RU2716784C1 - Device for filtration of large volumes of water - Google Patents

Abstract

FIELD: filtration.

SUBSTANCE: device for filtration of large volumes of water includes a housing, filtering elements, which are made in the form of cylindrical cartridges inserted one into another and placed between each other coaxially with a gap. Each cylindrical cartridge is formed from a mesh fixed outside the cylindrical frame from vertical ribs. Cylindrical cartridge lower part is closed by a plug rigidly connected to the cartridge. Cylindrical cartridges of each filter element are arranged relative to each other with reduction of mesh cells size in compliance with filtration direction from the outside to inside. In upper part of housing there are tube plates with holes, which hermetically separate body cavity to different-level zones. Each zone is equipped with two branch pipes for water supply and discharge. Any hole on the tube boards is aligned with the corresponding holes of other levels. Cylindrical cartridges made of mesh with identical size of cells are fixed in holes of one tube plate. Cartridges of one filter element are installed coaxially on pipe plates. Set of filter elements is arranged in housing with provision of equal distance from each other. Upper part of every cylindrical cartridge is secured to tube plate by means of tight connection.

EFFECT: high quality and fineness of filtration with simplification of filter design, reduced time required for filter cleaning, longer regeneration period, simplified maintenance.

6 cl, 3 dwg

Description

The invention relates to a device for filtering liquids and can be used in various industries where effective cleaning of liquids from mechanical impurities is required in a wide range of filter subtleties, with a continuous filtering process.

The filter according to the patent of the Russian Federation No. 2592632 is known, which includes a housing with connected fittings for entering a contaminated medium, a cleaned medium outlet, a washing medium outlet, a drainage fitting, a cover with a drive support and a gear motor mounted on it, an air outlet fitting, a collector shaft, including a central stepped shaft on which the positioning unit is located, which is a star with teeth. Inside the casing there are filter elements with an inner filtering surface in a replaceable cartridge mounted on a support flange inside the casing and fixed on top by a non-separable clamping board, in the central through holes of which a central pipe is fixed. The lower end of the central tube of the cartridge, mounted in the lower tube sheet and connected to the outlet fitting of the flushing medium. On the upper end of the central pipe, a sliding support is installed for the collector shaft, the lower hollow portion of which is connected to the bends. The number of taps corresponds to the number of concentric circles along which the filter elements are located. EFFECT: reduced weight and size characteristics, increased service life of the filter. However, the presence of a gear motor, manifold, washers, bushings made of antifriction non-metallic material for sliding relative to outlets and other nodes complicate the design of the regenerated filter.

The closest by design features is the cartridge filter according to the patent of the Russian Federation for utility model 137477. The filter refers to liquid filters designed to purify natural and waste waters, as well as oil products from suspended contaminants. The cartridge filter contains a tube-shaped housing, filter elements in the form of filter cartridges located inside the housing and having a filtering direction from inside to outside, and a washing direction from the outside to the inside, a pipe for supplying the liquid to be cleaned to the inlet of the filtering elements, a filtrate outlet pipe from the housing, a discharge pipe in drainage of dirt through automatic shut-off valves after flushing cartridges.

Outside the casing there are sensors that detect the difference between the filtrate pressures inside the casing and the liquid being cleaned inside each filter element. Sensors are connected to automatic shut-off valves of individual discharge pipes into the mud drain after flushing. The filter elements are arranged and fixed in two rows at an angle to each other. For the manufacture of the filter element any polymeric materials are used, while their designs can be membrane, mesh, slotted and others. The complexity of the filter design, its operation and maintenance is explained by the presence of pressure sensors and shut-off valves for each filter element, securing the nozzles at an angle does not contribute to compactness and makes maintenance difficult. The operation of shut-off valves operating in a contaminated environment is difficult.

The technical task of the invention is to provide high quality and fineness of filtering while simplifying the design of the filter, reducing the time spent on cleaning the filter, increasing the regeneration period, simplifying maintenance, and also simplifying the task of designing a filter for filtering large volumes of liquid.

To solve this problem, a filtering device is claimed.

A device for filtering large volumes of water, comprising a housing, filter elements located inside the housing, a nozzle for supplying the liquid to be cleaned, a nozzle for removing the filtrate from the housing, a nozzle for removing sediment after washing the cartridges,

characterized in that

each filter element is made in the form of cylindrical cartridges inserted one into the other, placed between themselves coaxially with a gap,

each cylindrical cartridge is formed of a grid fixed on the outside of the cylindrical frame of vertical ribs in the form of rods, round or tape rods, the lower part of each cylindrical cartridge being closed by a plug rigidly connected to the cartridge,

cylindrical cartridges of each filter element are arranged relative to each other with decreasing mesh size in accordance with the direction of filtration from the outside to the inside, and the inner layer with the smallest mesh size forms the central channel of the filter element,

