RU2159142C2 - Combined water-purifying filter - Google Patents

Abstract

FIELD: industrial purification of water. SUBSTANCE: proposed filter has housing equipped with supply and discharge pipe lines, granular medium and flushing system; filter consists of at least two sections connected in series where granular medium and filter elements are arranged. Filter elements are made in form of screen cones whose vertices are directed towards moving flow of starting water; size of mesh of each subsequent cone is lesser than simplified and low-cost method of manufacture of filter; enhanced durability. 14 cl, 5 dwg

Description

 The invention relates to industrial water treatment with the help of special devices installed in plumbing and heating collectors at the entrance to residential buildings and industrial buildings.

 Known device filters [1,2,3] containing a filter element made of perforated material, made in the form of hollow cones with sharp needles, rounded (spherical), or with truncated vertices, the bent base of which is hermetically fixed inside the annular element with a central hole or with covers. In this case, the purified water is supplied to the top of the filter element.

 The disadvantage of these devices is their functional limitation, since the filter can only be used for mechanical cleaning of liquids from macroinclusions.

 Known devices for cleaning liquids of housing and pipe filters [4,5,6], comprising a housing in the form of a section of a pipe or cylinder of a closed type with inlet and outlet pipelines, filter elements in the form of cylinders, hollow mesh cones or truncated pyramids interconnected by bases with the aim of increasing the filtering surface, washing and cleaning devices in the form of tubular forks with nozzles, trays and conical spirals placed along the inner generatrix of the cone, equipped with a rotation drive and a pat ubkom been cleared off for removal of contaminants.

 The disadvantage of these devices is the structural complexity and high cost of manufacture, as well as their functional limitations, since they are also intended only for mechanical cleaning of liquids from macroinclusions, and in these devices the liquids to be cleaned are fed into the internal cavity of the cones, which makes it difficult to remove contaminants.

 In the known filter [7], comprising a housing, inlet and outlet nozzles, a filter element and a flushing valve, a bypass device is patented, in fact, in the form of an additional pipeline with a shut-off element connecting the inlet and outlet pipes equipped with taps installed after the additional pipeline.

 The disadvantage of this filter is that the necessary and very frequent flushing of the filter element is carried out at a non-working pump unit, which significantly reduces the filter performance and its operational reliability.

 A known filter for cleaning liquids [8], divided by a transverse partition into sections of the first and second stage with different loading for sequential filtering, is equipped with supply and discharge pipelines, drainage and washing systems and a chute for collecting intermediate filtrate and washing water located along the filter in the opening the upper part of the dividing wall and having bottom holes, overlapped with grids with mesh sizes smaller than the particle sizes of the granular loads.

 The disadvantage of this filter is the bulkiness of its design, which requires large production and installation areas, as well as the need to use a complex multi-level drainage system.

 Known filters for cleaning liquids [9,10], containing a cylindrical body with granular loads, drainage distribution systems in the form of perforated pipes, nozzles for supplying and discharging the source and purified water, as well as special devices for the directed movement of the source liquid when filtering through the appropriate grainy loading. Such devices can be thin-walled cylindrical partitions, coaxially placed in housings filled with appropriate loads, consisting of an upper cylindrical part with holes (windows) rigidly connected to the housing cover and a lower conical part attached to the bottom of the housing with its large base, or in the form a system of pipes coaxially inserted one into the other, where the outer pipe connected to the inlet is perforated and plugged at the bottom, and the second pipe of a smaller diameter is inserted coaxially into the first pipe with an end gap, it is sealed at the top and communicated with radial perforated branches extending horizontally through the walls of the outer pipe, where they are hermetically fixed by welding. When the filter [10] is turned on, the initial fluid enters through the inlet pipe through the distribution system to the bottom of the filter bounded by the conical surface and is filtered from bottom to top through the loading of this zone, and then through the windows it enters the loading placed between the conical surface and the housing, and filtered from top to bottom. The purified water is taken by the drainage system and discharged through the outlet pipe. When the filter [9] is turned on, the source water, passing through the annular gap between the pipes, leaves the perforation holes of the outer pipe in the granular charge of the filter zone I and at the same time enters an additional pipe through the end gap, and is fed from above into the perforation holes of the radial outlets loading of the II zone and, having passed the filtration together with purified water of the I zone, is removed from the filter.

