RU2710196C1 - Cartridge filter element and filter using cartridge filter element - Google Patents

Abstract

FIELD: water and air purification technology.

SUBSTANCE: invention relates to design of filter elements and can be used for fine water purification. Cartridge filter element comprises a filtering surface fixed on the frame, which is formed by laying along a spiral of stainless wire of triangular cross-section with a filtering slot between turns of wire, the filter element is multilayered; frame of each filter layer includes rigidly installed vertical rods from stainless steel, between which there are installed, except for the last layer, wave-like or zigzag wire elements with cross-section of the same standard size as vertical rods, with possibility of volume separation between vertical rods into separate cells, on the external surface of the frame of each filtering layer a filtering surface is rigidly fixed by way of triangular/trapezoidal section stainless steel along the spiral with a filtering slot between turns of the wire with expansion of the slot in the filtration direction, all filtering layers including a frame and a filtering surface from a triangular/trapezoidal wire are placed in the cartridge coaxially with a gap between layers, sufficient for assembly of layers without tension, at least with a gap of not more than 1/20–1/10 of thickness of the filtering layer, standard size of the wire and size of the filtering layer slit are reduced in subsequent layers in the filtration direction with observance of the condition, at which the slot is up to 1/6–1/5 of the size of the triangle/trapezium base in the wire cross-section, wherein with reduction of filtering slot size, wire height is not reduced to provide structural strength and reliability of layer, and ratio between wire width and height is changed, as well as to provide a "slot:wire laying ratio" ratio of at least 0.20, a slot in the last filtering layer in the filtration direction has a size to provide a given refining fineness, at least technologically achieved value of 0.010–0.005 mm, and the size of the slot of the previous layers is reduced from the outer layer to the subsequent layers either by linear relationship or according to the functional relationship between the particle size and weight in the volume of the purified water, inner surface of last layer with least slot between turns of wire forms cleaned water outlet channel, wherein the channel cross-section along the cartridge axis exceeds the total live cross-section of the filter slots in the last layer in the filtration direction, wherein the outlet channel cross-section is selected based on the condition that the channel flow rate is not more than 1 meter per second with provision of the laminar water flow mode in the output channel, each filter layer is closed from above and from below by end circular plugs, and cartridge as a whole in lower part is closed by plug, which is made integral with plug, which is aligned without interference with inner surface of outlet channel, and in upper part cartridge is equipped with sealed cover with branch pipe for purified water outlet, equipped with means of installation and attachment of cartridge in working vertical position in filtered medium.

EFFECT: increased fineness of cleaning with simultaneous increase of surface of filtering layer, and consequently, and efficiency of cleaning, reduced time for filter cleaning and regeneration, increased cycle time between regenerations of filter due to arrangement of space for sediment placement.

6 cl, 9 dwg

Description

The invention relates to the design of filter elements and can be used for fine water purification.

Known cartridge filter element according to the patent on PM 127654, IPC B01D 29/48. A cartridge filter element comprising a tubular frame with perforations in the form of slots, on the surface of which a filter membrane is placed. The slots are covered with slotted metal plates or in the form of flat frames, or in the form of a sector part of a longitudinally cut cylinder. The surface of the pads is formed by pieces of wire with a triangular or trapezoidal section, fixed by welding with a fixed gap. The wires are laid and fastened one of the triangular peaks down to the surface of the tubular frame. Slit pads can correspond to the size of the slots and are attached directly to the slots, and if the dimensions exceed the dimensions of the slots, then they are mounted on top of the slots.

Disadvantages: low productivity, at least because of the small area of perforations in the form of slots on the tubular frame, the design of low technology due to the individual mounting of the filter frame for each slot. The filter element does not provide fine cleaning; it allows laying the wire in increments of 0.2 mm or 0.4 mm.

