plate made in form of truncated cone; water is fed to suspended layer chamber through deflector. Second chamber is used for housing the centrifugal thin-layer which is mounted above suspended layer chamber on perforated plate; this settler has form of vertical spiral tape. Second chamber is brought in communication with third chamber where secondary centrifugal settler also made in form of spiral tape is located. Filter filled with filter medium is mounted below spiral tape in fourth chamber. EFFECT: enhanced efficiency; improved quality of water purification; improved operating conditions of plant. 4 dwg

Description

 The invention relates to techniques for water purification, also to installations for treating industrial waters of various industries and can be used for treating natural waters, in agriculture, for the purification of domestic wastewater, for the treatment of especially contaminated waters, oily waters.

 Thin-layer sedimentation tanks are known which can be tubular or lamellar. Plate sumps consist of a series of parallel mounted plates horizontally or inclined / cm. book of Roev G.A. etc. Wastewater treatment and recycling of petroleum products. -M .: Nedra, 1987, p. 68 /. The efficiency of water clarification is not large enough due to the fact that the suspension enlargement chamber and sedimentation chamber are not separated and affect each other, which reduces the quality of water treatment.

 Floating load / cm filters are also known. the same book by G.A. Royev, s. 135-136 /. However, the use of a simplified filter design without additional elements affecting the degree of water purification is inefficient, a small filtration cycle, as a result of which the rinsing volume is too high, which is necessary for more frequent washing of the filter. The operating mode of the filter with relatively frequent washing generally reduces the quality of water purification and complicates its operation.

 The closest technical solution to the claimed one is a water treatment plant, taken as a prototype described in RF patent N 2032630, class. C 02 F 1/52, 1995. This installation contains a housing, the end walls of which are equipped with inlet and outlet pipes for water and sediment, a thin-layer settler, a conical sediment collector combined with a suspended layer / flocculation chamber /, and a floating filter are placed in the housing loading. The flocculation chamber is equipped with recirculating means installed in its lower part in the form of an ejector directed upward by the suction part, while the thin-layer elements are made in the form of tubes of flexible material.

 The disadvantage of this installation is that the process of flocculation proceeds in one zone of a thin-layer sump. There is a large removal of finer suspension and lighter to the filter, and therefore, it reduces the efficiency of cleaning and the operation of the installation as a whole, in addition, the operation of the ejector to recirculate the suspension breaks already formed flakes and contributes to the removal of small flakes to the filter, which also worsens installation work. The operation of the ejector does not allow to obtain a compacted, less moisture sludge in the sump, the sludge is in a disturbed state, the sludge discharged with very high humidity is discharged from the sump with a significantly larger volume of water, which complicates the technological scheme and maintenance of the sump, impairing the performance of the sump entails, as a result, to the deterioration of the filter and the deterioration of the quality of water treatment throughout the installation.

 The aim of the invention is to increase the efficiency and quality of water treatment, increase the duration of the filter cycle, reduce the volume of wash water, reduce material consumption, the process of enlargement of flakes and the settling process to make them independent, not affecting each other, this will prevent the removal of contaminants to the filter flow and maximize the use the volume of the installation due to the organization of intensive emission of contaminants, and also will make it easy and simple to operate the installation.

 This goal is achieved by the fact that in the installation for water purification, comprising a housing, units for supplying and discharging water and sludge located in the housing of a thin-layer sump, a conical sludge collector and a filter with loading, according to the invention, a new installation is the separation of the capacity of the installation housing into chambers . The first chamber of the suspended layer / flocculation /, below which at the bottom of the unit, a plate is made in the form of a truncated cone, the upper base of which is directed towards the chamber of the suspended layer, and in the center of the cone there is an opening over which a conical cap is located with a gap, which performs the function deflector, while between the bottom and the truncated cone a pipe is installed for the tangential input of the purified water. A second chamber is located above the first chamber of the weighted layer, in which the primary thin-layer settler is located, made in the form of a centrifugal settler in the form of a vertical spiral tape mounted on a perforated plate, while a pipe with a longitudinal hole equal to the height of the spiral tape is installed along the axis of the second chamber, communicated with a weighted layer camera. Thin-layer modules are installed between the surfaces of the spiral strip, the shelves of which are mounted at an adjustable angle of inclination relative to the horizontal surface, a conical sediment collector connected to the discharge pipe is attached to the perforated plate. In the third installation chamber, a secondary centrifugal sump in the form of a vertical spiral strip mounted on the sheet plane with a central hole is located above the filter. Below the spiral tape in the fourth chamber is a filter with a load, over which a layer of crushed stone is placed on the grid.