 A significant drawback of these filters is the lack of preliminary mechanical cleaning of the source water, which brings all inclusions directly to the granular charge, which is either not provided for at all or is difficult to wash, since the washing of the entire loading layer is carried out by supplying washing water to the lower loading layer, and the washing out contaminated water through the upper nozzle in the filter cover. A significant disadvantage of filters should also include the fact that the washing process of the filter requires its mandatory stop.

 A known filter for cleaning liquids [11], which can be used both for the purification of tap water, and in other industries where it is necessary to have clean water free of metal salts and organic soluble impurities. It contains at least two cylindrical bodies connected to each other, in one of which there is a charge from an ion-exchange resin, and in the other a charge from activated carbon. The load in each case is placed in polyethylene insulating sleeves, on the ends of which support grids are fixed, the last of which are clamped, and ring protrusions are made on their lateral surfaces, having a cross-section in the cross section, the ratio of the cross-section radius of which to the average grain size of the load is value 3 - 5.

 Such a filter is uneconomical to use for purification of water entering, for example, in heating systems of residential buildings and other industrial buildings. Moreover, the specified filter has a limited service life, since it also does not have means of preliminary mechanical cleaning and a flushing system.

 Closest to the proposed invention is a two-stage pressure filter [10], containing a housing with a granular charge, a drainage distribution system, nozzles for supplying and discharging the source, purified and wash water and coaxially placed in the housing with a granular charge cylindrical partition, the upper cylindrical part of which with holes - windows is rigidly attached to the housing cover, and the lower conical part with its large base is attached to the bottom of the housing.

 The disadvantages of this device are the lack of means for preliminary mechanical purification of the source water, the difficulty of washing thick layers of granular loads, and the need to stop the filter when washing it.

 The aim of the invention is to provide a device that combines a mesh filter elements with a high degree of mechanical purification of water, with granular loads, allowing its clarification, and, if necessary, its desalination, as well as capable of undergoing backwashing with purified water without stopping the cleaning process source water and supplying the consumer with clean water.

 This goal is achieved by the fact that the combined water treatment filter, comprising a housing equipped with inlet and outlet pipelines, a granular charge and a washing system, is made of at least two sections connected in series with each other, in which filter elements in the form of hollow mesh cones are placed, the vertices of which are directed towards the flow of the source water, and the mesh size of each subsequent cone is smaller than the mesh size of the previous cone, remaining unchanged over the entire surface of each of cones, while the last of the cones contains a granular charge, the first of the filter sections is connected to the inlet, and the last to the outlet piping, to which a filter for backwashing it, having a similar design, is connected parallel to the water treatment filter, while the water treatment filter is equipped with a washing a system connected to the outlet pipe of the filter for backwashing, the washing system of the water treatment filter contains a perforated pipe with radial perforations rigidly attached to it ingly taps disposed uniformly over the entire length of the perforated pipe passing through the axis of the cone through the entire thickness of loading.

 This goal is also achieved by the fact that in the combined water treatment filter, the granular load is made of expanded clay or quartz sand, or activated carbon, or anthracite.

 The cones of the filter elements are either acicular, or with truncated or spherical vertices.

 The backwash filter is equipped with a similar device as the water filter, and has a lower capacity.

 An additional goal is the desalination of water according to customer requirements. This goal is achieved by the fact that the water treatment filter is equipped with an additional section containing a granular charge of KU-2-8 h C ionite or equivalent ionite.