Known filter element according to the patent on PM 160446, IPC B01D 29/00. The filter element contains a power frame made of rods located along the generatrix of the body of revolution, in particular along the generatrix of a cylindrical or conical surface, and a filter shell fastened with it, made in the form of a wire wound around the power rods at a certain step and welded with them to form cracks for filtering the surface of the wire of the filter shell from the intake side of the filtered substance contains filter channels connecting the slots located between adjacent turns of wire.

The wire of the filter sheath is made in the cross section of a polygonal shape, in particular triangular, with one of the ribs of the wire connected by welding to the power frame, filter channels are located on the opposite edge of the wire of the wire. The filter channels are made expanding in the direction of flow of the filtered fluid.

The disadvantages include the insufficient performance of the filter element when solving the problem of fine cleaning, which requires the manufacture of very small filter channels, which reduces the cross-section.

The closest in purpose and design of the cartridge filter element is the invention according to the patent of the Russian Federation No. 2229795, IPC A01J 9/02, B01D 29/48. According to the description, the filter contains a sealed detachable housing with nozzles for entry and exit and a cartridge filter element. The filter element is made of two stages and consists of coarse and fine filters, mounted on a common base, one in the other. The inlet pipe is made in the form of a pipe passed through a filter element into a cavity located between the bottom of the housing and the cover of the outer filter cartridge. Each cartridge is a frame on which a spring is made of stainless steel wire of triangular cross section with a filtering gap between the coils of the spring. The filtering surfaces of the cartridges differ from each other by the size of the filtering slots. The filtering surface of the fine milk cartridge has a filter slit of 0.07 mm, and the filtering slit of the coarse cartridge is 0.140-0.180 mm, i.e. the ratio of the filter slots of the first and second stages of cleaning is made equal to not more than 2.5: 1. Each cartridge is equipped with a sealed cap fixed to the tail of the inlet pipe with a nut. To ensure the sealing of the joint between the glass and the base of the body, a gasket is introduced into the structure. Parts of the housing are interconnected by a quick-detachable connection. At the end of the work, the housing due to the presence of a quick-detachable connection is easily disconnected from the base, unscrewing the nuts, remove the coarse and fine cartridges and perform sanitary-hygienic washing of the filter parts.

The disadvantages of this filter are that it does not provide sufficiently fine cleaning (0.07 mm), and with an increase in the degree of purification it does not provide the necessary performance. Performance is also underestimated due to the cleaning of the filter by manual disassembly and washing, which increases downtime.

Known filter designs using blocks of cartridge filter elements.

A well-known alluvial filter (see AS Kopylov, EI Verkhovsky. Special water treatment at nuclear power plants. - M .: Higher school, 1988. - S. 141). The filter is made of stainless steel with a diameter of 0.4-1.2 m and a filtering surface area of 2-25 sq.m. The wash filter consists of a cylindrical body, a conical or spherical bottom and a removable spherical cover. Cylindrical filter elements are fixed on a tube plate located between the housing and the cover. The filter elements are a perforated tube with a threaded thread for spacing the wound wire. The thread pitch and wire diameter are selected such that the gap between the turns does not exceed 0.1 mm. Pipes are welded to the filter for supplying and discharging water. During the working cycle, its performance is monitored, preventing its decrease by more than 50% in order to avoid sliding of the alluvial filter layer from the cartridges. Flushing particles from the surface of the cartridges is carried out by water hammer. In operating mode, the filter allows 30-50 regeneration cycles. In the specified filter insufficient filter performance and fineness of cleaning.

Known cartridge filter according to patent RU 2396103, IPC B01D 27/08 for fine highly efficient cleaning of liquids from mechanical impurities. The cartridge filter contains a housing divided by a tube plate into the upper and lower chambers, filter cartridges with protective cases, fixed with open ends in the tube plate and mounted vertically, nozzles with valves. The protective cases are located in the upper chamber, which is the source fluid chamber, made of sealed material with open ends, both lower, fastened to the tube plate and upper, bonded to the upper open ends of the filter cartridges, the lower open ends of which are connected to the second tube plate, made of permeable material located below the outlet pipe and separating the lower chamber, which is the chamber of the purified liquid, from the lower part of the upper chamber of the original liquid, which is connected nene with its lower part using internal hollow cylindrical channels of filter cartridges.