tube plates are installed in the upper part of the casing with openings hermetically separating the casing cavity into different-level zones, and each zone is equipped with at least two nozzles with valves for supplying and discharging water, while any opening on the pipe planks is made coaxially with the corresponding openings of other levels ,

cylindrical cartridges made of mesh with the same mesh size are fixed in the holes of one tube plate, while cylindrical cartridges with the largest mesh cell size are fixed on the lower board, and cylindrical cartridges are fixed on each board next to the level with a sequential reduction in mesh cell size, while cylindrical cartridges of one filter element are mounted coaxially on tube sheets,

filter elements are placed in the housing with equal distance from each other and with the filter device housing, at least in accordance with the layout topology of the elements according to six-beam symmetry in the nodes and center of the honeycomb hexagonal grating,

in addition, positioning elements are placed in the gap between the cylindrical cartridges to ensure the coaxial position of the cylindrical cartridges forming one filter element, for example a coil spring,

the upper part of each cylindrical cartridge is fastened to the tube plate by means of a hermetic connection implemented using known technologies: either a threaded connection, or an adhesive connection, or by welding, which equally ensure the tight installation of cylindrical cartridges on the partition.

In FIG. 1 shows a general view of the filtering device, FIG. 2 shows a diagram of the attachment of cylindrical cartridges to multilevel tube plates; FIG. 3 shows a topology diagram of cylindrical cartridges in plan view at the nodes of the hexagonal lattice.

The filtering device comprises a housing 1, filtering elements 2. In the upper part of the housing there are tube plates 3-6 with openings 7. The tube plates hermetically divide the cavity of the housing into different level zones 8. Each zone 8 is equipped with at least two nozzles with valves for supplying and water drainage: nozzles 9-11 for supplying wash water and nozzles 12-14 for drainage of wash water. The upper part of the housing 1 is equipped with a nozzle 15 for discharging purified water, in the part of the tapering bottom there is a nozzle 16 for discharging sludge after washing the cartridges, in the lower part of the housing there are nozzles 17, 18 for supplying the water to be cleaned and the washing water out. the corresponding holes 19-21 on the boards of other levels,

Each filter element 2 is made in the form of cylindrical cartridges 22 inserted into one another, placed coaxially with each other with a gap 23.

The cylindrical cartridge 22 is formed from a mesh 24, mounted outside the cylindrical frame 25 from vertical ribs in the form of rods, round or tape rods, the lower part of each cylindrical cartridge is closed by a plug 26.

Cylindrical cartridges 22 in each filter element 2 are placed relative to each other with decreasing mesh size in accordance with the direction of filtration from the outside to the inside. The inner layer with the smallest mesh cell size forms in the structure of the filter element a central channel 27 for outputting purified water to zone 28 and for its discharge through pipe 15.

In the holes of one tube plate, cylindrical chucks made of mesh with the same cell size are fixed. On the bottom board 3, cylindrical cartridges with the largest mesh mesh size, for example 50 μm, are fixed, and on each next level board, cylindrical cartridges with a sequential reduction in mesh cell size are fixed, for example, cartridges with a filter mesh with a mesh of 25 microns are fixed on board 4, board 5 secured cartridges with a filtering mesh with a cell of 10 μm, on board 6 fixed the last cartridges in the filtering chain made of mesh, for example, with a cell of 5 μm. The fixing of the cylindrical cartridges on the tube sheets 3-6 can be performed using known technologies: either by means of a threaded connection, or by gluing, or by welding, which equally ensure the tight installation of cylindrical cartridges on the partition.

Cylindrical cartridges 22 of one filter cartridge are mounted coaxially on the tube sheets, which ensures a uniform distribution of water pressure over the entire filter surface of the mesh under conditions of creating a flow of water under pressure, which accordingly leads to the best filtration mode (and rinsing mode) with maximum performance. It is advisable to place positioning elements, for example, a cylindrical spring 29, in the gap 23 between the cylindrical cartridges, which simplifies the assembly of the filtering device to ensure the coaxial position of the cylindrical cartridges in the filter element (to simplify the circuit, the spring 29 is shown only on the inner cartridge).

The task of creating the best cleaning and washing conditions is also solved by rational placement of the filter elements 2 in the housing 1. It is proposed that the filter elements 2 be placed in the volume of the housing 1 with equal distance from each other and with the housing so that in terms of plan they are placed in accordance with the topology elements of six-beam symmetry in the nodes and center of the honeycomb hexagonal lattice (Fig. 3). This placement of the filter elements 2 also allows you to use their maximum number on a circular area in the cross section of the housing, creates an equal load on each filter element 2 and, as a result, the equal performance of the filter elements with any coordinate in the filter device.