 New in this device compared to the prototype is that the clean water discharge pipe of the filter for backwash is at the same time a supply pipe for washing the water treatment filter. As a result, the source water, passing through any of the filters, is supplied to the consumer purified, while ensuring the necessary quality of water and reducing the time of cleaning (rinsing) the filters.

 The consecutive installation of several cones directed by the vertices towards the flow of the source water reduces their contamination, increases the degree of mechanical purification of water, and also increases the service life of the filter, including by increasing the filter surface. The differentiation of the mesh sizes of the cones contributes to the same goal.

 The presence of perforated pipelines with horizontal branches that are evenly distributed over the entire volume of granular loads is a distinctive feature that allows us to solve the problems of a complete and high-quality washing of the loads, since, unlike analogs and prototypes, not pure, but finally purified water is supplied to the perforated pipelines of the proposed filter top to bottom.

 The introduction of a filter for backwashing a water treatment filter made it possible to wash itself through a water treatment filter with clean water without stopping the process of purifying the source water and supplying clean water to consumers is also a hallmark that allows us to solve production and technological problems associated with the need for continuous supply of clean water, and also solve the problems of medical and environmental safety and socio-psychological balance among the population of the regions.

 The essence of the invention is illustrated by drawings, in which a General view of the combined water treatment filter in section with the representation in FIG. 1-3 possible types of filter element designs.

 The filter comprises a housing 1 with a supply 2 and a discharge 3 pipelines, consisting of several filtration sections, in which hollow mesh cones 4, 5, 6 are placed, to the tops of which the source purified water is supplied from the supply pipe 2, and the mesh size of the cones decreases from one to the other, remaining constant on each cone. In the last cone there is a granular load 7. An additional section located above the cone 6 contains a granular load made of KU-2-8 h C ion exchanger, or an equivalent ion exchanger 8 placed in the tank 9. A pipeline passes through the tank 9 and the cone 6 10 connected to a washing system 11 for introducing clean washing water. The washing system 11 contains a perforated pipe 12 with perforated bends 13 rigidly attached to it in an amount of at least four pieces in each of the horizontal planes that are evenly distributed along the entire length of the perforated pipe 12. In parallel to the housing 1 of the water treatment filter, the housing 2 is connected to the inlet 2 and outlet 3 pipelines 14 backwash filters having a capacity smaller than that of the water filter. The outlet pipe 15 of the filter for backwashing is connected to the washing pipe 10 of the water treatment filter. To collect and remove contaminants, the water treatment filter contains a dirt collection system 16, from which dirt is discharged through a tap 17 into the sewer.

 The backwash filter washer system (not shown) is similar to the wastewater filter washer system.

 Filter housings can be mounted on a single base 18.

 In the design of the filters, electro-manometers 19, electro-automation, light and sound alarms (not shown) are provided.

 The filter works as follows. The water to be cleaned, for example, for heating systems in residential buildings and industrial buildings, or drinking water that flows through the pipe 2 into the housing 1, is distributed through the filter surfaces of the cones 4, 5, 6 and then passes from bottom to top through a layer of granular charge 7, in which the main the mass of suspended microparticles (water clarifies), then passes, if necessary (at the request of the consumer) through an ion exchanger 8, where the water is desalted, and then discharged through pipe 3 to the consumer. When a sound or light alarm arrives, the functional sections of the water treatment filter are flushed with a filter for backwashing through the flushing system 11 with partial or complete replacement of the granular loads. To do this, stop the water supply through the pipeline 2 to the housing 1, leaving the water supply to the housing 14 of the backwash filter, from which the purified water through the open valve 21 is fed through the pipeline 10 under pressure in the reverse order through the perforated pipe 12 with outlets 13, the pure water enters and washes the granular load 7 (8), the cones 4, 5, 6 from top to bottom, then through the mud system 16-17 is discharged into the sewer. During the washing process of the water treatment filter, the discharge pipe 3 does not completely close, so the water that has passed through the filter for backwashing continues to flow to consumers, only in slightly smaller volumes.