The filter is characterized by the duration of the filter between preventive measures, however, the indicated duration is insufficient due to the fact that mechanical impurities settle on the inner surfaces of the filter cartridges and move in the filtration mode by the flow of the initial liquid to the lower part of the upper chamber of the initial liquid, but such cleaning is ineffective.

Known filter apparatus according to the patent of Russian Federation 2668867, IPC B01D 29/11 for use in the chemical, oil refining, metallurgical industries for cleaning various liquids (gases) from pollution, the closest to the claimed filter in essence.

The filter apparatus comprises a cylindrical housing, as shown in FIG. 2 descriptions to 2668867, divided by a partition (the so-called tube plate) into the lower and upper chambers. On the partition from the upper chamber, threaded pipes are installed to which the filters are attached. The detachable threaded connection of the filters allows you to place a large number of filters. Access to threaded pipes is due to the plug connection of the plug (cover role) with the housing. Filters include a cylindrical perforated frame with a closed upper end, a filter element placed on the inner surface of the frame, and the second end of the frame sealed to a cylindrical sleeve with an internal thread, with which the filters are mounted on the nozzles. The thread tightening device is located on the closed end side. The apparatus provides ease of installation (dismantling), parallel operation of a large number of filters, reduction of the dimensions of the apparatus. However, the apparatus does not provide for the regeneration of filters, but only their replacement, which reduces the durability of the filter and its performance. The subtlety of cleaning is insufficient, since an increase in the subtlety of cleaning with constant productivity is possible only with a significant increase in the size of the apparatus of this design, as well as insufficient sludge capacity of one layer of the filter element.

The technical task of the invention is that

- to increase the fineness of cleaning with a simultaneous increase in the surface of the filter layer, and hence the cleaning performance,

- reduce the time for cleaning and regeneration of the filter,

- increase the cycle time between filter regenerations due to the organization of space for sediment placement.

Note hereinafter: the term “wire of triangular section”, “base of triangle”, “triangular wire” should be understood including “wire of both triangular and trapezoidal section”, “base of triangle or base of trapezoid”, “triangular or trapezoidal wire "in view of the manifestation of identical properties of these concepts in relation to the application materials.

Declares:

A cartridge filter element comprising a filter surface fixed to the frame, formed by spiral laying a triangular section stainless steel wire with a filter gap between the wire turns, characterized in that

- the filter element is multilayer,

- the frame of each filter layer includes rigidly installed vertical stainless steel rods, between which, with the exception of the last layer, wave-like or zigzag wire elements with a cross section of the same size as the vertical rods are installed, with the possibility of dividing the volume between the vertical rods into separate cells ,

- on the outer surface of the frame of each filter layer, the filter surface is rigidly fixed by laying in a spiral spiral stainless steel triangular section with a filter gap between the coils of the wire with the expansion of the gap in the filtration direction,

- all filter layers, including the frame and the filter surface of a triangular wire, are placed in the cartridge coaxially with a gap between the layers sufficient to assemble the layers without interference, at least with a gap of not more than 1 / 20-1 / 10 of the thickness of the filter layer,

- the wire size and the size of the slit of the filter layer are reduced in subsequent layers in the filtration direction, subject to the condition under which the gap is up to 1 / 6-1 / 5 of the size of the base of the triangle in the cross section of the wire, and with a decrease in the size of the filter slit, the wire height does not decrease for ensuring structural strength and reliability of the layer, and the ratio between the width and height of the wire is changed, and also to ensure the relationship "slot size: wire laying pitch", at least up to 0.20,

- the gap in the last filtering layer in the filtration direction has a size with the specified cleaning fineness, at least a technologically achievable value of 0.010-0.005 mm, and the gap size of the previous layers decreases from the outer layer to subsequent layers either linearly or in accordance with the functional the relationship between the size of the particles and their mass in the volume of purified water,