 This design allows you to comprehensively and efficiently purify water, with the tangential input of the purified water into the chamber of the suspended layer and with a continuously continuous passage of water between the surfaces of the spiral tapes of the second and third chambers of the installation and additionally between the adjustable shelves of thin-layer modules of the second chamber and the filter of the fourth chamber of the installation. In this case, in the first chamber of the installation, water describes rotational movements in an upward flow, and in a spiral tape along its entire height from the axis of the settler in a spiral, water moves horizontally along a sinusoid, to the walls of the installation case. From the last spiral of the spiral tape, the second chamber of the installation, water enters the third chamber, into the spiral of the spiral tape of the secondary centrifugal sump and, moving in a spiral around the circle to the center, enters the fourth chamber in the central part of the spiral and is cleaned in a downward flow in the filter.

 A comparative analysis of the proposed technical solution with analogues did not allow to identify signs similar to the claimed, which allows us to conclude that the criterion of "inventive step".

The proposed device is shown in the drawings, where:
in FIG. 1 - section of the installation according to AA;
in FIG. 2 - installation plan;
in FIG. 3 is a sectional view of the apparatus along AA in a perspective view;
in FIG. 4 - thin layer module.

The installation consists of a housing 1, the walls of which are equipped with inlet and outlet pipes for water and sediment. The capacity of the housing 1 installation is divided into cameras. In the first chamber of the suspended layer at the bottom there is a plate 3 made in the form of a truncated cone, the largest base of which is directed to the chamber 2 of the suspended layer, and in its center there is an opening 4, over which there is a conical cap 6 with a gap 5 in the form of a deflector. Between the bottom of the installation and the truncated cone 3, a pipe 7 is installed for the tangential input of the purified water. Above the chamber of the suspended layer 2 is located in the second chamber 8 a primary centrifugal-thin-layer sedimentation tank made in the form of a vertical spiral tape 9 mounted on a perforated plate 10. Between the surfaces of the spiral tape 9 along the axes of the chamber 8 are thin-layer modules 11, shelves 12 of which are located under adjustable angle = 25-50 ^o inclination relative to the horizontal plane. A pipe 13 is installed along the axis of the second chamber 8 with a longitudinal hole 14 equal to the height of the spiral tape, in communication with the chamber of the suspended layer 2. A conical sediment collector 15 is attached to the perforated plate 10 with an annular gap 16, which is in communication with the pipe 17 for removal of sediment. In the third chamber 18 above the filter there is a secondary centrifugal sump in the form of a vertical spiral tape 19 mounted on the plane of the sheet 20, in the center of which there is a hole 21. The filter cavity 22 / zone / of the third chamber is communicated via a channel with the second chamber 8 of the sump for supplying clarified water from the peripheral spiral 23, spirally and the tape 9, into the peripheral spiral 24, the spiral tape 19 of the third chamber 18. Below the spiral tape 19, under the sheet 20, a support grid 25 is installed. Underneath it is a grid 26 on which the first layer of crushed stone 27 is 150 mm high. Below the grid in the fourth chamber 28 is a filter with a load 29, and behind it are caps 30 with a pipe 31 for draining purified water. In the lower part of the housing 1 is attached a pipe 32 for draining the wash water.

 The device operates as follows. The purified water through a pipeline 7 tangentially enters between the bottom and the surface of the truncated cone 3 and then through the hole 4 and the gap 5 under the conical cap 6 into the first chamber 2 of the suspended layer. The installation of the cap 6 with a gap 5 relative to the plane of the cone 3 allows you to perform the work of the deflector. Namely, the flow rate of water flowing around the perimeter of the cap to the periphery was sufficient so that no sediment layer formed on the flat surface of the cone, uniform distribution of fluid around the perimeter was ensured, and subsequently, the cone angle of plate 3 to the horizon provided shading of the water flow with suspension in the chamber suspended layer 2, which allows the most useful use of the volume of the chamber of the suspended layer. Suspended flakes, moving to the periphery, rise, describe a complex trajectory of movement, part goes down and is picked up again by a stream of water, and part goes through pipe 13 into the second chamber 8 and then into the longitudinal hole 14 of the pipe 13, which serves to evenly distribute the volume of water along the entire height of the vertical spiral tape 9, then water with flakes of suspension, moving centrifugally horizontally along a sinusoid between the surfaces of the spiral tape, is subjected to a whole range of influences. Pollution in the form of flakes, moving horizontally around a circle in a long space between the spirals, is processed by centrifugal forces, the magnitude of which is directly proportional to the acceleration of a particle of the water system. Additionally, a gravitational force acts vertically in the volume of water between the spirals on the particle of the system. The gravitational force acting on the particle has a variable value, its value depends on the sinusoidal velocity of the particle in the water volume, on the descending branch of the sinusoid, under the action of the total forces, the particles gain acceleration and slide tangentially along the vertical surface of the tape. Lighter particles of suspension move further and form a weak suspended layer on the ascending sinusoidal branch, in which the particles are enlarged and enter the next block of thin-layer sedimentation for processing. Along the way, the particle describes a complex trajectory of movement, passing thin-layer modules 11 from a set of adjustable parallel shelves 12, mounted at an angle to the horizontal plane along the axes of the chamber 8, the particle of contamination is subjected to a new additional effect with a sinusoidal centrifugal movement, which allows the main mass to be retained on the surface of the shelf 12 pollution. Centrifugal forces together with gravitational forces during the movement of the water system along a sinusoid force the particles to make a complex trajectory of movement between the shelves 12 of the thin-layer module, the sediment, accumulating, simultaneously moves along the surface of the shelf diagonally, and then along a vertical plane along a certain path, the suspension is deposited on a flat surface perforated plate sheet. The remaining suspension in the volume of water, leaving the thin-layer module, moves horizontally around the circumference to the next thin-layer module 11 / they are 8 pieces / along the ascending path of the sinusoid, the sinusoid is formed by the fact that the volume of water entering the vertical window of the thin-layer module is shifted vertically relative to the volume of water leaving the thin-layer module to a height determined by the angle of inclination of the shelves of the thin-layer module. Moving centrifugally around the circumference between the surfaces of the spiral tape, the suspended water simultaneously makes a sinusoidal motion relative to the vertical axis, the number of sinusoids depends on the number of thin-layer modules installed between the vertical surfaces of the spiral tape. Contaminants from the bottom of the centrifugal-thin-layer sedimentation tank are lowered down to the plane of the perforated plate and through the holes of the perforated plate 10 are transferred to the conical sediment collector 15, and from it through the pipe 17 are discharged into the tank for subsequent processing / not shown /.