In the filtering mode, through the open pipe 17, the purified water enters the lower part of the housing below the tube plate 3. The pipes 9-14, 16, 18 are closed. Water passes through the mesh layers of the filter elements 2 with a sequential increase in the fineness of cleaning and through the central channel 27 of the inner cylindrical cartridge enters the upper zone 28 and is discharged through the pipe 15 of the drain of clean water. In areas above the tube plates 3, 4, 5 there is water with a different degree of purification, but there is no water movement, since each multilevel zone communicates only with the internal volumes of cylindrical cartridges with the same filter mesh and the nozzles of these zones are closed.

The washing mode of the filter elements can be determined, as in the known filters, using a differential pressure sensor or pressure relief at the outlet of any of the central channels 27.

In the washing mode, the pipes for supplying purified water 17 and drainage of clean water 15 are closed. The washing procedure is carried out separately for a set of cylindrical cartridges fastened to one partition.

The washing mode begins with cylindrical cartridges with a filter mesh with the smallest mesh size and fastened to the last pipe plate 6. In this mode, pipe 15 is opened with reverse supply of clean water to the upper part of the casing above pipe board 6 and the pipe for draining water 12 is opened. Rinsing water passes only through the mesh of the inner cylindrical cartridge, then through the gap of the adjacent cartridge it enters the area between 5 and 6 tube plates and is discharged through the nozzle 12. For washing cylindrical cartridges on the tube plate 5, open pipe 9 for supplying washing water and pipe 13 for withdrawing washing water. And further, respectively: for washing cartridges of any level, washing water fills the area above the cartridge mounting plate, and is discharged through the zone and the branch pipe for washing water discharge below the cartridge mounting zone.

In the inventive device, there is a classification of the deposited particles and their layer-by-layer placement in the gaps between the cylindrical cartridges. This significantly reduces the mass of sediment on the surface of the mesh of the inner cartridge with the smallest mesh size, which leads to a longer functioning of this filter layer, to increase the filtration cycle and improve the quality and fineness of water purification. Reduces the time and energy required to clean the filter device. The separation and removal of sediment is carried out more efficiently due to their layer-by-layer removal. Since washing is carried out on one layer of the mesh, the pressure of the washing water can be reduced by 4-5 times, which reduces the power of the pressure equipment used, as well as the pressure on the mesh and the cartridge frame. It is shown that the filtering device includes single-layer cylindrical cartridges that are simple in design and manufacturing and assembly techniques and at the same time have ample opportunities for choosing filtering volumes, including for filtering large volumes of liquid.

Claims (6)

1. A device for filtering large volumes of water, comprising a housing, filter elements located inside the housing, a nozzle for supplying a liquid to be cleaned, a nozzle for discharging the filtrate from the housing, a nozzle for removing sediment after washing the cartridges, characterized in that each filter element is made as one inserted into the other cylindrical cartridges placed between themselves coaxially with a gap, each cylindrical cartridge is formed of a mesh fixed to the outside of the cylindrical frame of vertical ribs, the lower part each cylindrical cartridge is closed by a plug rigidly connected to the cartridge, cylindrical cartridges of each filter element are placed relative to each other with decreasing mesh size in accordance with the direction of filtration from the outside to the inside, and the inner layer with the smallest mesh size forms the central channel of the filter element, in the upper part the casing is equipped with tube boards with holes that hermetically divide the cavity of the casing into different level zones, and each zone is equipped with at least two I have nozzles with valves for supplying and discharging water, while any hole on the tube plates is made coaxially with the corresponding holes of other levels, cylindrical cartridges made of mesh with the same cell size are fixed in the holes of one tube plate, while cylindrical cartridges are fixed on the bottom board with the largest size of the mesh cells, and on each next level board fixed cylindrical cartridges with a sequential reduction in the size of the mesh cells, while filtering the cylindrical cartridges of one The element is mounted coaxially on the tube plates, and the set of filter elements is housed in the housing to ensure equal distance from each other, while the upper part of each cylindrical cartridge is fastened to the tube plate by means of a tight connection. 2. The filtering device according to claim 1, characterized in that positioning elements are placed in the gap between the cylindrical cartridges to ensure the coaxial position of the cylindrical cartridges forming one filter element. 3. The filtering device according to claim 1, characterized in that positioning elements are placed in the gap between the cylindrical cartridges to ensure the coaxial position of the cylindrical cartridges in the form of coil springs. 4. The filtering device according to claim 1, characterized in that the frame of the cylindrical cartridges is made of vertical ribs in the form of either rods or round or tape rods. 5. The filtering device according to claim 1, characterized in that the upper part of each cylindrical cartridge is fastened to the tube plate by means of either a threaded connection, or an adhesive connection, or by welding. 6. The filtering device according to claim 1, characterized in that the filtering elements are placed in the housing with equal distance from each other and with the housing of the filtering device, at least in accordance with the layout topology of the elements in terms of six-beam symmetry in the nodes and center honeycomb hex grid.

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