- the inner surface of the last layer with the smallest gap between the turns of the wire forms the outlet channel for purified water, while the channel cross section along the cartridge axis exceeds the total living section of the filter slots in the last layer in the filtration direction, and the outlet channel cross section is selected from the condition of the flow rate in the channel no more 1 meter per second with the provision of a laminar flow of water in the output channel,

- each filter layer is closed at the top and bottom with end ring plugs, and the cartridge as a whole at the bottom is closed with a plug made at the same time as a stopper, which is combined without interference with the inner surface of the outlet channel, the cartridge in the upper part is equipped with a sealed cover with a pipe for the outlet of purified water, equipped with means for mounting and fixing the cartridge in a working vertical position in a filtered medium, for example, in the form of a threaded connection, including an outlet channel with an external thread and a nut. The caps and caps of the cartridge filter element are connected to the cartridge either rigidly by welding, or by means of a collapsible threaded connection.

The cartridge filter element is used in the design of the inventive filter.

A filter using the inventive cartridge filter element, comprising a cylindrical body with water supply and drain pipes, separated by a partition on the lower purified water supply chamber and the upper purified water discharge chamber, a sealed housing cover, filter elements fixed to the partition, characterized in that

- filter elements are made in the form of the claimed above cartridge filter elements,

- cartridge filter elements (hereinafter also cartridge filter elements) are placed vertically in the working position in the lower chamber and hermetically fastened to the baffle, while the filter elements are arranged to provide communication channels for the outlet of purified water of the filter elements through their nozzles with the upper chamber for removal of purified water,

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

- nozzles for supplying purified water and drainage of purified water to the filter housing are equipped with shutoff valves with the possibility of periodically reversing the regime of supplying purified water to the upper chamber and drainage of purified water from the lower chamber.

Cartridge filter elements can be fastened to the baffle by means of either a threaded connection, or an adhesive joint, or by welding, which perform similar functions for the purpose of sealing the filter elements on the baffle.

The invention is illustrated by the figures:

in FIG. 1 - sectional filter element;

in FIG. 2 is a diagram of the arrangement of the filter layers in the cross section of the cartridge filter element,

in FIG. 3 is a view of the frame in each layer and an illustration of the sludge capacity,

in FIG. 4 is a graph of the mass distribution of particles in a liquid according to the normal-logarithmic law;

in FIG. 5 and 6 - illustration of the sludge capacity of the filter layers of the same height / thickness and different heights / thickness depending on the fractions of the particles;

in FIG. 7 - dependence of the thickness of the filter layer on the mass of trapped particles;

in FIG. 8 is a sectional view of a filter with a block of cartridge filter elements,

in fig. 9 is a plan of the topology of the filtering elements in plan in the nodes of the hexagonal lattice.

The cartridge filter element is a slotted filter (shpaltovy) element made of stainless steel wire of triangular cross section with a filter gap between the turns of wire. The most commonly used grades for slotted bobbin screens are AISI 304 steel grades (10X18H9, 08X18H10); AISI321 (12X18H10T, 08X18H10T); AISI 316L (03X17H14MZ).

The proposed filter element 1 is multilayer and consists of several slotted filter layers. Each filter layer 2 contains a rigid frame 3 made of stainless steel. The frame is formed by vertical rods 4 in the form of forming a cylindrical surface, and between them are installed, for example, wave-shaped or zigzag wire elements 5 (hereinafter for simplicity, a zigzag wire) with a cross section of the same size as the vertical rods, and welded to the rods 4, and not extending beyond the cylindrical surface of the rods 4. The zigzag wire 5 allows you to divide the area between the vertical rods into separate cells 6, which in the filtering mode will perform Only pockets for collecting sediment. There are no wavy or zigzag wire elements in the last filtering layer, because after passing the last sieve with the smallest size of slots, there is no sediment in the water (or finer than the specified value).