 At the end of the washing of the water treatment filter, the water supply is closed through the pipe 2 to the housing 14, and also the pipe 10 is closed. Thus, the washed water treatment filter systems are ready for operation. It is necessary to open the water supply to the pipeline 2 and to the housing 1. In the same way, it is possible to backwash the filter itself for backwashing through the water treatment filter without stopping the supply of clean water to consumers. To do this, with closed pipelines 2 (into the housing 14) and 10 and open pipe 15, open the filter drain valve for backwash (not shown) and partially shut off the outlet pipe 3. Then clean water from the water treatment filter flows in the reverse order to the filter wash system for backwashing and washing it, without stopping the supply of clean water to consumers. At the same time, the processes of operation and washing the filters are regulated by shutoff valves shown in the drawing.

 The proposed combined water treatment filter allows for various quantities and sizes of filter elements - cones and optimal volumes of granular loads to ensure maximum performance and operational reliability of the filter design in the conditions of its use both at the inlet of drinking and heating water to single-storey cottages, and at the entrance to multi-storey residential buildings and industrial buildings of any number of storeys and apartment blocks, including social complexes, such as kindergartens, schools, hospitals, etc.

 Maintenance of such installations - filters in drinking water and heating water purification systems directly at the entrance to the buildings is not difficult, only 1-2 locksmiths on the street quarter with a two-sided location of residential and industrial buildings are enough.

Sources of information
1. Utility model of the Russian Federation N 370, B 01 D 35/02.

 2. Utility model of the Russian Federation N 7341, B 01 D 35/02.

 3. Utility model of the Russian Federation N 7338, B 01 D 35/02.

 4. A.S. USSR N 1787488, B 01 D 35/02.

 5. USSR patent N 1837939, B 01 D 35/02.

 6. RF patent N 2006253, B 01 D 29/72.

 7. RF patent N 2067018, B 01 D 35/22.

 8. RF patent N 2064322, B 01 D 24/18.

 9. RF patent N 1319367, B 01 D 24/00.

 10. RF patent N 1719018, B 01 D 24/18.

 11. RF patent N 2019261, B 01 D 24/10.

Claims (7)

 1. Combined water treatment filter, comprising a housing with inlet and outlet pipelines, a granular charge and a flushing system, consisting of at least two sections connected in series with each other, one of which has a granular load, characterized in that the filter elements are placed in the sections in the form of hollow mesh cones located with their vertices facing the flow of purified water with a decreasing mesh size in the direction of flow, remaining unchanged over the entire surface of each element The entent, in this case, the granular load is placed in the last of the cones, the extreme sections of the filter are connected respectively to the inlet and outlet pipelines, to which a filter for backwashing it having a similar design is connected in parallel with the water treatment filter, while the water treatment filter is equipped with a washing system connected to the outlet pipe of the filter for backwash containing a perforated pipe with radially perforated radially rigid taps connected to it, located equal to ERNO over the entire length of the perforated pipe passing through the axis of the cone through the entire thickness of loading.  2. The combined water treatment filter according to claim 1, characterized in that the granular load is made of expanded clay, or from quartz sand, or activated carbon, or anthracite.  3. The combined water treatment filter according to any one of claims 1 to 2, characterized in that the water treatment filter is equipped with an additional section containing a granular charge, in which the perforated washing pipe is located.  4. The combined water treatment filter according to any one of claims 1 to 3, characterized in that the granular charge is made of KU-2-8sCh ion exchanger or equivalent ion exchanger.  5. The combined water treatment filter according to any one of claims 1 to 4, characterized in that the tops of the cones are sharp-pointed, or truncated, or spherical.  6. The combined water treatment filter according to any one of claims 1 to 5, characterized in that a washing system similar to that located in the water treatment filter is located in the filter for backwashing.  7. The combined water treatment filter according to any one of claims 1 to 6, characterized in that the filter for backwashing has a smaller capacity than that of the water treatment filter.

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