 Water from the peripheral coil of the spiral 23 of the second installation chamber passes into the superfilter cavity of the third installation chamber and then into the peripheral spiral 24 of the secondary centrifugal sump with spiral tape 19, where the water continues centrifugal movement along the circumference between the vertical surfaces of the spiral tape of horizontal centrifugal settling, descending to the plane of the sheet 20, in which an opening 21 is provided for the flow of water from the third chamber 18 and the fourth filter chamber 28 with filter loading 29.

 With laminar movement of water in a conditionally infinitely long channel of a secondary centrifugal sump in the area of the filter's filter space, conditions are created for the maximum useful use of the entire volume of the third chamber of the installation with full maturity of the remaining suspension entering the filtering zone, which further increases the efficiency of the entire installation. The clarified water is processed by filtration through a layer of a filter charge 29 of a certain fraction (for example, 1-3 mm), the filtered water is discharged through a system of caps 30 through a pipe 31 into a clear water pocket 33 with a water level controller 34 throughout the installation. After a certain working cycle, the filter load is flushed through the pipelines 32 of the drainage system to drain the wash water from the filter and a siphon type hydraulic device / not shown / installed near the filter and connected to the pipeline of the drainage system 32.

 The system of lattice, mesh and gravel performs the following function.

 The lattice 25 of sheet metal placed on the edge, the top above the grid and the same under the grid, serves to hold a metal grid between them, which is affected by two forces, the vertical force is the total force of the pop-up filter load 29, and the compensating total weight of the crushed stone 27. Two forces opposite to the sign cancel each other out. In turn, the metal mesh serves to prevent the removal of the filter load 29 and to keep it in a certain volume. The mesh size of the mesh 26 should be smaller than the size of the filter load fraction. On top of the mesh 26 in the cavity between the ribs of the retaining lattice 25, crushed stone 27 of a fraction of 10-15 mm with a thickness of 120-150 mm is poured.

Claims (1)

 Installation for water purification, comprising a housing equipped with inlet and outlet pipes of purified water and sludge, a thin-layer sump, a conical sludge collector and a filter with a load placed in the housing, characterized in that the capacity of the installation housing is divided by a partition into chambers, in the first chamber, at the bottom , a plate is installed, made in the form of a truncated cone, the larger base of which is directed to the first chamber of the suspended layer, and in its center there is an opening, over which there is a conical cap with a gap, in fulfilling the function of the deflector, and between the bottom and the truncated cone there is a pipe for tangential input of the water to be purified, a second chamber is placed above the first chamber of the suspended layer, in which there is a thin-layer sump made in the form of a centrifugal sump in the form of a vertical spiral tape mounted on a perforated plate between the surfaces of the spiral tape are thin-layer modules, the shelves of which are located at an adjustable angle of inclination relative to the horizontal plane, and along a pipe with a longitudinal hole equal to the height of the spiral tape, in communication with the first chamber of the suspended layer, is installed on the axis of the second chamber, while a conical sediment collector with an annular gap is attached to the perforated plate, which is in communication with the pipe for removing sediment, in the third installation chamber, a secondary a centrifugal sump in the form of a vertical spiral tape mounted on the plane of the sheet, in the center of which there is a hole, while the third chamber is in communication with the second chamber for supplying light perishable water from the peripheral spiral tape of the primary centrifugal thin-layer sump to the peripheral spiral of the tape of the secondary centrifugal sump, below which, in the fourth chamber, there is a filter with a load, over which a mesh is installed, a layer of crushed stone is placed on it, below, in the filter, caps are installed, communicated with a pipeline for draining treated water, and a nozzle for draining the wash water is attached to the bottom.

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