On the outer surface of the frame 3 of each filter layer 2, a slotted smooth filter surface 7 is formed. It is manufactured on modern automatic machines (one of the many offers from HEBEI OUKER WIRE MESH EQUIPMENT CO., LTD, China) by spiral laying of stainless steel wire 8 triangular or trapezoidal section with a filtering gap 9 between the turns of wire with the expansion of the gap in the direction of filtration. The wire is welded to the rods 4 at all intersection points. A characteristic advantage of the manufacture of slotted filtering surfaces is the very high accuracy of laying of wire 8 with guaranteed tight tolerance on the size of the gap between adjacent turns of wire. Next-generation profiling machines provide surface quality and high precision triangular wire geometry - up to 15 microns (0.015 mm) depending on needs.

An important indicator of the effective use of filters, in particular a slit filter, is the filter’s living cross-section coefficient as the ratio of the total area of the filter slots 9 between the wires to the area of the entire filter surface 7. A small ratio indicates the need to increase the dimensions of the filter and reduce the cleaning performance. According to the claimed cartridge filter element, the filtering slot in the layer 10, in the latter in the filtration direction, has a size of 0.010-0.005 mm, corresponding, on the one hand, to the specified cleaning fineness, and, on the other hand, the specified size is at least technologically the achieved value, and the filtering surface with such a gap can be implemented in modern conditions. With such small values, a satisfactory coefficient of living cross-section can be obtained using also a small cross-section for winding a triangular wire, for example, 0.02 mm. Currently known in practice, the standard sizes of a triangular wire have a certain widespread cross-sectional shape, for example, a narrowing angle of 7 ° -8 ° from the base of the triangle to its apex. A wire with such a cross section and small size cannot provide the structural strength of the filter layer and technological methods for winding it. According to the claimed invention, to create a cartridge filter element of high fineness and high performance per unit volume of the filter element, it is proposed to use a wire in which the size of the base of the triangle in cross section is 4-5 times larger than the specified filter gap, but the wire height does not decrease with decreasing the width of the slit and is selected sufficient to ensure structural strength. It is proposed that the width of the slit tends to 1 / 6-1 / 5 of the width of the wire, with a different ratio, the dimensions increase, and the live section decreases. Also, the optimal ratio “slot width: wire laying pitch” of at least 0.20 was obtained by calculation.

All filter layers 2, including the frame 3 and the smooth filter surface 7 of the triangular wire 8 welded to the frame, are placed in cartridge 1 coaxially with a gap 11 between the filter layers, sufficient to assemble the layers in the cartridge without interference, at least with a gap of no more 1 / 20-1 / 10 of the thickness of the filter layer 2. In the cleaning mode, the purified water and the filter cake are distributed in this area of the frame 12. The thickness of the filter layer is the thickness of the rods 4 of the frame and the height of the triangular wire mounted on the frame 8. Typically the size of the wire and the filter slit 9 are reduced in subsequent layers in the direction of filtration. The filtering gap in the last layer 10 in the direction of filtration is selected by the developer from the condition of ensuring the necessary fineness of cleaning. As shown above, when receiving drinking-quality water, the gap size in the last layer is set to 0.010-0.005 mm, and the gap sizes of the previous layers decrease from the outer layer to the next layers either linearly or in accordance with the functional relationship between the particle size and their mass in volume of purified water. For example, with a linear relationship: the size of the slit of the 1st layer is 0.05, the last layer is 0.005 mm, the filter layers are 5, the parameters of the slits of the first and subsequent adjacent filter layers of the layers are 0.05-0.025-0.015-0.010-0.005 mm.

The principles of constructing a multilayer cartridge and calculating the height of the filter layers is illustrated by figures 4-7, where d _i and f _i are the particle size of the i-th fraction and their relative mass in the treated water; h _{i is the} height of the i-ro filter layer 2. In FIG. Figure 4 shows the dependence of the distribution of solid particles in a liquid according to the normal-logarithmic law, where it is shown that particles of an average fraction of 5-15 μm make up 60-70% of the mass of all particles. This mass must be filtered, for example, by the second and third layers. Accordingly, the height of the second and third layers is designed to accommodate the mass of particles of this fraction in the pocket cells 6. In FIG. 7 shows a proportional relationship, where the height of the frame of the i-th filter layer is greater, the greater the relative mass of the i-th fraction captured by this layer. When implementing a cartridge filter element, where the height of each layer 2 corresponds to the mass of screened particles by this layer (shown in Fig. 6), approximately the time filling of the pocket cells is ensured due to the not identical sludge capacity. In general, this leads to a significant increase in the filter cartridge productivity due to an increase in the cycle time between filter regenerations due to the organization of space for sediment placement. In practice, technological complications of the design in the form of design and implementation of filter layers of different heights in justified cases can be recognized as impractical and satisfactory can be recognized as a variant of the cartridge filter element with filter layers of the same thickness. With a linear decrease in the slots to the last layer in the direction of filtration, the working load on the filter layers is not the same (Fig. 5) and the productivity and cycle time of the filter element regeneration will slightly decrease compared to the above described mode, but the manufacturing and operation costs will decrease.

The inner surface of the last layer 10 with the smallest filter slit forms a purified water outlet channel 13, while the channel cross section along the cartridge axis exceeds the total living section of the filter slots in the last layer 10. The output channel cross section is determined from the condition of the flow velocity in the channel not more than 1 meter per second . At this speed, the water in the outlet channel 13 does not exit the laminar flow regime.

Each filter layer 2 of the cartridge 1 is closed from above and below by end ring caps 14 to ensure a tight fit of the caps on the ring layer 2 and to isolate the internal volumes of all filter layers 2 from each other. The cartridge as a whole in the lower part is closed by a plug 15, made at the same time with a plug 16, which is compatible without interference with the inner surface of the output channel 13. The plug supports the coaxial position of the vertical rods 4 of the frame 3. The upper part of the cartridge 1 is closed by a sealed cover 17 with a cleaned outlet 18 water. The caps and caps of the cartridge filter element 1 can be connected to the cartridge either rigidly by welding (pos. 19 of Fig. 1), or by means of a collapsible threaded connection (not shown in the figures). In the working position, the cartridge 1 is installed and fixed in a container with a filtered medium 20 vertically, and for this purpose the nozzle 18 is equipped with means for mounting and fixing the cartridge in a working vertical position in the filtered medium, for example, by means of a thread on the nozzle, nut and sealing materials.

The filtering process using the inventive cartridge filter element 1 is as follows.

The liquid to be cleaned sequentially passes the filter layers from the outer layer to the output channel 13 along the axis of the cartridge filter element. Particles 12 settle on a smooth filtering surface 7 without creating a dense sedimentary layer, since due to the expansion of slots 9 in the filtration direction, particles do not accumulate between adjacent faces of the coils due to an increase in the distance between them in the direction of water flow. The number of filter layers and the absence of material of the auxiliary filter load increases the allowable volume of the sediment layer by 100-200 times, and therefore the filtration cycle time is significantly increased.

In the gap 11 between the filter layers, the particles 12 are freely moved by the fluid flow. However, thanks to the pocket cells 6 formed by the zigzag wire 5, the sediment 12 is accumulated and retained in each layer and uniformly on the surface 7 of a separate layer, including the vertical working orientation of the cartridge, which increases the stability of the filtration process over the entire surface and the time work. Moreover, the sediment is also classified by size in accordance with the dimensions of the slots 9 in each layer. When washing the cartridge filter element 1 with countercurrent water, the precipitate 12, evenly distributed on the surface, is free, simultaneously throughout the volume and therefore quickly passes through the gap intervals of the previous layer. The regeneration time of such a filter in comparison with the known ones is significantly reduced by 5-10 times.

The filter using the inventive cartridge filter element contains a cylindrical housing 21, separated by a baffle 22 on the lower chamber 23 of the purified water supply and the upper chamber 24 of the purified water outlet, the sealed housing cover 25, the filter elements 1 fixed to the partition by means of a threaded connection, the supply and exhaust pipes water 26 and 27, respectively. The filtering filter elements are made in the form of the specified claimed cartridge filter elements 1.

Cartridge filter elements 1 are placed in the lower chamber 23 and hermetically fastened to the baffle 22, for example, by means of a threaded connection, including a pipe 18 of the outlet channel of the cartridge filter element with an external thread and a nut (the threaded connection and sealing materials are not shown in detail in the figures as well-known). The pipe 18 provides communication channels 13 of the outlet of the purified water of the cartridge filter elements 1 with the upper chamber 24 of the outlet of the purified water. The filter elements can be fastened to the partition not only by means of a threaded connection, but also by means of either an adhesive connection or by welding, which perform similar functions for the purpose of hermetically installing the filter elements on the partition. It is advisable to place the cartridge filter elements in the volume of the filter housing 21, ensuring equal distance from each other and between the filter housing and the cartridge filter elements 1. This advantageous solution corresponds to the layout topology of the elements in plan in the nodes and in the center of the honeycomb hexagonal grating, and the arrangement of cartridges is illustrated FIG. 9. The placement of cartridges in the nodes of the hexagonal lattice allows you to use the maximum number of objects (cartridge filters) in a circular area in the cross section of the filter and ensures uniform distribution throughout the filter volume of the flow rate of the purified water, equal load on each filter element as a whole and the area of its outer cylindrical surface and, as a result, equal performance of filter elements with any coordinate in the filter. The filter operates as follows.

The cleaned water enters the closed volume of the lower chamber 23 of the filter through the pipe 26. The water velocity in the section between the cartridges is not more than 1 m / s in order to avoid turbulence and turbulence. The purified water passes through the multilayer structure of the cartridge filter elements and through the internal outlet channels 13 enters, acquiring practically drinkable quality, into the upper chamber 24. The filtered precipitate 12, divided by size in accordance with the size of the slit 9 in each layer 2 in the laminar flow mode, is held on the surface of the layer and at the same time is evenly distributed on the vertical surface of each layer inside cells 6. In contrast to the known filters, in which the performance decreases due to the formation of a washable filter layer of a heterogeneous and dense structure, and mainly near the filtering surface, in the proposed filter, the precipitate is divided into fractions, distributed not on the surface of the filter element, but uniformly throughout the volume. The manufacture of a mesh frame made it possible to increase the sludge capacity of the cartridge filter elements and the filter with their use by at least two orders of magnitude. Also, due to the location of the sediment evenly in volume and in the layers of cartridges, the time for filter regeneration by supplying washing water is significantly reduced, and the reduction in downtime can increase the filter performance.

In order to regenerate the nozzles 26, 27 for supplying purified water and for removing purified water, they are equipped with shutoff valves with the possibility of periodically reversing the supply of purified washing water through the nozzle 28 to the upper chamber and for removing the washing water from the lower chamber through the nozzle 29.

In the proposed filter, the fineness of water purification is achieved not only due to the use of a filter layer with the minimum achievable slot size. But also in connection with the screening by each layer of sediment of a certain fraction, and at the same time, in each layer the maximum volume for the placement of sediment is organized. For example, a cartridge of five filter layers functions as five separate filters for a specific sediment. The filter load does not fall on the first 1-2 layers, but is evenly distributed over all filter layers. This increases the period of functioning of the cartridge filter element, during which a live section is stored in each layer.

The proposed filter provides high fineness of water purification, is characterized by increased sludge capacity, provides increased cleaning performance. The filter allows to reduce the time for cleaning and regeneration of the filter, to increase the cycle time between regenerations of the filter due to the organization of space for the placement of sediment.

The cartridge filter element and the filter using such a cartridge filter element can be made on the basis of known materials and equipment, including using a triangular wire of the desired cross section.

Claims (6)

1. The cartridge filter element containing a filter surface fixed to the frame, formed by spiral laying of a stainless steel wire of triangular cross section with a filter gap between the turns of wire, characterized in that the filter element is multilayer; the frame of each filter layer includes rigidly installed vertical stainless steel rods, between which, with the exception of the last layer, wave-like or zigzag wire elements with a cross section of the same size as vertical rods are installed, with the possibility of dividing the volume between the vertical rods into separate cells, on the outer surface of the frame of each filter layer, the filter surface is rigidly fixed by spiraling stainless steel triangular o / trapezoidal section with a filter gap between the coils of the wire with the gap widening in the direction of filtration, all filter layers, including the frame and the filter surface of a triangular / trapezoidal wire, are placed in the cartridge coaxially with a gap between the layers sufficient to assemble the layers without interference at least with a gap of not more than 1 / 20-1 / 10 of the thickness of the filter layer, the wire size and the size of the slit of the filter layer are reduced in subsequent layers in the direction of filtration, subject to the condition under which b is up to 1 / 6-1 / 5 of the size of the base of the triangle / trapezoid in the cross section of the wire, and with a decrease in the size of the filter slit, the height of the wire does not decrease to ensure structural strength and reliability of the layer, but the ratio between the width and height of the wire changes, as well as ensuring the ratio “gap: wire-laying step” to at least 0.20, the gap in the last filter layer in the filtration direction has a size with a given cleaning fineness, at least a technologically achievable value of 0.010-0.00 5 mm, and the gap size of the previous layers decreases from the outer layer to the subsequent layers either linearly or in accordance with the functional relationship between the particle size and their mass in the volume of water being cleaned, the inner surface of the last layer with the smallest gap between the turns of the wire forms an exit channel purified water, while the cross-section of the channel along the axis of the cartridge exceeds the total living cross-section of the filter slots in the last layer in the direction of filtration, and the cross section of the outlet channel is selected from the condition that soon the flow in the channel is not more than 1 meter per second, ensuring the laminar flow of water in the output channel, each filter layer is closed at the top and bottom with end ring plugs, and the cartridge as a whole at the bottom is closed with a plug made at the same time as a stopper, combined without interference with the inner surface of the outlet channel, and in the upper part of the cartridge is equipped with a sealed cover with a pipe for the outlet of purified water, equipped with means for installing and fixing the cartridge in a working vertical position in a filtered medium. 2. The cartridge filter element according to claim 1, characterized in that the caps and caps of the cartridge filter element are connected to the cartridge either rigidly by welding, or by means of a collapsible threaded connection. 3. The cartridge filter element according to claim 1, characterized in that the means for installing and securing the cartridge in the working vertical position in the filtered medium is made in the form of a threaded connection, including an outlet channel with an external thread and a nut. 4. A filter using a cartridge filter element, comprising a cylindrical body, separated by a partition on the lower chamber of the purified water and the upper chamber of the purified water, a sealed housing cover, filter elements mounted on the partition, nozzles for the inlet and outlet of water, characterized in that the filter the elements are made in the form of cartridge filter elements according to paragraphs. 1-3, the cartridge filter elements are placed vertically in the working position in the lower chamber and hermetically fastened to the baffle by means of a threaded connection, including an outlet channel with an external thread, while this nozzle provides communication of the purified water outlet channels of the cartridge filter elements with the upper outlet chamber of the cleaned water, cartridge filter elements are placed with equal distance from each other and between the filter housing and cartridge filter elements, pat ki treated water supply and discharge treated water are provided with stop valves to perform periodic reversal feeding mode of purified water to the upper chamber and discharging the treated water from the lower chamber. 5. The filter according to claim 4, characterized in that the layout topology of the cartridge filter elements in the plan forms in aggregate a honeycomb hexagonal grid. 6. The filter according to claim 4, characterized in that the cartridge filter elements can be fastened to the baffle by means of either a threaded connection, or an adhesive connection, or by welding.

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